# 29 T orso and pelvic trauma

# ABDOMINAL COMPARTMENT SYNDROME AND THE OPEN ABDOME

ABDOMINAL COMPARTMENT SYNDROME AND THE OPEN ABDOMEN

Raised intra-abdominal pressure has far-reaching conse - quences for the patient; the syndrome that results is known as ACS. ACS is a major cause of  morbidity and mortality in the critically ill patient and its early recognition is essential ( Table 29.8 ). In all cases of abdominal trauma in w hich the development of  ACS in the immediate postoperative phase is considered a risk, the abdomen should be left open and managed as for damage control surgery . - 

TABLE 29.8
Effect of raised intra-abdominal pressure on
individual organ function.
System
Effect
Renal
Increase in renal vascular resistance
leading to a reduction in glomerular
/f_i
ltration rate and impaired renal function
Cardiovascular
Decrease in venous return resulting
in decreased cardiac output because
of both a reduction in preload and an
increase in afterload
Respiratory
Increased ventilation pressures because
of splinting of the diaphragm, decreased
lung compliance and incr
eased airway
pressures
Visceral effects
Reduction in visceral perfusion
Intracranial effects
Severe rises in intracranial pressures

ABDOMINAL COMPARTMENT SYNDROME AND THE OPEN ABDOMEN

Raised intra-abdominal pressure has far-reaching conse - quences for the patient; the syndrome that results is known as ACS. ACS is a major cause of  morbidity and mortality in the critically ill patient and its early recognition is essential ( Table 29.8 ). In all cases of abdominal trauma in w hich the development of  ACS in the immediate postoperative phase is considered a risk, the abdomen should be left open and managed as for damage control surgery . - 

TABLE 29.8
Effect of raised intra-abdominal pressure on
individual organ function.
System
Effect
Renal
Increase in renal vascular resistance
leading to a reduction in glomerular
/f_i
ltration rate and impaired renal function
Cardiovascular
Decrease in venous return resulting
in decreased cardiac output because
of both a reduction in preload and an
increase in afterload
Respiratory
Increased ventilation pressures because
of splinting of the diaphragm, decreased
lung compliance and incr
eased airway
pressures
Visceral effects
Reduction in visceral perfusion
Intracranial effects
Severe rises in intracranial pressures

# ABDOMINAL COMPARTMENT SYNDROME AND THE OPEN ABDOMEN

ABDOMINAL COMPARTMENT SYNDROME AND THE OPEN ABDOMEN

Raised intra-abdominal pressure has far-reaching conse - quences for the patient; the syndrome that results is known as ACS. ACS is a major cause of  morbidity and mortality in the critically ill patient and its early recognition is essential ( Table 29.8 ). In all cases of abdominal trauma in w hich the development of  ACS in the immediate postoperative phase is considered a risk, the abdomen should be left open and managed as for damage control surgery . - 

TABLE 29.8
Effect of raised intra-abdominal pressure on
individual organ function.
System
Effect
Renal
Increase in renal vascular resistance
leading to a reduction in glomerular
/f_i
ltration rate and impaired renal function
Cardiovascular
Decrease in venous return resulting
in decreased cardiac output because
of both a reduction in preload and an
increase in afterload
Respiratory
Increased ventilation pressures because
of splinting of the diaphragm, decreased
lung compliance and incr
eased airway
pressures
Visceral effects
Reduction in visceral perfusion
Intracranial effects
Severe rises in intracranial pressures

# ANTIBIOTICS IN TORSO TRAUMA

ANTIBIOTICS IN TORSO TRAUMA

There is no level 1 evidence to recommend the use of  antibiotics for the insertion of  chest drains. However, prophylactic anti biotics prior to surgery should be used in all cases of  penetrating abdominal trauma. Unless there is major contamination, a single dose is su ﬃ cient. American Association for the Surgery of  Trauma. Organ injury scaling system . Available from http://www .aast.org (accessed February 2022). American College of  Surgeons. Advanced trauma life support course manual for doctors , 10th edn. Chicago, IL: American College of  Surgeons, 2020. Bo ﬀ ard KD (ed.). Deﬁnitive surgery of  trauma care , 5th edn. London: Taylor and Francis, 2019. Eastern Association for the Surgery of  Trauma. Guidelines for practice management: evidence-based guidelines . Available from http://www . east.org (accessed February 2022). Feliciano DV , Mattox LK, Moore EE (eds). Trauma , 9th edn. New Y ork, NY: McGraw Hill, 2020. Khan MA, McMonagle M (eds). Trauma: code red: companion to the RCSEng deﬁnitive surgical trauma skills course . Boca Raton, FL: CRC Press, 2018. Khan MA, Nott D (eds). Fundamentals of  frontline surgery . Boca Raton, FL: CRC Press, 2021. - Tornetta P , Ricci W , Court-Brown CM et al . Rockwood and Green’s fractures in adults , 9th edn. Philadelphia, PA: Wolters Kluwer, 2019. World Society for Abdominal Compartment Syndrome. Abdominal compartment syndrome . Available from http://www .wsacs.org (accessed February 2022). ANTIBIOTICS IN TORSO TRAUMA

There is no level 1 evidence to recommend the use of  antibiotics for the insertion of  chest drains. However, prophylactic anti biotics prior to surgery should be used in all cases of  penetrating abdominal trauma. Unless there is major contamination, a single dose is su ﬃ cient. American Association for the Surgery of  Trauma. Organ injury scaling system . Available from http://www .aast.org (accessed February 2022). American College of  Surgeons. Advanced trauma life support course manual for doctors , 10th edn. Chicago, IL: American College of  Surgeons, 2020. Bo ﬀ ard KD (ed.). Deﬁnitive surgery of  trauma care , 5th edn. London: Taylor and Francis, 2019. Eastern Association for the Surgery of  Trauma. Guidelines for practice management: evidence-based guidelines . Available from http://www . east.org (accessed February 2022). Feliciano DV , Mattox LK, Moore EE (eds). Trauma , 9th edn. New Y ork, NY: McGraw Hill, 2020. Khan MA, McMonagle M (eds). Trauma: code red: companion to the RCSEng deﬁnitive surgical trauma skills course . Boca Raton, FL: CRC Press, 2018. Khan MA, Nott D (eds). Fundamentals of  frontline surgery . Boca Raton, FL: CRC Press, 2021. - Tornetta P , Ricci W , Court-Brown CM et al . Rockwood and Green’s fractures in adults , 9th edn. Philadelphia, PA: Wolters Kluwer, 2019. World Society for Abdominal Compartment Syndrome. Abdominal compartment syndrome . Available from http://www .wsacs.org (accessed February 2022). ANTIBIOTICS IN TORSO TRAUMA

There is no level 1 evidence to recommend the use of  antibiotics for the insertion of  chest drains. However, prophylactic anti biotics prior to surgery should be used in all cases of  penetrating abdominal trauma. Unless there is major contamination, a single dose is su ﬃ cient. American Association for the Surgery of  Trauma. Organ injury scaling system . Available from http://www .aast.org (accessed February 2022). American College of  Surgeons. Advanced trauma life support course manual for doctors , 10th edn. Chicago, IL: American College of  Surgeons, 2020. Bo ﬀ ard KD (ed.). Deﬁnitive surgery of  trauma care , 5th edn. London: Taylor and Francis, 2019. Eastern Association for the Surgery of  Trauma. Guidelines for practice management: evidence-based guidelines . Available from http://www . east.org (accessed February 2022). Feliciano DV , Mattox LK, Moore EE (eds). Trauma , 9th edn. New Y ork, NY: McGraw Hill, 2020. Khan MA, McMonagle M (eds). Trauma: code red: companion to the RCSEng deﬁnitive surgical trauma skills course . Boca Raton, FL: CRC Press, 2018. Khan MA, Nott D (eds). Fundamentals of  frontline surgery . Boca Raton, FL: CRC Press, 2021. - Tornetta P , Ricci W , Court-Brown CM et al . Rockwood and Green’s fractures in adults , 9th edn. Philadelphia, PA: Wolters Kluwer, 2019. World Society for Abdominal Compartment Syndrome. Abdominal compartment syndrome . Available from http://www .wsacs.org (accessed February 2022).

# Anatomy

Anatomy

The surgical anatomy of  the pelvis is key to the understanding of  pelvic injuries. /uni25CF The pelvic inlet is circular. It is a structure that is immensely strong, but routinely gives way at more than one point should su ﬃ cient force be applied to it. Therefore, iso lated fractures of  the anterior or posterior pelvic ring are uncommon. /uni25CF The forces required to fracture the pelvic ring do not respect the surrounding organ systems. /uni25CF The pelvis has a rich collateral blood supply , especially across the sacrum and posterior part of  the ileum. The cancellous bone of  the pelvis also has an excellent blood supply . Most pelvic haemorrhage emanates from venous injury and fracture sites. However, in the haemodynam ically unstable patient with severe pelvic injury , arterial bleeding is more frequent. Important for the treatment is that the surgeon has to deal with both arterial and venous bleeding. Marvin Tile , b. 1933, orthopaedic surgeon, Sunnybrook Medical Centre, Toronto, Canada. - - - /uni25CF Postmortem examination has shown that the extrapelvic peritoneal space can accommodate more than 3000 /uni00A0 mL. However, in the case of  a severe pelvic fracture where the retroperitoneal compartment is disrupted and the external bony barrier is not stable, haematoma may extend upwards towards the mediastinum (‘chimney e ﬀ ect’) or downwards into the medial thigh in case of  rupture of  the pelvic ﬂoor. /uni25CF All iliac vessels, the sciatic nerve roots (including the lum - bosacral nerve) and the ureters cross the sacroiliac joint; disruption of  this joint may cause severe haemorrhage and sometimes cause arterial obstruction of  the internal iliac artery and sciatic nerve palsy . Injuries to the ureters are rare. /uni25CF The pelvic viscera are suspended from the bony pelvis by condensations of  the endopelvic fascia. Shear forces acting - on the pelvis will transmit these to pelvic viscera, leading to avulsion and shearing injuries. /uni25CF The pelvis also includes the acetabulum, a major structure in weight transfer to the leg. Inappropriate treatment will lead to severe disability . 

Type A
Type B
Type C
Figure 29.11
Tile classi
/f_i
cation of fractures of the pelvis.

Anatomy

The surgical anatomy of  the pelvis is key to the understanding of  pelvic injuries. /uni25CF The pelvic inlet is circular. It is a structure that is immensely strong, but routinely gives way at more than one point should su ﬃ cient force be applied to it. Therefore, iso lated fractures of  the anterior or posterior pelvic ring are uncommon. /uni25CF The forces required to fracture the pelvic ring do not respect the surrounding organ systems. /uni25CF The pelvis has a rich collateral blood supply , especially across the sacrum and posterior part of  the ileum. The cancellous bone of  the pelvis also has an excellent blood supply . Most pelvic haemorrhage emanates from venous injury and fracture sites. However, in the haemodynam ically unstable patient with severe pelvic injury , arterial bleeding is more frequent. Important for the treatment is that the surgeon has to deal with both arterial and venous bleeding. Marvin Tile , b. 1933, orthopaedic surgeon, Sunnybrook Medical Centre, Toronto, Canada. - - - /uni25CF Postmortem examination has shown that the extrapelvic peritoneal space can accommodate more than 3000 /uni00A0 mL. However, in the case of  a severe pelvic fracture where the retroperitoneal compartment is disrupted and the external bony barrier is not stable, haematoma may extend upwards towards the mediastinum (‘chimney e ﬀ ect’) or downwards into the medial thigh in case of  rupture of  the pelvic ﬂoor. /uni25CF All iliac vessels, the sciatic nerve roots (including the lum - bosacral nerve) and the ureters cross the sacroiliac joint; disruption of  this joint may cause severe haemorrhage and sometimes cause arterial obstruction of  the internal iliac artery and sciatic nerve palsy . Injuries to the ureters are rare. /uni25CF The pelvic viscera are suspended from the bony pelvis by condensations of  the endopelvic fascia. Shear forces acting - on the pelvis will transmit these to pelvic viscera, leading to avulsion and shearing injuries. /uni25CF The pelvis also includes the acetabulum, a major structure in weight transfer to the leg. Inappropriate treatment will lead to severe disability . 

Type A
Type B
Type C
Figure 29.11
Tile classi
/f_i
cation of fractures of the pelvis.

Anatomy

The surgical anatomy of  the pelvis is key to the understanding of  pelvic injuries. /uni25CF The pelvic inlet is circular. It is a structure that is immensely strong, but routinely gives way at more than one point should su ﬃ cient force be applied to it. Therefore, iso lated fractures of  the anterior or posterior pelvic ring are uncommon. /uni25CF The forces required to fracture the pelvic ring do not respect the surrounding organ systems. /uni25CF The pelvis has a rich collateral blood supply , especially across the sacrum and posterior part of  the ileum. The cancellous bone of  the pelvis also has an excellent blood supply . Most pelvic haemorrhage emanates from venous injury and fracture sites. However, in the haemodynam ically unstable patient with severe pelvic injury , arterial bleeding is more frequent. Important for the treatment is that the surgeon has to deal with both arterial and venous bleeding. Marvin Tile , b. 1933, orthopaedic surgeon, Sunnybrook Medical Centre, Toronto, Canada. - - - /uni25CF Postmortem examination has shown that the extrapelvic peritoneal space can accommodate more than 3000 /uni00A0 mL. However, in the case of  a severe pelvic fracture where the retroperitoneal compartment is disrupted and the external bony barrier is not stable, haematoma may extend upwards towards the mediastinum (‘chimney e ﬀ ect’) or downwards into the medial thigh in case of  rupture of  the pelvic ﬂoor. /uni25CF All iliac vessels, the sciatic nerve roots (including the lum - bosacral nerve) and the ureters cross the sacroiliac joint; disruption of  this joint may cause severe haemorrhage and sometimes cause arterial obstruction of  the internal iliac artery and sciatic nerve palsy . Injuries to the ureters are rare. /uni25CF The pelvic viscera are suspended from the bony pelvis by condensations of  the endopelvic fascia. Shear forces acting - on the pelvis will transmit these to pelvic viscera, leading to avulsion and shearing injuries. /uni25CF The pelvis also includes the acetabulum, a major structure in weight transfer to the leg. Inappropriate treatment will lead to severe disability . 

Type A
Type B
Type C
Figure 29.11
Tile classi
/f_i
cation of fractures of the pelvis.

# Biliary injuries

Biliary injuries

Isolated traumatic biliary injuries are rare and occur mainly from penetrating trauma, often in association with injuries to other structures that lie in close proximity . The common bile duct can be repaired over a T-tube or drained and referred to appropriate care as part of  damage control, or even ligated. Biliary injuries

Isolated traumatic biliary injuries are rare and occur mainly from penetrating trauma, often in association with injuries to other structures that lie in close proximity . The common bile duct can be repaired over a T-tube or drained and referred to appropriate care as part of  damage control, or even ligated. Biliary injuries

Isolated traumatic biliary injuries are rare and occur mainly from penetrating trauma, often in association with injuries to other structures that lie in close proximity . The common bile duct can be repaired over a T-tube or drained and referred to appropriate care as part of  damage control, or even ligated.

# CRITICAL PHYSIOLOGY

CRITICAL PHYSIOLOGY

Resuscitation of  all injuries to the chest and abdomen should follow the latest Advanced Trauma Life Support (ATLS) prin ciples ( Table 29.1 ; see Chapters 26 and 27 ). Haemorrhage is the major problem. This may be obvi - ous at the time of evaluation; however, in the young physi - cally ﬁt individual, bleeding may produce no or only minimal changes in vital measures and, therefore, be di ﬃ cult to assess ( Table 29.2 ). Although obvious injury may be present, tradi - tional indicators (such as pulse rate), in isola tion, are unreliable. Bleeding occurs from ﬁve major sites – ‘ one on the ﬂoor and four more ’: /uni25CF external – ‘ﬂoor’; /uni25CF chest; /uni25CF abdomen (including the retroperitoneum); /uni25CF pelvis; /uni25CF extremities. 

TABLE 29.1
Advanced Trauma Life Support principles of
resuscitation.
C Catastrophic haemorrhage
A Airway
B Breathing
C Circulation
D Disability (neurology)
E Environment and exposure
Liver
Spleen
Kidney
bleeding in torso trauma.
Physiological
Increasing respiratory rate
Increasing pulse rate
Falling blood pressure
Rising serum lactate
Anatomical
Visible bleeding
Injury in close proximity to major vessels
Penetrating injury with a retained missile

CRITICAL PHYSIOLOGY

Resuscitation of  all injuries to the chest and abdomen should follow the latest Advanced Trauma Life Support (ATLS) prin ciples ( Table 29.1 ; see Chapters 26 and 27 ). Haemorrhage is the major problem. This may be obvi - ous at the time of evaluation; however, in the young physi - cally ﬁt individual, bleeding may produce no or only minimal changes in vital measures and, therefore, be di ﬃ cult to assess ( Table 29.2 ). Although obvious injury may be present, tradi - tional indicators (such as pulse rate), in isola tion, are unreliable. Bleeding occurs from ﬁve major sites – ‘ one on the ﬂoor and four more ’: /uni25CF external – ‘ﬂoor’; /uni25CF chest; /uni25CF abdomen (including the retroperitoneum); /uni25CF pelvis; /uni25CF extremities. 

TABLE 29.1
Advanced Trauma Life Support principles of
resuscitation.
C Catastrophic haemorrhage
A Airway
B Breathing
C Circulation
D Disability (neurology)
E Environment and exposure
Liver
Spleen
Kidney
bleeding in torso trauma.
Physiological
Increasing respiratory rate
Increasing pulse rate
Falling blood pressure
Rising serum lactate
Anatomical
Visible bleeding
Injury in close proximity to major vessels
Penetrating injury with a retained missile

CRITICAL PHYSIOLOGY

Resuscitation of  all injuries to the chest and abdomen should follow the latest Advanced Trauma Life Support (ATLS) prin ciples ( Table 29.1 ; see Chapters 26 and 27 ). Haemorrhage is the major problem. This may be obvi - ous at the time of evaluation; however, in the young physi - cally ﬁt individual, bleeding may produce no or only minimal changes in vital measures and, therefore, be di ﬃ cult to assess ( Table 29.2 ). Although obvious injury may be present, tradi - tional indicators (such as pulse rate), in isola tion, are unreliable. Bleeding occurs from ﬁve major sites – ‘ one on the ﬂoor and four more ’: /uni25CF external – ‘ﬂoor’; /uni25CF chest; /uni25CF abdomen (including the retroperitoneum); /uni25CF pelvis; /uni25CF extremities. 

TABLE 29.1
Advanced Trauma Life Support principles of
resuscitation.
C Catastrophic haemorrhage
A Airway
B Breathing
C Circulation
D Disability (neurology)
E Environment and exposure
Liver
Spleen
Kidney
bleeding in torso trauma.
Physiological
Increasing respiratory rate
Increasing pulse rate
Falling blood pressure
Rising serum lactate
Anatomical
Visible bleeding
Injury in close proximity to major vessels
Penetrating injury with a retained missile

# Classiﬁcation

Classiﬁcation

Pelvic ring fractures can be classiﬁed into three types, using - the Tile classiﬁcation (for subtypes and other classiﬁca - tions see Further reading ), based on the severity of the fracture (and reﬂecting the energy required to cause it) ( Figure 29.11 ). Ho wever, no fracture pattern can exclude signiﬁcant haemorrhage. Type A are the most common fractures and are completely stable. They result from lateral compression, which causes compression fractures of  the pubic rami or compression frac ture of  the sacrum posteriorly . Type B These fractures are partially stable, and there is disruption of  the anterior pelvis and partial disruption of  the posterior pelvis. The pelvis can open and close ‘like a book’, but because the sacroiliac ligaments remain intact there is no vertical displacement. Internal or external stabilisation is required. Blood loss can be signiﬁcant. Type C This fracture is completely unstable. Both the anterior pelvis and the entire posterior pelvic complexes are disrupted and the disrupted pelvic bones are free to displace horizontally and vertically . In both type B and type C pelvic injuries, there is a high risk of  associated abdominal injuries (bowel perforation or mesenteric laceration) and rupture of  the diaphragm. Classiﬁcation

Pelvic ring fractures can be classiﬁed into three types, using - the Tile classiﬁcation (for subtypes and other classiﬁca - tions see Further reading ), based on the severity of the fracture (and reﬂecting the energy required to cause it) ( Figure 29.11 ). Ho wever, no fracture pattern can exclude signiﬁcant haemorrhage. Type A are the most common fractures and are completely stable. They result from lateral compression, which causes compression fractures of  the pubic rami or compression frac ture of  the sacrum posteriorly . Type B These fractures are partially stable, and there is disruption of  the anterior pelvis and partial disruption of  the posterior pelvis. The pelvis can open and close ‘like a book’, but because the sacroiliac ligaments remain intact there is no vertical displacement. Internal or external stabilisation is required. Blood loss can be signiﬁcant. Type C This fracture is completely unstable. Both the anterior pelvis and the entire posterior pelvic complexes are disrupted and the disrupted pelvic bones are free to displace horizontally and vertically . In both type B and type C pelvic injuries, there is a high risk of  associated abdominal injuries (bowel perforation or mesenteric laceration) and rupture of  the diaphragm. Classiﬁcation

Pelvic ring fractures can be classiﬁed into three types, using - the Tile classiﬁcation (for subtypes and other classiﬁca - tions see Further reading ), based on the severity of the fracture (and reﬂecting the energy required to cause it) ( Figure 29.11 ). Ho wever, no fracture pattern can exclude signiﬁcant haemorrhage. Type A are the most common fractures and are completely stable. They result from lateral compression, which causes compression fractures of  the pubic rami or compression frac ture of  the sacrum posteriorly . Type B These fractures are partially stable, and there is disruption of  the anterior pelvis and partial disruption of  the posterior pelvis. The pelvis can open and close ‘like a book’, but because the sacroiliac ligaments remain intact there is no vertical displacement. Internal or external stabilisation is required. Blood loss can be signiﬁcant. Type C This fracture is completely unstable. Both the anterior pelvis and the entire posterior pelvic complexes are disrupted and the disrupted pelvic bones are free to displace horizontally and vertically . In both type B and type C pelvic injuries, there is a high risk of  associated abdominal injuries (bowel perforation or mesenteric laceration) and rupture of  the diaphragm.

# Clinical examination

Clinical examination

Pelvic fractures should be easily identiﬁed if  ATLS guidelines are followed. There is no role of  ‘springing’ the pelvis. If  a binder has not been applied and an ‘open book’ fracture is suspected, a binder must be immediately applied as the pres ence of  major pelvic fracture is associated with life-threatening blood loss and requires appropriate measures. Inspection of  the skin may reveal lacerations in the groin, perineum or sacral area, indica ting an open pelvic fracture, the result of  gross deformation. Evidence of  perineal injury or haematuria mandates radiological ev aluation of  the urinary tract from below upwards (retrograde urethrogram followed by cystogram or CT cystogram and an excretory urogram, as appropriate) when the physiology allows. Inspection of  the urethral meatus may reveal a drop of  blood, indicating ure thral damage. Inspection of the anus may reveal lacerations to the sphinc ter mechanism. Rectal examination may reveal blood in the rectum and/or discontinuity of  the rectal wall, indicating a rectal laceration. In male patients, the prostate is palpated; a high-riding prosta te indicates a complete urethral avulsion. A full neurological examination is performed of  the perineal area, sphincter mechanism and femoral and sciatic nerves. Clinical examination

Pelvic fractures should be easily identiﬁed if  ATLS guidelines are followed. There is no role of  ‘springing’ the pelvis. If  a binder has not been applied and an ‘open book’ fracture is suspected, a binder must be immediately applied as the pres ence of  major pelvic fracture is associated with life-threatening blood loss and requires appropriate measures. Inspection of  the skin may reveal lacerations in the groin, perineum or sacral area, indica ting an open pelvic fracture, the result of  gross deformation. Evidence of  perineal injury or haematuria mandates radiological ev aluation of  the urinary tract from below upwards (retrograde urethrogram followed by cystogram or CT cystogram and an excretory urogram, as appropriate) when the physiology allows. Inspection of  the urethral meatus may reveal a drop of  blood, indicating ure thral damage. Inspection of the anus may reveal lacerations to the sphinc ter mechanism. Rectal examination may reveal blood in the rectum and/or discontinuity of  the rectal wall, indicating a rectal laceration. In male patients, the prostate is palpated; a high-riding prosta te indicates a complete urethral avulsion. A full neurological examination is performed of  the perineal area, sphincter mechanism and femoral and sciatic nerves. Clinical examination

Pelvic fractures should be easily identiﬁed if  ATLS guidelines are followed. There is no role of  ‘springing’ the pelvis. If  a binder has not been applied and an ‘open book’ fracture is suspected, a binder must be immediately applied as the pres ence of  major pelvic fracture is associated with life-threatening blood loss and requires appropriate measures. Inspection of  the skin may reveal lacerations in the groin, perineum or sacral area, indica ting an open pelvic fracture, the result of  gross deformation. Evidence of  perineal injury or haematuria mandates radiological ev aluation of  the urinary tract from below upwards (retrograde urethrogram followed by cystogram or CT cystogram and an excretory urogram, as appropriate) when the physiology allows. Inspection of  the urethral meatus may reveal a drop of  blood, indicating ure thral damage. Inspection of the anus may reveal lacerations to the sphinc ter mechanism. Rectal examination may reveal blood in the rectum and/or discontinuity of  the rectal wall, indicating a rectal laceration. In male patients, the prostate is palpated; a high-riding prosta te indicates a complete urethral avulsion. A full neurological examination is performed of  the perineal area, sphincter mechanism and femoral and sciatic nerves.

# Colon

Colon

Blunt injuries to the colon are relatively infrequent; penetrating injuries occur more often. If  relatively little contamination is present and the viability is satisfactory , such wounds can be repaired primarily . If, however, there is extensive contamina tion, the patient is physiologically compromised or the bowel is of  doubtful viability , then the bowel can be closed o ﬀ (‘clip and drop’). A defunctioning colostomy can be formed later or the bowel reanastomosed once the patient is stable. Colon

Blunt injuries to the colon are relatively infrequent; penetrating injuries occur more often. If  relatively little contamination is present and the viability is satisfactory , such wounds can be repaired primarily . If, however, there is extensive contamina tion, the patient is physiologically compromised or the bowel is of  doubtful viability , then the bowel can be closed o ﬀ (‘clip and drop’). A defunctioning colostomy can be formed later or the bowel reanastomosed once the patient is stable. Colon

Blunt injuries to the colon are relatively infrequent; penetrating injuries occur more often. If  relatively little contamination is present and the viability is satisfactory , such wounds can be repaired primarily . If, however, there is extensive contamina tion, the patient is physiologically compromised or the bowel is of  doubtful viability , then the bowel can be closed o ﬀ (‘clip and drop’). A defunctioning colostomy can be formed later or the bowel reanastomosed once the patient is stable.

# Computed tomography scan

Computed tomography scan

CT has become the ‘gold standard’ for the intra-abdominal diagnosis of injury in the stable patient. The scan can be performed using intravenous contrast. CT is sensitive for blood and individual organ injury as well as for retroperitoneal injury . An entirely normal abdominal CT is usually su ﬃ cient to exclude intraperitoneal injury . The following points are important when performing CT: /uni25CF it remains an inappropriate investigation for physiologically compromised patients; /uni25CF if  duodenal injury is suspected from the mechanism of injury , oral contrast may be helpful; /uni25CF if  rectal and distal colonic injury is suspected in the absence of  blood on rectal examination, air around the colon may indicate injury; in all cases clinical suspicion supersedes investigation results. 

Figure 29.8
Compression injury to the liver, bursting the liver sub
stance.

Computed tomography scan

CT has become the ‘gold standard’ for the intra-abdominal diagnosis of injury in the stable patient. The scan can be performed using intravenous contrast. CT is sensitive for blood and individual organ injury as well as for retroperitoneal injury . An entirely normal abdominal CT is usually su ﬃ cient to exclude intraperitoneal injury . The following points are important when performing CT: /uni25CF it remains an inappropriate investigation for physiologically compromised patients; /uni25CF if  duodenal injury is suspected from the mechanism of injury , oral contrast may be helpful; /uni25CF if  rectal and distal colonic injury is suspected in the absence of  blood on rectal examination, air around the colon may indicate injury; in all cases clinical suspicion supersedes investigation results. 

Figure 29.8
Compression injury to the liver, bursting the liver sub
stance.

Computed tomography scan

CT has become the ‘gold standard’ for the intra-abdominal diagnosis of injury in the stable patient. The scan can be performed using intravenous contrast. CT is sensitive for blood and individual organ injury as well as for retroperitoneal injury . An entirely normal abdominal CT is usually su ﬃ cient to exclude intraperitoneal injury . The following points are important when performing CT: /uni25CF it remains an inappropriate investigation for physiologically compromised patients; /uni25CF if  duodenal injury is suspected from the mechanism of injury , oral contrast may be helpful; /uni25CF if  rectal and distal colonic injury is suspected in the absence of  blood on rectal examination, air around the colon may indicate injury; in all cases clinical suspicion supersedes investigation results. 

Figure 29.8
Compression injury to the liver, bursting the liver sub
stance.

# DAMAGE CONTROL

DAMAGE CONTROL

Following major injury , protracted surgery in the physio logically unstable patient can in itself  prove fatal. Patients with the ‘deadly triad’ (hypothermia, acidosis and coagulopathy) are those at highest risk. Damage control or damage limitation surgery is a concept that originated from a naval shipbuilding stra tegy , whereby ships were designed so that the damage was kept ‘local’ and only minimal repairs were needed to prevent the ship from sinking while deﬁnitive repairs waited until it had reached port. The technique has been adopted follow ing major trauma and includes initial care and resuscitation (damage control resuscitation) and the surgical correction of the injury (damage control surgery). The minimum amount of  surgery needed to stabilise the patient’s condition ma y be the safest course until the physiolog ical derangement can be corrected. Damage control surgery is restricted to only three goals: /uni25CF stopping any active surgical bleeding; /uni25CF controlling any contamination; /uni25CF restoring normal physiology . Once the ﬁrst two have been achieved then the operation is suspended and the abdomen temporarily closed to allow for restoration of  physiology to occur. The pa tient’s resuscitation then continues in the ICU, where other therapeutic interven tions can take place. Once the physiology has been corrected, the patient warmed and the coagulopathy corrected, the patient is returned to the operating theatre for any deﬁnitive surgery DAMAGE CONTROL

Following major injury , protracted surgery in the physio logically unstable patient can in itself  prove fatal. Patients with the ‘deadly triad’ (hypothermia, acidosis and coagulopathy) are those at highest risk. Damage control or damage limitation surgery is a concept that originated from a naval shipbuilding stra tegy , whereby ships were designed so that the damage was kept ‘local’ and only minimal repairs were needed to prevent the ship from sinking while deﬁnitive repairs waited until it had reached port. The technique has been adopted follow ing major trauma and includes initial care and resuscitation (damage control resuscitation) and the surgical correction of the injury (damage control surgery). The minimum amount of  surgery needed to stabilise the patient’s condition ma y be the safest course until the physiolog ical derangement can be corrected. Damage control surgery is restricted to only three goals: /uni25CF stopping any active surgical bleeding; /uni25CF controlling any contamination; /uni25CF restoring normal physiology . Once the ﬁrst two have been achieved then the operation is suspended and the abdomen temporarily closed to allow for restoration of  physiology to occur. The pa tient’s resuscitation then continues in the ICU, where other therapeutic interven tions can take place. Once the physiology has been corrected, the patient warmed and the coagulopathy corrected, the patient is returned to the operating theatre for any deﬁnitive surgery DAMAGE CONTROL

Following major injury , protracted surgery in the physio logically unstable patient can in itself  prove fatal. Patients with the ‘deadly triad’ (hypothermia, acidosis and coagulopathy) are those at highest risk. Damage control or damage limitation surgery is a concept that originated from a naval shipbuilding stra tegy , whereby ships were designed so that the damage was kept ‘local’ and only minimal repairs were needed to prevent the ship from sinking while deﬁnitive repairs waited until it had reached port. The technique has been adopted follow ing major trauma and includes initial care and resuscitation (damage control resuscitation) and the surgical correction of the injury (damage control surgery). The minimum amount of  surgery needed to stabilise the patient’s condition ma y be the safest course until the physiolog ical derangement can be corrected. Damage control surgery is restricted to only three goals: /uni25CF stopping any active surgical bleeding; /uni25CF controlling any contamination; /uni25CF restoring normal physiology . Once the ﬁrst two have been achieved then the operation is suspended and the abdomen temporarily closed to allow for restoration of  physiology to occur. The pa tient’s resuscitation then continues in the ICU, where other therapeutic interven tions can take place. Once the physiology has been corrected, the patient warmed and the coagulopathy corrected, the patient is returned to the operating theatre for any deﬁnitive surgery

# Damage control resuscitation

Damage control resuscitation

The concept of  damage control has been broadened to include the techniques used in resuscitation as well as in surgery . The time in the emergency department is minimised and the majority of  resuscitation of  the patient is carried out in the operating theatre and not in the resuscitation bay ( Table 29.6 Resuscitation is individualised through repeated point-of-care testing of  haemoglobin, acidosis (pH and lactate) and clot ting, and is therefore directed towards the early delivery of biologically active colloids, clotting products and whole blood in order to buy time. The physiological disturbances that are associated with the downward spiral of  acidosis, coagulopa and hypothermia in these serious injuries are predicted and attempts are made to avoid them rather than react to them. This is a key component of  damage control resuscitation. The decision of whether damage control surgery is the appropriate course should be made early ( Table 29.7 ) and allows the whole surgical and anaesthetic team to work together to limit the time in surgery and achieve the earliest possible admission of the patient to the ICU. Damage control is a staged process. The initial focus is haemorrhage control, followed by con - trol and limitation of  contamination, which are achieved using a range of  abbreviated techniques including simple ligation of bleeding vessels, shunting of  major arteries and veins, drain - age, temporary stapling of bowel and therapeutic packing. Following the above, the abdomen is closed in a temporary fashion either by using commercially available products or by ◊ using a sheet of  plastic (e.g. OPSITE or similar product) over the bowel, an intermediate pack to allow suction and a further - sheet of  adherent plastic drape to the skin to form a watertight and airtight seal. Suction is applied to the intermediate pack area to collect abdominal ﬂuid. This technique is known as the ◊ ‘Vac-Pac’ or ‘OPSITE sandwich’ ( Figure 29.12 ). As soon as control has been achieved the patient is transferred to the ICU, where resuscitation is continued. - - - . ). - thy 

(a)
Outer layer Inner layer
◊
◊
/Ioban™) (OPSITE
/Ioban™)
(OPSITE
Abdominal swab/
cotton drape
Abdominal
content
Suction drains
(b)
Figure 29.12
(a)
Diagram showing temporary skin closure in damage
control.
(b)
Abdominal closure following damage control surgery
◊
showing an OPSITE
closure.

The next stage following damage control surgery and physiological stabilisation is deﬁnitive surgery . The team should aim to perform deﬁnitive anastomoses, vascular recon struction and closure of  the body cavity within 24–72 hours of  injury . However, this must be individualised to the patient, the response to critical care resuscitation and the progression of injury . /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The abdomen is closed as soon as possible, bearing in mind the risks of  abdominal compartment syndrome (ACS). The closure is not without its own morbidity . Successful closure may require aggressive o ﬀ -loading of  ﬂuid and even haemo ﬁltration to achieve this if  the patient will tolerate it. The best situation is closure of  the abdominal fascia, or, if  this cannot be achieved, then skin closure only . Occasionally , mesh closure can be used, with skin g rafting over the mesh and subsequent abdominal wall reconstruction. Thoracic damage control is conceptually based on the same philosophy . This is that haemorrhage control and focused surgical procedures minimise further surgical insult and lead to improved survival in the unstable trauma patient. T he aim is to control bleeding and limit air leaks using the fastest procedures available, such as staplers, to minimise the operative time. surgery have already been described. Damage control applies equally to the extremities. In this case, it is shunting of  blood vessels, identifying and marking damaged structures such as nerves, fasciotomy and removal of contaminated tissue that are the main tasks . Subsequent deﬁn - itive management can be carried out at a later stage. Summary box 29.9 Damage control /uni25CF - /uni25CF /uni25CF /uni25CF 

Stage
Intervention
I
Patient selection
II
Control of haemorrhage and control of contamination
III
Resuscitation continued in the intensive care unit
IV
De
/f_i
nitive surgery
V
Abdominal closure
TABLE 29.7
Indications for damage control surgery.
Inability to achieve haemostasis
Anatomical
Complex abdominal injury, e.g. liver and
pancreas
Combined vascular, solid and hollow
organ injury, e.g. aortic or caval injury
Inaccessible major venous injury, e.g.
retrohepatic vena cava
Demand for non-operative control of other
injuries, e.g. fractured pelvis
Anticipated need for a time-consuming
procedure
Physiological
Temperature <34°C
(decline of
pH <7.2
physiological
Serum lactate >5
/uni00A0
mmol/L (normal:
reserve)
<2.5
/uni00A0
mmol/L)
Prothrombin time >16
/uni00A0
s
Partial thromboplastin time >60
/uni00A0
s
>10 units blood transfused
Systolic blood pressure <90
/uni00A0
mmHg for
>60 min
Environmental
Operating time >60 min (core temperature
loss is usually 2°C/h)
Inability to approximate the abdominal
incision
Desire to reassess the intra-abdominal
contents (directed relook)
Resuscitation is carried out in the operating theatre using
biologically active
/f_l
uids (i.e. blood) – damage control
resuscitation
The surgery performed is the minimum needed to stabilise the
patient
The aims of surgery are to control haemorrhage and limit
contamination
Secondary surgery is aimed at de
/f_i
nitive repair

Damage control resuscitation

The concept of  damage control has been broadened to include the techniques used in resuscitation as well as in surgery . The time in the emergency department is minimised and the majority of  resuscitation of  the patient is carried out in the operating theatre and not in the resuscitation bay ( Table 29.6 Resuscitation is individualised through repeated point-of-care testing of  haemoglobin, acidosis (pH and lactate) and clot ting, and is therefore directed towards the early delivery of biologically active colloids, clotting products and whole blood in order to buy time. The physiological disturbances that are associated with the downward spiral of  acidosis, coagulopa and hypothermia in these serious injuries are predicted and attempts are made to avoid them rather than react to them. This is a key component of  damage control resuscitation. The decision of whether damage control surgery is the appropriate course should be made early ( Table 29.7 ) and allows the whole surgical and anaesthetic team to work together to limit the time in surgery and achieve the earliest possible admission of the patient to the ICU. Damage control is a staged process. The initial focus is haemorrhage control, followed by con - trol and limitation of  contamination, which are achieved using a range of  abbreviated techniques including simple ligation of bleeding vessels, shunting of  major arteries and veins, drain - age, temporary stapling of bowel and therapeutic packing. Following the above, the abdomen is closed in a temporary fashion either by using commercially available products or by ◊ using a sheet of  plastic (e.g. OPSITE or similar product) over the bowel, an intermediate pack to allow suction and a further - sheet of  adherent plastic drape to the skin to form a watertight and airtight seal. Suction is applied to the intermediate pack area to collect abdominal ﬂuid. This technique is known as the ◊ ‘Vac-Pac’ or ‘OPSITE sandwich’ ( Figure 29.12 ). As soon as control has been achieved the patient is transferred to the ICU, where resuscitation is continued. - - - . ). - thy 

(a)
Outer layer Inner layer
◊
◊
/Ioban™) (OPSITE
/Ioban™)
(OPSITE
Abdominal swab/
cotton drape
Abdominal
content
Suction drains
(b)
Figure 29.12
(a)
Diagram showing temporary skin closure in damage
control.
(b)
Abdominal closure following damage control surgery
◊
showing an OPSITE
closure.

The next stage following damage control surgery and physiological stabilisation is deﬁnitive surgery . The team should aim to perform deﬁnitive anastomoses, vascular recon struction and closure of  the body cavity within 24–72 hours of  injury . However, this must be individualised to the patient, the response to critical care resuscitation and the progression of injury . /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The abdomen is closed as soon as possible, bearing in mind the risks of  abdominal compartment syndrome (ACS). The closure is not without its own morbidity . Successful closure may require aggressive o ﬀ -loading of  ﬂuid and even haemo ﬁltration to achieve this if  the patient will tolerate it. The best situation is closure of  the abdominal fascia, or, if  this cannot be achieved, then skin closure only . Occasionally , mesh closure can be used, with skin g rafting over the mesh and subsequent abdominal wall reconstruction. Thoracic damage control is conceptually based on the same philosophy . This is that haemorrhage control and focused surgical procedures minimise further surgical insult and lead to improved survival in the unstable trauma patient. T he aim is to control bleeding and limit air leaks using the fastest procedures available, such as staplers, to minimise the operative time. surgery have already been described. Damage control applies equally to the extremities. In this case, it is shunting of  blood vessels, identifying and marking damaged structures such as nerves, fasciotomy and removal of contaminated tissue that are the main tasks . Subsequent deﬁn - itive management can be carried out at a later stage. Summary box 29.9 Damage control /uni25CF - /uni25CF /uni25CF /uni25CF 

Stage
Intervention
I
Patient selection
II
Control of haemorrhage and control of contamination
III
Resuscitation continued in the intensive care unit
IV
De
/f_i
nitive surgery
V
Abdominal closure
TABLE 29.7
Indications for damage control surgery.
Inability to achieve haemostasis
Anatomical
Complex abdominal injury, e.g. liver and
pancreas
Combined vascular, solid and hollow
organ injury, e.g. aortic or caval injury
Inaccessible major venous injury, e.g.
retrohepatic vena cava
Demand for non-operative control of other
injuries, e.g. fractured pelvis
Anticipated need for a time-consuming
procedure
Physiological
Temperature <34°C
(decline of
pH <7.2
physiological
Serum lactate >5
/uni00A0
mmol/L (normal:
reserve)
<2.5
/uni00A0
mmol/L)
Prothrombin time >16
/uni00A0
s
Partial thromboplastin time >60
/uni00A0
s
>10 units blood transfused
Systolic blood pressure <90
/uni00A0
mmHg for
>60 min
Environmental
Operating time >60 min (core temperature
loss is usually 2°C/h)
Inability to approximate the abdominal
incision
Desire to reassess the intra-abdominal
contents (directed relook)
Resuscitation is carried out in the operating theatre using
biologically active
/f_l
uids (i.e. blood) – damage control
resuscitation
The surgery performed is the minimum needed to stabilise the
patient
The aims of surgery are to control haemorrhage and limit
contamination
Secondary surgery is aimed at de
/f_i
nitive repair

Damage control resuscitation

The concept of  damage control has been broadened to include the techniques used in resuscitation as well as in surgery . The time in the emergency department is minimised and the majority of  resuscitation of  the patient is carried out in the operating theatre and not in the resuscitation bay ( Table 29.6 Resuscitation is individualised through repeated point-of-care testing of  haemoglobin, acidosis (pH and lactate) and clot ting, and is therefore directed towards the early delivery of biologically active colloids, clotting products and whole blood in order to buy time. The physiological disturbances that are associated with the downward spiral of  acidosis, coagulopa and hypothermia in these serious injuries are predicted and attempts are made to avoid them rather than react to them. This is a key component of  damage control resuscitation. The decision of whether damage control surgery is the appropriate course should be made early ( Table 29.7 ) and allows the whole surgical and anaesthetic team to work together to limit the time in surgery and achieve the earliest possible admission of the patient to the ICU. Damage control is a staged process. The initial focus is haemorrhage control, followed by con - trol and limitation of  contamination, which are achieved using a range of  abbreviated techniques including simple ligation of bleeding vessels, shunting of  major arteries and veins, drain - age, temporary stapling of bowel and therapeutic packing. Following the above, the abdomen is closed in a temporary fashion either by using commercially available products or by ◊ using a sheet of  plastic (e.g. OPSITE or similar product) over the bowel, an intermediate pack to allow suction and a further - sheet of  adherent plastic drape to the skin to form a watertight and airtight seal. Suction is applied to the intermediate pack area to collect abdominal ﬂuid. This technique is known as the ◊ ‘Vac-Pac’ or ‘OPSITE sandwich’ ( Figure 29.12 ). As soon as control has been achieved the patient is transferred to the ICU, where resuscitation is continued. - - - . ). - thy 

(a)
Outer layer Inner layer
◊
◊
/Ioban™) (OPSITE
/Ioban™)
(OPSITE
Abdominal swab/
cotton drape
Abdominal
content
Suction drains
(b)
Figure 29.12
(a)
Diagram showing temporary skin closure in damage
control.
(b)
Abdominal closure following damage control surgery
◊
showing an OPSITE
closure.

The next stage following damage control surgery and physiological stabilisation is deﬁnitive surgery . The team should aim to perform deﬁnitive anastomoses, vascular recon struction and closure of  the body cavity within 24–72 hours of  injury . However, this must be individualised to the patient, the response to critical care resuscitation and the progression of injury . /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The abdomen is closed as soon as possible, bearing in mind the risks of  abdominal compartment syndrome (ACS). The closure is not without its own morbidity . Successful closure may require aggressive o ﬀ -loading of  ﬂuid and even haemo ﬁltration to achieve this if  the patient will tolerate it. The best situation is closure of  the abdominal fascia, or, if  this cannot be achieved, then skin closure only . Occasionally , mesh closure can be used, with skin g rafting over the mesh and subsequent abdominal wall reconstruction. Thoracic damage control is conceptually based on the same philosophy . This is that haemorrhage control and focused surgical procedures minimise further surgical insult and lead to improved survival in the unstable trauma patient. T he aim is to control bleeding and limit air leaks using the fastest procedures available, such as staplers, to minimise the operative time. surgery have already been described. Damage control applies equally to the extremities. In this case, it is shunting of  blood vessels, identifying and marking damaged structures such as nerves, fasciotomy and removal of contaminated tissue that are the main tasks . Subsequent deﬁn - itive management can be carried out at a later stage. Summary box 29.9 Damage control /uni25CF - /uni25CF /uni25CF /uni25CF 

Stage
Intervention
I
Patient selection
II
Control of haemorrhage and control of contamination
III
Resuscitation continued in the intensive care unit
IV
De
/f_i
nitive surgery
V
Abdominal closure
TABLE 29.7
Indications for damage control surgery.
Inability to achieve haemostasis
Anatomical
Complex abdominal injury, e.g. liver and
pancreas
Combined vascular, solid and hollow
organ injury, e.g. aortic or caval injury
Inaccessible major venous injury, e.g.
retrohepatic vena cava
Demand for non-operative control of other
injuries, e.g. fractured pelvis
Anticipated need for a time-consuming
procedure
Physiological
Temperature <34°C
(decline of
pH <7.2
physiological
Serum lactate >5
/uni00A0
mmol/L (normal:
reserve)
<2.5
/uni00A0
mmol/L)
Prothrombin time >16
/uni00A0
s
Partial thromboplastin time >60
/uni00A0
s
>10 units blood transfused
Systolic blood pressure <90
/uni00A0
mmHg for
>60 min
Environmental
Operating time >60 min (core temperature
loss is usually 2°C/h)
Inability to approximate the abdominal
incision
Desire to reassess the intra-abdominal
contents (directed relook)
Resuscitation is carried out in the operating theatre using
biologically active
/f_l
uids (i.e. blood) – damage control
resuscitation
The surgery performed is the minimum needed to stabilise the
patient
The aims of surgery are to control haemorrhage and limit
contamination
Secondary surgery is aimed at de
/f_i
nitive repair

# Diagnosis

Diagnosis

Radiograph Examination of  a plain radiograph of  the pelvis requires an understanding of  the mechanism of  injury and a decision on the stability of  the pelvic rim. It is important to note that the vast majority of  patients with suspected pelvic fractures may have a pelvic binder in place and hence plain radiograph ﬁndings may be normal. FAST may be unreliable as it does not localise intra-abdominal bleeding in these patients. CT is the diagnostic modality of  choice in the physiologically helpful in providing details of  both the anatomy of  the fracture and the origin of  the bleeding (venous or arterial). An open book-type mechanism causes one or both ilia to - rotate externally (opening, like a book). A la teral compression mechanism causes the pelvis to collapse. An ‘open book frac - ture’ is seen as a widening of  the pubic symphysis or widening at the site of  a fracture in the pubic ramus. Not only is there dis - ruption of  the bony pelvis, but also tearing of  the pelvic ﬂoor and thus the pelvic venous plexus is at risk. T he more unstable the pelvis, the more likely the structures are to be damaged. When the pelvis collapses from a lateral compression injury , the pubic bones usually fracture . Displacement of  the anterior pelvis by greater than 2 /uni00A0 cm indicates at least partial instability . A vertical shear disruption of  the sacroiliac joint with apparent shortening of  the limb on the a ﬀ ected side implies signiﬁcant energy of  injury . Diagnosis

Radiograph Examination of  a plain radiograph of  the pelvis requires an understanding of  the mechanism of  injury and a decision on the stability of  the pelvic rim. It is important to note that the vast majority of  patients with suspected pelvic fractures may have a pelvic binder in place and hence plain radiograph ﬁndings may be normal. FAST may be unreliable as it does not localise intra-abdominal bleeding in these patients. CT is the diagnostic modality of  choice in the physiologically helpful in providing details of  both the anatomy of  the fracture and the origin of  the bleeding (venous or arterial). An open book-type mechanism causes one or both ilia to - rotate externally (opening, like a book). A la teral compression mechanism causes the pelvis to collapse. An ‘open book frac - ture’ is seen as a widening of  the pubic symphysis or widening at the site of  a fracture in the pubic ramus. Not only is there dis - ruption of  the bony pelvis, but also tearing of  the pelvic ﬂoor and thus the pelvic venous plexus is at risk. T he more unstable the pelvis, the more likely the structures are to be damaged. When the pelvis collapses from a lateral compression injury , the pubic bones usually fracture . Displacement of  the anterior pelvis by greater than 2 /uni00A0 cm indicates at least partial instability . A vertical shear disruption of  the sacroiliac joint with apparent shortening of  the limb on the a ﬀ ected side implies signiﬁcant energy of  injury . Diagnosis

Radiograph Examination of  a plain radiograph of  the pelvis requires an understanding of  the mechanism of  injury and a decision on the stability of  the pelvic rim. It is important to note that the vast majority of  patients with suspected pelvic fractures may have a pelvic binder in place and hence plain radiograph ﬁndings may be normal. FAST may be unreliable as it does not localise intra-abdominal bleeding in these patients. CT is the diagnostic modality of  choice in the physiologically helpful in providing details of  both the anatomy of  the fracture and the origin of  the bleeding (venous or arterial). An open book-type mechanism causes one or both ilia to - rotate externally (opening, like a book). A la teral compression mechanism causes the pelvis to collapse. An ‘open book frac - ture’ is seen as a widening of  the pubic symphysis or widening at the site of  a fracture in the pubic ramus. Not only is there dis - ruption of  the bony pelvis, but also tearing of  the pelvic ﬂoor and thus the pelvic venous plexus is at risk. T he more unstable the pelvis, the more likely the structures are to be damaged. When the pelvis collapses from a lateral compression injury , the pubic bones usually fracture . Displacement of  the anterior pelvis by greater than 2 /uni00A0 cm indicates at least partial instability . A vertical shear disruption of  the sacroiliac joint with apparent shortening of  the limb on the a ﬀ ected side implies signiﬁcant energy of  injury .

# Diagnostic peritoneal lavage

Diagnostic peritoneal lavage

Diagnostic peritoneal lavage (DPL) is a test rarely used in modern-day practice but can be of  value in resource-limited settings. It is a test used to assess the presence of  blood or contaminants in the abdomen. A nasogastric tube is placed to empty the stomach and a urinary catheter is inserted to drain the bladder. A cannula is inserted below the umbilicus, directed caudally and posteriorly . The cannula is aspirated for blood (>10 /uni00A0 mL is deemed as positive) and, following this, 500 /uni00A0 mL of  warmed Ringer’s lactate solution is allo wed to run into the abdomen from a 1-litre bag. The bag, with 500 /uni00A0 mL remaining, is placed on the ﬂoor and the intra-abdominal ﬂuid is allowed to ﬂow under the inﬂuence of gravity – this aids drainage. The pres - ence of  frank blood or similar contents to a nasogastric tube or urinary catheter denotes a positive DPL. If  time allows and laboratory diagnosis is available, the presence of  >100 /uni00A0 000 red cells/µL or >500 white cells/µL is deemed positive (this is equiv alent to 20 /uni00A0 mL of  free blood in the abdominal cavity), as is a raised amylase level. In the absence of  laboratory facilities, a urine dipstick may be useful. Drainage of  lavage ﬂuid via a chest drain indicates penetration of  the diaphragm. Although DPL has largely been replaced by eFAST (see Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) ), it remains the standard in many institutions where eFAST is not available or is unre - liable. Diagnostic peritoneal lavage

Diagnostic peritoneal lavage (DPL) is a test rarely used in modern-day practice but can be of  value in resource-limited settings. It is a test used to assess the presence of  blood or contaminants in the abdomen. A nasogastric tube is placed to empty the stomach and a urinary catheter is inserted to drain the bladder. A cannula is inserted below the umbilicus, directed caudally and posteriorly . The cannula is aspirated for blood (>10 /uni00A0 mL is deemed as positive) and, following this, 500 /uni00A0 mL of  warmed Ringer’s lactate solution is allo wed to run into the abdomen from a 1-litre bag. The bag, with 500 /uni00A0 mL remaining, is placed on the ﬂoor and the intra-abdominal ﬂuid is allowed to ﬂow under the inﬂuence of gravity – this aids drainage. The pres - ence of  frank blood or similar contents to a nasogastric tube or urinary catheter denotes a positive DPL. If  time allows and laboratory diagnosis is available, the presence of  >100 /uni00A0 000 red cells/µL or >500 white cells/µL is deemed positive (this is equiv alent to 20 /uni00A0 mL of  free blood in the abdominal cavity), as is a raised amylase level. In the absence of  laboratory facilities, a urine dipstick may be useful. Drainage of  lavage ﬂuid via a chest drain indicates penetration of  the diaphragm. Although DPL has largely been replaced by eFAST (see Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) ), it remains the standard in many institutions where eFAST is not available or is unre - liable. Diagnostic peritoneal lavage

Diagnostic peritoneal lavage (DPL) is a test rarely used in modern-day practice but can be of  value in resource-limited settings. It is a test used to assess the presence of  blood or contaminants in the abdomen. A nasogastric tube is placed to empty the stomach and a urinary catheter is inserted to drain the bladder. A cannula is inserted below the umbilicus, directed caudally and posteriorly . The cannula is aspirated for blood (>10 /uni00A0 mL is deemed as positive) and, following this, 500 /uni00A0 mL of  warmed Ringer’s lactate solution is allo wed to run into the abdomen from a 1-litre bag. The bag, with 500 /uni00A0 mL remaining, is placed on the ﬂoor and the intra-abdominal ﬂuid is allowed to ﬂow under the inﬂuence of gravity – this aids drainage. The pres - ence of  frank blood or similar contents to a nasogastric tube or urinary catheter denotes a positive DPL. If  time allows and laboratory diagnosis is available, the presence of  >100 /uni00A0 000 red cells/µL or >500 white cells/µL is deemed positive (this is equiv alent to 20 /uni00A0 mL of  free blood in the abdominal cavity), as is a raised amylase level. In the absence of  laboratory facilities, a urine dipstick may be useful. Drainage of  lavage ﬂuid via a chest drain indicates penetration of  the diaphragm. Although DPL has largely been replaced by eFAST (see Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) ), it remains the standard in many institutions where eFAST is not available or is unre - liable.

# Duodenum

Duodenum

Duodenal injury is frequently associated with injuries to the adjoining pancreas. Like the pancreas, the duodenum lies retroperitoneally and so injuries are hidden, discovered late or at laparotomy performed for other reasons. CT is the diagnostic modality of choice. The only sign may be gas or a ﬂuid collection in the periduodenal tissue, and leakage of  oral contrast, administration of  which may improve accuracy of diagnosis. Smaller injuries can be repaired primarily . The ﬁrst, third and fourth parts of  the duodenum behave like small bowel and can be repaired in the same fashion. The second part of  the duodenum is ﬁxed to the head of the pancreas with a common blood supply and may have a poorer blood supply than the remainder. Major trauma, especially if  the head of the pan - - creas is simultaneously injured, should be treated as part of  a damage control procedure and be referred for deﬁnitive care. Duodenum

Duodenal injury is frequently associated with injuries to the adjoining pancreas. Like the pancreas, the duodenum lies retroperitoneally and so injuries are hidden, discovered late or at laparotomy performed for other reasons. CT is the diagnostic modality of choice. The only sign may be gas or a ﬂuid collection in the periduodenal tissue, and leakage of  oral contrast, administration of  which may improve accuracy of diagnosis. Smaller injuries can be repaired primarily . The ﬁrst, third and fourth parts of  the duodenum behave like small bowel and can be repaired in the same fashion. The second part of  the duodenum is ﬁxed to the head of the pancreas with a common blood supply and may have a poorer blood supply than the remainder. Major trauma, especially if  the head of the pan - - creas is simultaneously injured, should be treated as part of  a damage control procedure and be referred for deﬁnitive care. Duodenum

Duodenal injury is frequently associated with injuries to the adjoining pancreas. Like the pancreas, the duodenum lies retroperitoneally and so injuries are hidden, discovered late or at laparotomy performed for other reasons. CT is the diagnostic modality of choice. The only sign may be gas or a ﬂuid collection in the periduodenal tissue, and leakage of  oral contrast, administration of  which may improve accuracy of diagnosis. Smaller injuries can be repaired primarily . The ﬁrst, third and fourth parts of  the duodenum behave like small bowel and can be repaired in the same fashion. The second part of  the duodenum is ﬁxed to the head of the pancreas with a common blood supply and may have a poorer blood supply than the remainder. Major trauma, especially if  the head of the pan - - creas is simultaneously injured, should be treated as part of  a damage control procedure and be referred for deﬁnitive care.

# EMERGENCY THORACIC SURGERY

EMERGENCY THORACIC SURGERY

Emergency thoracic surgery is an essential part of  the arma - mentarium of  any surgeon dealing with major trauma. A - timely surgical intervention for the correct indications can be the key step in saving an injured patient’s life. It is important to make a distinction between: - /uni25CF immediate thoracotomy in the emergency department for the control of  haemorrhage, cardiac tamponade or inter - nal cardiac massage; /uni25CF emergency sternotomy for anterior mediastinal structures and the heart; /uni25CF planned thoracotomy for deﬁnitive correction of  the prob - lem – this usually takes place in the more controlled envi - ronment of  the operating theatre. - The clinical decision as to whether a patient requires sur - - gery in the emergency department or they can be transferred to the operating theatre can be complex. It is far better to per - form a thoracotomy in the operating theatre, either through t an anterolateral approach or a median ster notomy , with good light and assistance and the potential for autotransfusion or bypass, than it is to attempt heroic emergency surgery in the resuscita tion area. However, if  the patient is in extremis with a falling systolic blood pressure, there is no choice but to pro - ceed immediately with a left anterolateral thoracotomy . In cer - tain circumstances, when care is futile, it may not need to be performed at all. A resuscitation room thoracotomy following blunt trauma has limited indications and is rarely successful. EMERGENCY THORACIC SURGERY

Emergency thoracic surgery is an essential part of  the arma - mentarium of  any surgeon dealing with major trauma. A - timely surgical intervention for the correct indications can be the key step in saving an injured patient’s life. It is important to make a distinction between: - /uni25CF immediate thoracotomy in the emergency department for the control of  haemorrhage, cardiac tamponade or inter - nal cardiac massage; /uni25CF emergency sternotomy for anterior mediastinal structures and the heart; /uni25CF planned thoracotomy for deﬁnitive correction of  the prob - lem – this usually takes place in the more controlled envi - ronment of  the operating theatre. - The clinical decision as to whether a patient requires sur - - gery in the emergency department or they can be transferred to the operating theatre can be complex. It is far better to per - form a thoracotomy in the operating theatre, either through t an anterolateral approach or a median ster notomy , with good light and assistance and the potential for autotransfusion or bypass, than it is to attempt heroic emergency surgery in the resuscita tion area. However, if  the patient is in extremis with a falling systolic blood pressure, there is no choice but to pro - ceed immediately with a left anterolateral thoracotomy . In cer - tain circumstances, when care is futile, it may not need to be performed at all. A resuscitation room thoracotomy following blunt trauma has limited indications and is rarely successful. EMERGENCY THORACIC SURGERY

Emergency thoracic surgery is an essential part of  the arma - mentarium of  any surgeon dealing with major trauma. A - timely surgical intervention for the correct indications can be the key step in saving an injured patient’s life. It is important to make a distinction between: - /uni25CF immediate thoracotomy in the emergency department for the control of  haemorrhage, cardiac tamponade or inter - nal cardiac massage; /uni25CF emergency sternotomy for anterior mediastinal structures and the heart; /uni25CF planned thoracotomy for deﬁnitive correction of  the prob - lem – this usually takes place in the more controlled envi - ronment of  the operating theatre. - The clinical decision as to whether a patient requires sur - - gery in the emergency department or they can be transferred to the operating theatre can be complex. It is far better to per - form a thoracotomy in the operating theatre, either through t an anterolateral approach or a median ster notomy , with good light and assistance and the potential for autotransfusion or bypass, than it is to attempt heroic emergency surgery in the resuscita tion area. However, if  the patient is in extremis with a falling systolic blood pressure, there is no choice but to pro - ceed immediately with a left anterolateral thoracotomy . In cer - tain circumstances, when care is futile, it may not need to be performed at all. A resuscitation room thoracotomy following blunt trauma has limited indications and is rarely successful.

# Emergency department thoracotomy or sternotomy

Emergency department thoracotomy or sternotomy

Emergency department thoracotomy (EDT) should be reserved - for those patients with penetrating injury in whom signs of  life are still present. Patients who have received cardiopulmonary resuscitation (CPR) in the prehospital phase of  their care are unlikely to survive, and electrical activity must be present. In certain situations, EDT is considered futile: - /uni25CF CPR for more than 15 minutes (despite endotracheal intu - bation) in the presence of  penetrating thoracic trauma; /uni25CF CPR for more than 10 minutes (despite endotracheal intu - bation) in the presence of  blunt thoracic trauma; /uni25CF blunt trauma when there have been no signs of  life at the scene. trauma in whom the blood pressure is falling despite adequate resuscitation are shown in Table 29.4 . The aim of  EDT is to perform: /uni25CF internal cardiac massage in the cardiovascularly ‘full’ patient (no role for internal massage in the ‘empty’ patient); /uni25CF control of  haemorrhage from injury to the heart or lung; /uni25CF control of  intrathoracic haemorrhage from other sources; /uni25CF control of  massive air leak; /uni25CF clamping of  the thoracic aorta to preserve the blood sup ply to the heart and brain, and cutting o ﬀ the arterial sup ply distally , in a moribund patient with a major distal pen etrating injury . 

TABLE 29.4
Survival rates for thoracotomy in patients
with penetrating trauma.
Blood pressure despite resuscitation
Survival
>60
/uni00A0
mmHg
60%
>40
/uni00A0
mmHg
30%
<40
/uni00A0
mmHg
3%

Emergency department thoracotomy or sternotomy

Emergency department thoracotomy (EDT) should be reserved - for those patients with penetrating injury in whom signs of  life are still present. Patients who have received cardiopulmonary resuscitation (CPR) in the prehospital phase of  their care are unlikely to survive, and electrical activity must be present. In certain situations, EDT is considered futile: - /uni25CF CPR for more than 15 minutes (despite endotracheal intu - bation) in the presence of  penetrating thoracic trauma; /uni25CF CPR for more than 10 minutes (despite endotracheal intu - bation) in the presence of  blunt thoracic trauma; /uni25CF blunt trauma when there have been no signs of  life at the scene. trauma in whom the blood pressure is falling despite adequate resuscitation are shown in Table 29.4 . The aim of  EDT is to perform: /uni25CF internal cardiac massage in the cardiovascularly ‘full’ patient (no role for internal massage in the ‘empty’ patient); /uni25CF control of  haemorrhage from injury to the heart or lung; /uni25CF control of  intrathoracic haemorrhage from other sources; /uni25CF control of  massive air leak; /uni25CF clamping of  the thoracic aorta to preserve the blood sup ply to the heart and brain, and cutting o ﬀ the arterial sup ply distally , in a moribund patient with a major distal pen etrating injury . 

TABLE 29.4
Survival rates for thoracotomy in patients
with penetrating trauma.
Blood pressure despite resuscitation
Survival
>60
/uni00A0
mmHg
60%
>40
/uni00A0
mmHg
30%
<40
/uni00A0
mmHg
3%

Emergency department thoracotomy or sternotomy

Emergency department thoracotomy (EDT) should be reserved - for those patients with penetrating injury in whom signs of  life are still present. Patients who have received cardiopulmonary resuscitation (CPR) in the prehospital phase of  their care are unlikely to survive, and electrical activity must be present. In certain situations, EDT is considered futile: - /uni25CF CPR for more than 15 minutes (despite endotracheal intu - bation) in the presence of  penetrating thoracic trauma; /uni25CF CPR for more than 10 minutes (despite endotracheal intu - bation) in the presence of  blunt thoracic trauma; /uni25CF blunt trauma when there have been no signs of  life at the scene. trauma in whom the blood pressure is falling despite adequate resuscitation are shown in Table 29.4 . The aim of  EDT is to perform: /uni25CF internal cardiac massage in the cardiovascularly ‘full’ patient (no role for internal massage in the ‘empty’ patient); /uni25CF control of  haemorrhage from injury to the heart or lung; /uni25CF control of  intrathoracic haemorrhage from other sources; /uni25CF control of  massive air leak; /uni25CF clamping of  the thoracic aorta to preserve the blood sup ply to the heart and brain, and cutting o ﬀ the arterial sup ply distally , in a moribund patient with a major distal pen etrating injury . 

TABLE 29.4
Survival rates for thoracotomy in patients
with penetrating trauma.
Blood pressure despite resuscitation
Survival
>60
/uni00A0
mmHg
60%
>40
/uni00A0
mmHg
30%
<40
/uni00A0
mmHg
3%

# INDIVIDUAL ORGAN INJURY Liver

INDIVIDUAL ORGAN INJURY Liver

Blunt liver trauma occurs as a result of  direct injury . The liver is a solid organ and compressive forces can easily burst the liver substance ( Figure 29.8 ). The liver is usually compressed between the impacting object and the ribcage or vertebral column. Most injuries are relatively minor and can be managed non-operatively . James Hogarth Pringle , 1863–1941, Australian-born surgeon, The Royal Inﬁrmary , Glasgow , UK. Robert William Sengstaken , 1923–1978, surgeon, Garden City , NY , USA, and The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA, designed a tube with two in-built balloons for the treatment of  oesophageal varices. The tube was passed and the distal balloon inﬂated. The tube was drawn backwards until the distal balloon was held at the oesophageal hiatus. The proximal balloon was inﬂated, allowing tamponade of  any varices in the distal oesophagus. lets have a shock wave and when they pass through a solid structure such as the liver they cause signiﬁcant damage some distance from the actual track of  the bullet. Not all penetrating y stop bleeding wounds require operativ e management and ma spontaneously . In the physiologically non-compromised patient, CT is the investigation of  choice. It provides information on the liver injury itself, as well as on injuries to the adjoining major vascu - lar and biliary structures. Injury in which there is a suggestion of  a vascular component should be reimaged, as there is a sig - niﬁcant risk of  the development of  subsequent ischaemia, false aneurysms, arteriovenous ﬁstulae or haemobiliary ﬁstula. It is advised that all patients should be rescanned prior to discharge. Liver injury can be graded and managed using the American Association for the Surgery of  Trauma (AAST) Injury Scoring Scale (ISS) (https://www .aast.org/resources - detail/injury-scoring-scale). 

-

INDIVIDUAL ORGAN INJURY Liver

Blunt liver trauma occurs as a result of  direct injury . The liver is a solid organ and compressive forces can easily burst the liver substance ( Figure 29.8 ). The liver is usually compressed between the impacting object and the ribcage or vertebral column. Most injuries are relatively minor and can be managed non-operatively . James Hogarth Pringle , 1863–1941, Australian-born surgeon, The Royal Inﬁrmary , Glasgow , UK. Robert William Sengstaken , 1923–1978, surgeon, Garden City , NY , USA, and The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA, designed a tube with two in-built balloons for the treatment of  oesophageal varices. The tube was passed and the distal balloon inﬂated. The tube was drawn backwards until the distal balloon was held at the oesophageal hiatus. The proximal balloon was inﬂated, allowing tamponade of  any varices in the distal oesophagus. lets have a shock wave and when they pass through a solid structure such as the liver they cause signiﬁcant damage some distance from the actual track of  the bullet. Not all penetrating y stop bleeding wounds require operativ e management and ma spontaneously . In the physiologically non-compromised patient, CT is the investigation of  choice. It provides information on the liver injury itself, as well as on injuries to the adjoining major vascu - lar and biliary structures. Injury in which there is a suggestion of  a vascular component should be reimaged, as there is a sig - niﬁcant risk of  the development of  subsequent ischaemia, false aneurysms, arteriovenous ﬁstulae or haemobiliary ﬁstula. It is advised that all patients should be rescanned prior to discharge. Liver injury can be graded and managed using the American Association for the Surgery of  Trauma (AAST) Injury Scoring Scale (ISS) (https://www .aast.org/resources - detail/injury-scoring-scale). 

-

INDIVIDUAL ORGAN INJURY Liver

Blunt liver trauma occurs as a result of  direct injury . The liver is a solid organ and compressive forces can easily burst the liver substance ( Figure 29.8 ). The liver is usually compressed between the impacting object and the ribcage or vertebral column. Most injuries are relatively minor and can be managed non-operatively . James Hogarth Pringle , 1863–1941, Australian-born surgeon, The Royal Inﬁrmary , Glasgow , UK. Robert William Sengstaken , 1923–1978, surgeon, Garden City , NY , USA, and The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA, designed a tube with two in-built balloons for the treatment of  oesophageal varices. The tube was passed and the distal balloon inﬂated. The tube was drawn backwards until the distal balloon was held at the oesophageal hiatus. The proximal balloon was inﬂated, allowing tamponade of  any varices in the distal oesophagus. lets have a shock wave and when they pass through a solid structure such as the liver they cause signiﬁcant damage some distance from the actual track of  the bullet. Not all penetrating y stop bleeding wounds require operativ e management and ma spontaneously . In the physiologically non-compromised patient, CT is the investigation of  choice. It provides information on the liver injury itself, as well as on injuries to the adjoining major vascu - lar and biliary structures. Injury in which there is a suggestion of  a vascular component should be reimaged, as there is a sig - niﬁcant risk of  the development of  subsequent ischaemia, false aneurysms, arteriovenous ﬁstulae or haemobiliary ﬁstula. It is advised that all patients should be rescanned prior to discharge. Liver injury can be graded and managed using the American Association for the Surgery of  Trauma (AAST) Injury Scoring Scale (ISS) (https://www .aast.org/resources - detail/injury-scoring-scale). 

-

# INJURY MECHANISMS ASSOCIATED WITH TORSO TRAUMA

INJURY MECHANISMS ASSOCIATED WITH TORSO TRAUMA

- Injury consistently traverses di ﬀ erent anatomical zones of  the body , a ﬀ ecting structures on both sides of  traditional anatomi - cal zones. These zones are known as junctional zones. INJURY MECHANISMS ASSOCIATED WITH TORSO TRAUMA

- Injury consistently traverses di ﬀ erent anatomical zones of  the body , a ﬀ ecting structures on both sides of  traditional anatomi - cal zones. These zones are known as junctional zones. INJURY MECHANISMS ASSOCIATED WITH TORSO TRAUMA

- Injury consistently traverses di ﬀ erent anatomical zones of  the body , a ﬀ ecting structures on both sides of  traditional anatomi - cal zones. These zones are known as junctional zones.

# INTERVENTIONAL RADIOLOGY

INTERVENTIONAL RADIOLOGY

Interventional radiology can be useful in the management of torso trauma as both an investigative and a therapeutic tool for patients with vascular injury . Angioembolisation following demonstration of  ongoing bleeding in splenic and renal injury is a valuable technique. Non-operative management is generally preferred for the management of  solid organ injury in physiologically non- compromised children. Non-operative management of  solid abdominal organ injury has rapidly gained acceptance in the management of  adults as well. A stable patient and accurate CT imaging are prerequisites for this approach. Failure of non-operative management is uncommon and typically occurs within the ﬁrst 12 hours after injury . Therefore, if  correctly selected, the vast majority of  these patients will avoid surgery , require less blood transfusion and sustain fewer complications than operated patients. INTERVENTIONAL RADIOLOGY

Interventional radiology can be useful in the management of torso trauma as both an investigative and a therapeutic tool for patients with vascular injury . Angioembolisation following demonstration of  ongoing bleeding in splenic and renal injury is a valuable technique. Non-operative management is generally preferred for the management of  solid organ injury in physiologically non- compromised children. Non-operative management of  solid abdominal organ injury has rapidly gained acceptance in the management of  adults as well. A stable patient and accurate CT imaging are prerequisites for this approach. Failure of non-operative management is uncommon and typically occurs within the ﬁrst 12 hours after injury . Therefore, if  correctly selected, the vast majority of  these patients will avoid surgery , require less blood transfusion and sustain fewer complications than operated patients. INTERVENTIONAL RADIOLOGY

Interventional radiology can be useful in the management of torso trauma as both an investigative and a therapeutic tool for patients with vascular injury . Angioembolisation following demonstration of  ongoing bleeding in splenic and renal injury is a valuable technique. Non-operative management is generally preferred for the management of  solid organ injury in physiologically non- compromised children. Non-operative management of  solid abdominal organ injury has rapidly gained acceptance in the management of  adults as well. A stable patient and accurate CT imaging are prerequisites for this approach. Failure of non-operative management is uncommon and typically occurs within the ﬁrst 12 hours after injury . Therefore, if  correctly selected, the vast majority of  these patients will avoid surgery , require less blood transfusion and sustain fewer complications than operated patients.

# Immediate life-threatening injuries

Immediate life-threatening injuries

Airway obstruction Early intubation is very important, particularly in cases of  neck haematoma or possible airway oedema. Airway distortion can be insidious and progressive and can make delayed intubation more di ﬃ cult if  not impossible. Tension pneumothorax A tension pneumothorax develops when a ‘one-way valve’ air leak occurs either from the lung or through the chest wall. Air is sucked into the thoracic cavity without any means of  escape, completely collapsing and then compressing the a ﬀ ected lung. The mediastinum is displaced to the opposite side, decreasing venous return and compressing the opposite lung. The most common causes are penetrating chest trauma, blunt chest trauma with a parenchymal lung injury and air leak that did not spontaneously close, iatrogenic lung injury (e.g. due to central venepuncture) and mechanical positiv e-pressure ventilation. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The clinical presentation is dramatic. The patient is increas ingly restless with tachypnoea, dyspnoea and distended neck veins (similar to pericardial tamponade). Clinical examination may reveal tracheal deviation; this is a late ﬁnding and is not - necessary to clinically conﬁrm diagnosis. There will also be hyper-resonance and decreased or absent breath sounds over the a ﬀ ected hemithorax. Tension pneumothorax is a clinical diagnosis and treatment should never be delayed by waiting for radiological conﬁrmation. Always treat it with a high index of  suspicion of  being present ( Figure 29.3 ). Treatment consists of  immediate decompression. This was historically taught by rapid insertion of  a large-bore cannula into the second intercostal space in the mid-clavicular line of the a ﬀ ected side, follo wed by insertion of  a chest tube through the ﬁfth intercostal space in the anterior axillary line. However, current teaching advocates undertaking decompression in the safe triangle – deﬁned posteriorly by latissimus dorsi, anteriorly by the lateral border of pectoralis major and inferiorly by a line perpendicular to the nipple going to the back, just anterior to the mid-axillary line – or, in extremis, a ﬁnger thoracostomy at the same location. Pericardial tamponade Pericardial tamponade needs to be di ﬀ erentiated from a tension pneumothorax in the shocked patient with distended neck veins. It is most commonly the result of  penetrating trauma. Accumulation of  a relatively small amount of  blood (50 /uni00A0 mL) into the non-distensible pericardial sac can produce compression of  the heart and obstruction of  the venous return, leading to decreased ﬁlling of  the cardiac chambers during diastole. All patients with penetrating injury anywhere near the - heart plus shock must be considered to have a cardiac injury until proven otherwise. Classically , the presentation consists of central venous pressure elevation, a decline in arterial pressure with tachycardia and mu ﬄ ed heart sounds. However, in cases 

TABLE 29.3
The ‘deadly dozen’ threats to life from chest
injury.
Immediately life-
Airway obstruction
threatening
Tension pneumothorax
Pericardial tamponade
Open pneumothorax
Massive haemothorax
Flail chest
Potentially life-
Aortic injuries
threatening
Tracheobronchial injuries
Myocardial contusion
Rupture of the diaphragm
Oesophageal injuries
Pulmonary contusion
Figure 29.3
Radiological appearance of a tension pneumothorax
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

neck veins may be ﬂat. A high index of  suspicion and further diagnostic investigations will be needed to make the diagnosis is those cases that are not clinically obvious. These include an eFAST showing ﬂuid in the pericardial sac, which is the most expeditious and reliable diagnostic tool, or chest radiography , looking for an enlarged heart shadow . In penetrating injury to the heart there is usually a sub stantial clot in the pericardium, which may prevent aspiration. Pericardiocentesis has no role in the management of  cardiac tamponade secondary to penetrating myocardial injury . The correct immediate treatment of tamponade is operative, either via a subxiphoid window or by open surgery (sternotomy or left anterolateral thoracotomy), with repair of  the heart in the operating theatre if  time allows or otherwise in the emergency department. Summary box 29.4 Pericardial tamponade /uni25CF /uni25CF /uni25CF Open pneumothorax (‘sucking chest wound’) This is due to a large open defect in the chest (>3 /uni00A0 cm), lead ing to immediate equilibration between intrathoracic and atmospheric pressure. If  the opening in the chest wall exceeds about two-thirds of  the diameter of  the trachea, then with each inspiratory cycle air will be pr eferentially drawn through the defect rather than through the trachea. Air accumulates in the hemithorax (rather than in the lung) with each inspiration, leading to profound hypoventilation on the a ﬀ ected side and hypoxia. If  there is a valvular e ﬀ ect, increasing amounts of air in the pleura will result in a tension pneumothorax (see Tension pneumothorax ). Initial management consists of  promptly closing the defect ◊ with a sterile occlusive plastic dressing (e.g. OPSITE or similar product), taped on three sides to act as a ﬂutter-type valve. A chest tube is inserted as soon as possible in a site remote from the injury site. Massive haemothorax The most common cause of  massive haemothorax in blunt injury is continuing bleeding from torn intercostal vessels or occasionally from the internal mammary artery secondary to fractures of the ribs. In penetrating injury , a variety of viscera, both thoracic and abdominal (with blood leaking through a hole in the diaphragm from the positive pressure abdomen into the negative pressure thorax), may be involved. ◊ Trademark of  Smith+Nephew. compromise respiratory e ﬀ orts, compressing the lung and preventing adequate ventilation. Presenta tion is with haemorrhagic shock, ﬂat neck veins, unilateral absence of breath sounds and dullness to percussion. The initial treatment consists of  correcting the hypovolaemic shock, insertion of  an intercostal drain and, in some cases, intubation. Initial drainage - of  more than 1500 /uni00A0 mL of  blood or ongoing haemorrhage of more than 200 /uni00A0 mL/h over 3–4 hours is generally considered an indication for urgent thoracotomy . Blood in the pleural space should be removed as completely and rapidly as possible to prevent ongoing bleeding, an empy - There is no role for clamping a ema or ﬁbr othorax later. chest tube to tamponade a massive haemothorax . The following points are important in the management of an open pneumothorax/haemothorax: /uni25CF if  the lung does not reinﬂate, the drain should be placed on low-pressure (5 /uni00A0 cmH O) suction; 2 /uni25CF clot occlusion of  a chest drainage tube may result in ‘no’ drainage, even in the presence of  ongoing bleeding; /uni25CF a second drain is sometimes necessary (but see Tracheobronchial injuries ); /uni25CF a chest radiograph or eFAST can help identify the pres - ence of  blood; /uni25CF physiotherapy and active mobilisation should begin as soon as possible. Flail chest This condition usually results from blunt trauma associated with multiple rib fractures, and is deﬁned as three or more ribs fractured in two or more places. The blunt force typically - also produces an underlying pulmonary contusion. The diagnosis is made clinically in patients who are not ventilated, not by radiography . To conﬁrm the diagnosis the chest wall can be observed for paradoxical motion of a chest wall segment. On inspiration, the loose segment of  the chest wall is displaced inwards and therefore less air moves into the lungs. On expiration, the segment moves outwards (paradoxical respiration). V oluntary splinting of  the chest wall occurs as a result of  pain, so mechanically impaired chest wall movement and the associated lung contusion all contribute to the hypoxia. There is a high risk of  developing a pneumothorax or haemothorax. The CT scan remains the gold standard for diagnosis of  this condition. Traditionally , mechanical ventilation was used to ‘internally splint’ the chest but had a price in terms of  intensive care unit (ICU) resources and ventilation-dependent morbidity . Currently , treatment consists of  oxygen administration, adequate analgesia (including opiates) and physiotherapy . If a chest tube is in place, topical intrapleural local analgesia introduced via the tube can also be used. V entilation is reserved for patients developing respiratory failure despite adequate analgesia and oxygen. Surgery to stabilise the ﬂail segment using internal ﬁxation of  the ribs may be useful in a selected group of  patients with isolated or severe chest injury and pulmonary contusion. 

The presentation is similar to a tension pneumothorax –
deteriorating cyanosis, tachycardia and agitation
eFAST is diagnostic and may also detect free
/f_l
uid in the
abdomen or pericardium
There is no role for pericardiocentesis in traumatic cardiac
tamponade. A left anterolateral thoracotomy or sternotomy
should be performed with evacuation of the haematoma and
repair of the myocardium



Figure 29.4
Chest radiograph showing a widened mediastinum
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

Immediate life-threatening injuries

Airway obstruction Early intubation is very important, particularly in cases of  neck haematoma or possible airway oedema. Airway distortion can be insidious and progressive and can make delayed intubation more di ﬃ cult if  not impossible. Tension pneumothorax A tension pneumothorax develops when a ‘one-way valve’ air leak occurs either from the lung or through the chest wall. Air is sucked into the thoracic cavity without any means of  escape, completely collapsing and then compressing the a ﬀ ected lung. The mediastinum is displaced to the opposite side, decreasing venous return and compressing the opposite lung. The most common causes are penetrating chest trauma, blunt chest trauma with a parenchymal lung injury and air leak that did not spontaneously close, iatrogenic lung injury (e.g. due to central venepuncture) and mechanical positiv e-pressure ventilation. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The clinical presentation is dramatic. The patient is increas ingly restless with tachypnoea, dyspnoea and distended neck veins (similar to pericardial tamponade). Clinical examination may reveal tracheal deviation; this is a late ﬁnding and is not - necessary to clinically conﬁrm diagnosis. There will also be hyper-resonance and decreased or absent breath sounds over the a ﬀ ected hemithorax. Tension pneumothorax is a clinical diagnosis and treatment should never be delayed by waiting for radiological conﬁrmation. Always treat it with a high index of  suspicion of  being present ( Figure 29.3 ). Treatment consists of  immediate decompression. This was historically taught by rapid insertion of  a large-bore cannula into the second intercostal space in the mid-clavicular line of the a ﬀ ected side, follo wed by insertion of  a chest tube through the ﬁfth intercostal space in the anterior axillary line. However, current teaching advocates undertaking decompression in the safe triangle – deﬁned posteriorly by latissimus dorsi, anteriorly by the lateral border of pectoralis major and inferiorly by a line perpendicular to the nipple going to the back, just anterior to the mid-axillary line – or, in extremis, a ﬁnger thoracostomy at the same location. Pericardial tamponade Pericardial tamponade needs to be di ﬀ erentiated from a tension pneumothorax in the shocked patient with distended neck veins. It is most commonly the result of  penetrating trauma. Accumulation of  a relatively small amount of  blood (50 /uni00A0 mL) into the non-distensible pericardial sac can produce compression of  the heart and obstruction of  the venous return, leading to decreased ﬁlling of  the cardiac chambers during diastole. All patients with penetrating injury anywhere near the - heart plus shock must be considered to have a cardiac injury until proven otherwise. Classically , the presentation consists of central venous pressure elevation, a decline in arterial pressure with tachycardia and mu ﬄ ed heart sounds. However, in cases 

TABLE 29.3
The ‘deadly dozen’ threats to life from chest
injury.
Immediately life-
Airway obstruction
threatening
Tension pneumothorax
Pericardial tamponade
Open pneumothorax
Massive haemothorax
Flail chest
Potentially life-
Aortic injuries
threatening
Tracheobronchial injuries
Myocardial contusion
Rupture of the diaphragm
Oesophageal injuries
Pulmonary contusion
Figure 29.3
Radiological appearance of a tension pneumothorax
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

neck veins may be ﬂat. A high index of  suspicion and further diagnostic investigations will be needed to make the diagnosis is those cases that are not clinically obvious. These include an eFAST showing ﬂuid in the pericardial sac, which is the most expeditious and reliable diagnostic tool, or chest radiography , looking for an enlarged heart shadow . In penetrating injury to the heart there is usually a sub stantial clot in the pericardium, which may prevent aspiration. Pericardiocentesis has no role in the management of  cardiac tamponade secondary to penetrating myocardial injury . The correct immediate treatment of tamponade is operative, either via a subxiphoid window or by open surgery (sternotomy or left anterolateral thoracotomy), with repair of  the heart in the operating theatre if  time allows or otherwise in the emergency department. Summary box 29.4 Pericardial tamponade /uni25CF /uni25CF /uni25CF Open pneumothorax (‘sucking chest wound’) This is due to a large open defect in the chest (>3 /uni00A0 cm), lead ing to immediate equilibration between intrathoracic and atmospheric pressure. If  the opening in the chest wall exceeds about two-thirds of  the diameter of  the trachea, then with each inspiratory cycle air will be pr eferentially drawn through the defect rather than through the trachea. Air accumulates in the hemithorax (rather than in the lung) with each inspiration, leading to profound hypoventilation on the a ﬀ ected side and hypoxia. If  there is a valvular e ﬀ ect, increasing amounts of air in the pleura will result in a tension pneumothorax (see Tension pneumothorax ). Initial management consists of  promptly closing the defect ◊ with a sterile occlusive plastic dressing (e.g. OPSITE or similar product), taped on three sides to act as a ﬂutter-type valve. A chest tube is inserted as soon as possible in a site remote from the injury site. Massive haemothorax The most common cause of  massive haemothorax in blunt injury is continuing bleeding from torn intercostal vessels or occasionally from the internal mammary artery secondary to fractures of the ribs. In penetrating injury , a variety of viscera, both thoracic and abdominal (with blood leaking through a hole in the diaphragm from the positive pressure abdomen into the negative pressure thorax), may be involved. ◊ Trademark of  Smith+Nephew. compromise respiratory e ﬀ orts, compressing the lung and preventing adequate ventilation. Presenta tion is with haemorrhagic shock, ﬂat neck veins, unilateral absence of breath sounds and dullness to percussion. The initial treatment consists of  correcting the hypovolaemic shock, insertion of  an intercostal drain and, in some cases, intubation. Initial drainage - of  more than 1500 /uni00A0 mL of  blood or ongoing haemorrhage of more than 200 /uni00A0 mL/h over 3–4 hours is generally considered an indication for urgent thoracotomy . Blood in the pleural space should be removed as completely and rapidly as possible to prevent ongoing bleeding, an empy - There is no role for clamping a ema or ﬁbr othorax later. chest tube to tamponade a massive haemothorax . The following points are important in the management of an open pneumothorax/haemothorax: /uni25CF if  the lung does not reinﬂate, the drain should be placed on low-pressure (5 /uni00A0 cmH O) suction; 2 /uni25CF clot occlusion of  a chest drainage tube may result in ‘no’ drainage, even in the presence of  ongoing bleeding; /uni25CF a second drain is sometimes necessary (but see Tracheobronchial injuries ); /uni25CF a chest radiograph or eFAST can help identify the pres - ence of  blood; /uni25CF physiotherapy and active mobilisation should begin as soon as possible. Flail chest This condition usually results from blunt trauma associated with multiple rib fractures, and is deﬁned as three or more ribs fractured in two or more places. The blunt force typically - also produces an underlying pulmonary contusion. The diagnosis is made clinically in patients who are not ventilated, not by radiography . To conﬁrm the diagnosis the chest wall can be observed for paradoxical motion of a chest wall segment. On inspiration, the loose segment of  the chest wall is displaced inwards and therefore less air moves into the lungs. On expiration, the segment moves outwards (paradoxical respiration). V oluntary splinting of  the chest wall occurs as a result of  pain, so mechanically impaired chest wall movement and the associated lung contusion all contribute to the hypoxia. There is a high risk of  developing a pneumothorax or haemothorax. The CT scan remains the gold standard for diagnosis of  this condition. Traditionally , mechanical ventilation was used to ‘internally splint’ the chest but had a price in terms of  intensive care unit (ICU) resources and ventilation-dependent morbidity . Currently , treatment consists of  oxygen administration, adequate analgesia (including opiates) and physiotherapy . If a chest tube is in place, topical intrapleural local analgesia introduced via the tube can also be used. V entilation is reserved for patients developing respiratory failure despite adequate analgesia and oxygen. Surgery to stabilise the ﬂail segment using internal ﬁxation of  the ribs may be useful in a selected group of  patients with isolated or severe chest injury and pulmonary contusion. 

The presentation is similar to a tension pneumothorax –
deteriorating cyanosis, tachycardia and agitation
eFAST is diagnostic and may also detect free
/f_l
uid in the
abdomen or pericardium
There is no role for pericardiocentesis in traumatic cardiac
tamponade. A left anterolateral thoracotomy or sternotomy
should be performed with evacuation of the haematoma and
repair of the myocardium



Figure 29.4
Chest radiograph showing a widened mediastinum
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

Immediate life-threatening injuries

Airway obstruction Early intubation is very important, particularly in cases of  neck haematoma or possible airway oedema. Airway distortion can be insidious and progressive and can make delayed intubation more di ﬃ cult if  not impossible. Tension pneumothorax A tension pneumothorax develops when a ‘one-way valve’ air leak occurs either from the lung or through the chest wall. Air is sucked into the thoracic cavity without any means of  escape, completely collapsing and then compressing the a ﬀ ected lung. The mediastinum is displaced to the opposite side, decreasing venous return and compressing the opposite lung. The most common causes are penetrating chest trauma, blunt chest trauma with a parenchymal lung injury and air leak that did not spontaneously close, iatrogenic lung injury (e.g. due to central venepuncture) and mechanical positiv e-pressure ventilation. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF The clinical presentation is dramatic. The patient is increas ingly restless with tachypnoea, dyspnoea and distended neck veins (similar to pericardial tamponade). Clinical examination may reveal tracheal deviation; this is a late ﬁnding and is not - necessary to clinically conﬁrm diagnosis. There will also be hyper-resonance and decreased or absent breath sounds over the a ﬀ ected hemithorax. Tension pneumothorax is a clinical diagnosis and treatment should never be delayed by waiting for radiological conﬁrmation. Always treat it with a high index of  suspicion of  being present ( Figure 29.3 ). Treatment consists of  immediate decompression. This was historically taught by rapid insertion of  a large-bore cannula into the second intercostal space in the mid-clavicular line of the a ﬀ ected side, follo wed by insertion of  a chest tube through the ﬁfth intercostal space in the anterior axillary line. However, current teaching advocates undertaking decompression in the safe triangle – deﬁned posteriorly by latissimus dorsi, anteriorly by the lateral border of pectoralis major and inferiorly by a line perpendicular to the nipple going to the back, just anterior to the mid-axillary line – or, in extremis, a ﬁnger thoracostomy at the same location. Pericardial tamponade Pericardial tamponade needs to be di ﬀ erentiated from a tension pneumothorax in the shocked patient with distended neck veins. It is most commonly the result of  penetrating trauma. Accumulation of  a relatively small amount of  blood (50 /uni00A0 mL) into the non-distensible pericardial sac can produce compression of  the heart and obstruction of  the venous return, leading to decreased ﬁlling of  the cardiac chambers during diastole. All patients with penetrating injury anywhere near the - heart plus shock must be considered to have a cardiac injury until proven otherwise. Classically , the presentation consists of central venous pressure elevation, a decline in arterial pressure with tachycardia and mu ﬄ ed heart sounds. However, in cases 

TABLE 29.3
The ‘deadly dozen’ threats to life from chest
injury.
Immediately life-
Airway obstruction
threatening
Tension pneumothorax
Pericardial tamponade
Open pneumothorax
Massive haemothorax
Flail chest
Potentially life-
Aortic injuries
threatening
Tracheobronchial injuries
Myocardial contusion
Rupture of the diaphragm
Oesophageal injuries
Pulmonary contusion
Figure 29.3
Radiological appearance of a tension pneumothorax
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

neck veins may be ﬂat. A high index of  suspicion and further diagnostic investigations will be needed to make the diagnosis is those cases that are not clinically obvious. These include an eFAST showing ﬂuid in the pericardial sac, which is the most expeditious and reliable diagnostic tool, or chest radiography , looking for an enlarged heart shadow . In penetrating injury to the heart there is usually a sub stantial clot in the pericardium, which may prevent aspiration. Pericardiocentesis has no role in the management of  cardiac tamponade secondary to penetrating myocardial injury . The correct immediate treatment of tamponade is operative, either via a subxiphoid window or by open surgery (sternotomy or left anterolateral thoracotomy), with repair of  the heart in the operating theatre if  time allows or otherwise in the emergency department. Summary box 29.4 Pericardial tamponade /uni25CF /uni25CF /uni25CF Open pneumothorax (‘sucking chest wound’) This is due to a large open defect in the chest (>3 /uni00A0 cm), lead ing to immediate equilibration between intrathoracic and atmospheric pressure. If  the opening in the chest wall exceeds about two-thirds of  the diameter of  the trachea, then with each inspiratory cycle air will be pr eferentially drawn through the defect rather than through the trachea. Air accumulates in the hemithorax (rather than in the lung) with each inspiration, leading to profound hypoventilation on the a ﬀ ected side and hypoxia. If  there is a valvular e ﬀ ect, increasing amounts of air in the pleura will result in a tension pneumothorax (see Tension pneumothorax ). Initial management consists of  promptly closing the defect ◊ with a sterile occlusive plastic dressing (e.g. OPSITE or similar product), taped on three sides to act as a ﬂutter-type valve. A chest tube is inserted as soon as possible in a site remote from the injury site. Massive haemothorax The most common cause of  massive haemothorax in blunt injury is continuing bleeding from torn intercostal vessels or occasionally from the internal mammary artery secondary to fractures of the ribs. In penetrating injury , a variety of viscera, both thoracic and abdominal (with blood leaking through a hole in the diaphragm from the positive pressure abdomen into the negative pressure thorax), may be involved. ◊ Trademark of  Smith+Nephew. compromise respiratory e ﬀ orts, compressing the lung and preventing adequate ventilation. Presenta tion is with haemorrhagic shock, ﬂat neck veins, unilateral absence of breath sounds and dullness to percussion. The initial treatment consists of  correcting the hypovolaemic shock, insertion of  an intercostal drain and, in some cases, intubation. Initial drainage - of  more than 1500 /uni00A0 mL of  blood or ongoing haemorrhage of more than 200 /uni00A0 mL/h over 3–4 hours is generally considered an indication for urgent thoracotomy . Blood in the pleural space should be removed as completely and rapidly as possible to prevent ongoing bleeding, an empy - There is no role for clamping a ema or ﬁbr othorax later. chest tube to tamponade a massive haemothorax . The following points are important in the management of an open pneumothorax/haemothorax: /uni25CF if  the lung does not reinﬂate, the drain should be placed on low-pressure (5 /uni00A0 cmH O) suction; 2 /uni25CF clot occlusion of  a chest drainage tube may result in ‘no’ drainage, even in the presence of  ongoing bleeding; /uni25CF a second drain is sometimes necessary (but see Tracheobronchial injuries ); /uni25CF a chest radiograph or eFAST can help identify the pres - ence of  blood; /uni25CF physiotherapy and active mobilisation should begin as soon as possible. Flail chest This condition usually results from blunt trauma associated with multiple rib fractures, and is deﬁned as three or more ribs fractured in two or more places. The blunt force typically - also produces an underlying pulmonary contusion. The diagnosis is made clinically in patients who are not ventilated, not by radiography . To conﬁrm the diagnosis the chest wall can be observed for paradoxical motion of a chest wall segment. On inspiration, the loose segment of  the chest wall is displaced inwards and therefore less air moves into the lungs. On expiration, the segment moves outwards (paradoxical respiration). V oluntary splinting of  the chest wall occurs as a result of  pain, so mechanically impaired chest wall movement and the associated lung contusion all contribute to the hypoxia. There is a high risk of  developing a pneumothorax or haemothorax. The CT scan remains the gold standard for diagnosis of  this condition. Traditionally , mechanical ventilation was used to ‘internally splint’ the chest but had a price in terms of  intensive care unit (ICU) resources and ventilation-dependent morbidity . Currently , treatment consists of  oxygen administration, adequate analgesia (including opiates) and physiotherapy . If a chest tube is in place, topical intrapleural local analgesia introduced via the tube can also be used. V entilation is reserved for patients developing respiratory failure despite adequate analgesia and oxygen. Surgery to stabilise the ﬂail segment using internal ﬁxation of  the ribs may be useful in a selected group of  patients with isolated or severe chest injury and pulmonary contusion. 

The presentation is similar to a tension pneumothorax –
deteriorating cyanosis, tachycardia and agitation
eFAST is diagnostic and may also detect free
/f_l
uid in the
abdomen or pericardium
There is no role for pericardiocentesis in traumatic cardiac
tamponade. A left anterolateral thoracotomy or sternotomy
should be performed with evacuation of the haematoma and
repair of the myocardium



Figure 29.4
Chest radiograph showing a widened mediastinum
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

# Introduction

INTRODUCTION

Injury seldom respects anatomical boundaries, hence the divi sion of  the body into the abdomen and the thorax is artiﬁcial. Therefore, injury to the torso with its associated physiological consequences is more appropriate. The torso is generally regarded as the focal point of  the human body , consisting of the chest, abdomen and pelvis and not including the head, neck, arms and legs. About 42% of  all deaths are the result of brain injury , but some 39% of  all trauma deaths are caused by major haemorrhage, usually from torso injury ( Figure 29.1 Historically , injury was treated on an anatomical basis; however, it has become clear that physiology should be the over-riding consideration. The driver of  successful resuscitation is ther efore the preservation of  normal physiology . Techniques such as damage control resuscitation and its key component damage control surgery have dramatically improved survival through an understanding of the best techniques required to restore physiological stability (see Chapters 1, 26 and 27 

Other
6%
CNS
Unknown
MOF 7%
42%
0%
Bleeding 39%
Bleeding + CNS
6%
Figure 29.1
Causes of death in trauma. CNS, central nervous system;
MOF , multiple organ failure.
The operative approaches to the thoracic cavity
•
The special features of an emergency department
•
thoracotomy for haemorrhage control
The indications for, and techniques of, the trauma
•
laparotomy
The philosophy of damage control resuscitation
•
The management of trauma to the pelvis
•

# Investigation

Investigation

Routine investigation in the emergency department of  injury to the chest is based on clinical examination, supplemented by appropriate imaging. 

Figure 29.2
The anatomical extent of the
abdomen.

with sonography for trauma (eFAST) Ultrasound can be used to di ﬀ erentiate between contusion and the actual presence of  blood. Extended focused assessment with sonography for trauma (eFAST) is becoming the most common investigation. The technique uses sonographic assess ment in the chest, looking for a cardiac tamponade or free blood and air in the hemithoraces, and assessment for blood in the abdominal cavity , in the paracolic gutters, subdiaphrag matic spaces and pelvis. Finger thoracostomy In the physiologically grossly unstable patient, where physical examination is inconclusive and there is no time for radiological investigations, bilateral ﬁnger thoracostomy can be a diagnos tic procedure as well as a therapeutic one, and the beneﬁts of undertaking it often outweigh the risks. It is undertaken by making a 5-cm skin incision on the ﬁfth rib just anterior to the mid-axillary line. The intercostal muscles are then separated just above the ﬁfth rib and the pleural cavity entered. A ﬁnger is then inserted and a pleural swee p made to ensure the pleural cavity has been entered. Chest radiograph In those cases where the patient is physiologically non- compromised or the spine is at risk, an anteroposterior (AP) supine chest radiograph is usually the simplest initial investigation. It will provide good information regarding tracheal deviation, lung and mediastinal pathology as well as skeletal injury . In penetrating injury , it may be more helpful for the radio graph to be performed with the patient positioned erect, as this will best reveal a small pneumothorax, ﬂuid meniscus, air–ﬂuid level or the presence of  free gas under the diaphragm, indi ca ting the presence of  a hollow abdominal viscus perforation. Note that up to 300 /uni00A0 mL of  blood may pool behind the domes of  the diaphragm, and may not be visible even in the erect view . T he presence of  thoracic skeletal injury should alert the clinician to the possibility of  adjacent thoracic or abdominal visceral injury . Rupture of  the thoracic aorta can be related to fractures of  the ﬁrst and second rib, bilateral clavicular fracture and fracture of the sternum, thoracic spine or scapula. Frac ture of  the lower ribs can be related to injury of  the liver or spleen. Fracture of  the ribs, irrespective of  site, can be related to injury to the lung parenchyma or thoracic wall vascula causing pneumothorax, haemothorax or lung contusion. Computed tomography scan The computed tomography (CT) scan with contrast allows for three-dimensional reconstruction of the chest and abdomen, as well as of  the bony skeleton. It has become the principal and most reliable examination for major injury in trauma. In blunt chest trauma, the CT scan will allow the deﬁnition of  frac tures, as well as showing haematomas, pneumothoraces and pulmonary contusion. In penetrating trauma, the scan may show the track or presence of the missile and allow the pr planning of  deﬁnitive surgery . However, although the presence of  an isolated rupture of  the diaphragm with migration of in injury without migration the diagnosis will not be obvious. The pitfalls of  investigation are: /uni25CF failure to assess tracheal shift immediately above the sternal notch clinically (deviation of  the trachea occurs away from the a ﬀ ected side in tension pneumothorax and towards the - a ﬀ ected side in lung collapse); /uni25CF failure to percuss and auscultate both front and back in a supine patient (an inﬂated lung will ‘ﬂoat’ on a haemo - - thorax, so auscultation from the front may sound normal); /uni25CF failure to pass a nasogastric tube if  rupture of  the dia - phragm is suspected; a chest radiograph will show the nasogastric tube apparently within the chest cavity; /uni25CF a supine chest radiograph can show a haemothorax as a homogeneous increase in opacity of  the hemithorax – this - can cause confusion between the darker side and the lighter side as to which may be a haemothorax (less radiolucent) or a pneumothorax (more radiolucent); look carefully for lung markings and do not drain the wrong side; /uni25CF pursuing radiological investigation (radiography or CT scan) instead of  resuscitation in the unstable patient. Summary box 29.2 Investigation of chest injuries /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF - Management - In penetrating injury , most patients who have su ﬀ ered injury to the chest can be managed with appropriate resuscitation and insertion of  an intercostal drain. If  a sucking chest wound is present, this should not be fully closed but should be covered with a piece of  plastic, closed on three sides to form a one-way valve, and ther eafter an underwater chest drain should be inserted remote from the - wound. No attempt should be made to close a sucking chest wound until controlled drainage has been achieved, in case a stable patient with an open pneumothorax is converted into an ture, unstable patient with a tension pneumothorax. In blunt injury , most bleeding occurs from the intercostal or internal mammary vessels and it is relatively rare for these to require surgery . If  bleeding does not stop spontaneously , the v essels can be embolised, via an interventional radiological approach, or treated operatively , during which the vessels can be tied o ﬀ or encircled. In blunt chest compressive injury , particularly in the presence of  a ﬂail chest, there can be an associated lung contusion. - The patient in extremis with exsanguinating chest haemor - rhage is discussed in Emergency department thoracotomy or sternotomy . oper Life-threatening injuries can be remembered as the ‘deadly dozen’. Six are immediately life-threatening and should be 

Directly or indirectly involved in >50% of trauma deaths
More than 80% can be managed non-operatively
A chest radiograph is the investigation of
/f_i
rst choice
Finger thoracostomy can be diagnostic and therapeutic
A pan-CT scan provides rapid diagnosis

Closed management of chest injuries /uni25CF /uni25CF /uni25CF sought and managed during the primary survey and six are potentially life-threatening and should be detected during the secondary survey ( Table 29.3 ). A high index of  suspicion must be maintained thereafter to diagnose the potential threats to life, as their symptoms and signs can be very subtle. Early con sultation and referral to a trauma centre is advised in cases of doubt. 

More than 80% of chest injuries can be managed with the
insertion of an intercostal drain only
Do not close a sucking chest wound until a drain is in place
If bleeding persists, the chest will need to be opened and
direct haemostatic control is obtained

Investigation

Investigations are driven by the cardiovascular status of  the patient. In torso trauma, the best and most sensitive modality is a CT scan with intravenous contrast; however, in the unstable - patient, this is generally not possible. In patients with penetrating injury , metal markers (e.g. bent paper clips) should be placed on all external wounds before plain ﬁlms are taken, irrespective of  the area being radiographed, as this allows an assessment of  the trajectory and helps to correla te the number of  holes and the number of missiles that can be seen within the patient. This will help determine whether two holes are indicative of one missile pass - ing through the patient, or two missiles, both retained inter - nally ( Figure 29.7 ). A single hole implies that the projectile has been retained. Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) Focused abdominal sonography for trauma (FAST) is a tech - nique whereby ultrasound (sonography) imaging is used to assess the torso for the presence of  free ﬂuid in the abdominal cavity , and is extended into the thoracic cavities and peri - cardium (eFAST). There should be no attempt to determine the natur e or extent of  the speciﬁc injury . eFAST is usually a rapid, reproducible, portable and non-invasive bedside test and can be performed at the same time as resuscitation. eFAST is accurate at detecting >100 /uni00A0 mL of  free blood; however, it is very operator dependent and, especially if  the patient is very obese or the bowel is full of  gas, it may be unreliable. Hollow viscus injury and solid organ injury are di ﬃ cult to diagnose, even in Sydney Ringer , 1835–1910, Professor of  Clinical Medicine, University College Hospital, London, UK. to assess and eFAST has a low sensitivity (29–35%) for organ injury without haemoperitoneum. eFAST is also unreliable for excluding injury in penetrating trauma. If  there is doubt, the xamination can be repeated. eF AST e Summary box 29.5 Utilisation of eFAST /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

(b)
Figure 29.7
(a)
Chest radiograph showing a gunshot wound with
bullet markers.
(b)
Abdominal radiograph of a gunshot wound
showing bullet markers.
Detects free
/f_l
uid in the abdomen or pericardium
Will not reliably detect less than 100
/uni00A0
mL of free blood
Does not directly identify injury to hollow viscus
Cannot reliably exclude injury in penetrating trauma
May need repeating or supplementing with other investigations
Is unreliable for assessment of the retroperitoneum

Investigation

Routine investigation in the emergency department of  injury to the chest is based on clinical examination, supplemented by appropriate imaging. 

Figure 29.2
The anatomical extent of the
abdomen.

with sonography for trauma (eFAST) Ultrasound can be used to di ﬀ erentiate between contusion and the actual presence of  blood. Extended focused assessment with sonography for trauma (eFAST) is becoming the most common investigation. The technique uses sonographic assess ment in the chest, looking for a cardiac tamponade or free blood and air in the hemithoraces, and assessment for blood in the abdominal cavity , in the paracolic gutters, subdiaphrag matic spaces and pelvis. Finger thoracostomy In the physiologically grossly unstable patient, where physical examination is inconclusive and there is no time for radiological investigations, bilateral ﬁnger thoracostomy can be a diagnos tic procedure as well as a therapeutic one, and the beneﬁts of undertaking it often outweigh the risks. It is undertaken by making a 5-cm skin incision on the ﬁfth rib just anterior to the mid-axillary line. The intercostal muscles are then separated just above the ﬁfth rib and the pleural cavity entered. A ﬁnger is then inserted and a pleural swee p made to ensure the pleural cavity has been entered. Chest radiograph In those cases where the patient is physiologically non- compromised or the spine is at risk, an anteroposterior (AP) supine chest radiograph is usually the simplest initial investigation. It will provide good information regarding tracheal deviation, lung and mediastinal pathology as well as skeletal injury . In penetrating injury , it may be more helpful for the radio graph to be performed with the patient positioned erect, as this will best reveal a small pneumothorax, ﬂuid meniscus, air–ﬂuid level or the presence of  free gas under the diaphragm, indi ca ting the presence of  a hollow abdominal viscus perforation. Note that up to 300 /uni00A0 mL of  blood may pool behind the domes of  the diaphragm, and may not be visible even in the erect view . T he presence of  thoracic skeletal injury should alert the clinician to the possibility of  adjacent thoracic or abdominal visceral injury . Rupture of  the thoracic aorta can be related to fractures of  the ﬁrst and second rib, bilateral clavicular fracture and fracture of the sternum, thoracic spine or scapula. Frac ture of  the lower ribs can be related to injury of  the liver or spleen. Fracture of  the ribs, irrespective of  site, can be related to injury to the lung parenchyma or thoracic wall vascula causing pneumothorax, haemothorax or lung contusion. Computed tomography scan The computed tomography (CT) scan with contrast allows for three-dimensional reconstruction of the chest and abdomen, as well as of  the bony skeleton. It has become the principal and most reliable examination for major injury in trauma. In blunt chest trauma, the CT scan will allow the deﬁnition of  frac tures, as well as showing haematomas, pneumothoraces and pulmonary contusion. In penetrating trauma, the scan may show the track or presence of the missile and allow the pr planning of  deﬁnitive surgery . However, although the presence of  an isolated rupture of  the diaphragm with migration of in injury without migration the diagnosis will not be obvious. The pitfalls of  investigation are: /uni25CF failure to assess tracheal shift immediately above the sternal notch clinically (deviation of  the trachea occurs away from the a ﬀ ected side in tension pneumothorax and towards the - a ﬀ ected side in lung collapse); /uni25CF failure to percuss and auscultate both front and back in a supine patient (an inﬂated lung will ‘ﬂoat’ on a haemo - - thorax, so auscultation from the front may sound normal); /uni25CF failure to pass a nasogastric tube if  rupture of  the dia - phragm is suspected; a chest radiograph will show the nasogastric tube apparently within the chest cavity; /uni25CF a supine chest radiograph can show a haemothorax as a homogeneous increase in opacity of  the hemithorax – this - can cause confusion between the darker side and the lighter side as to which may be a haemothorax (less radiolucent) or a pneumothorax (more radiolucent); look carefully for lung markings and do not drain the wrong side; /uni25CF pursuing radiological investigation (radiography or CT scan) instead of  resuscitation in the unstable patient. Summary box 29.2 Investigation of chest injuries /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF - Management - In penetrating injury , most patients who have su ﬀ ered injury to the chest can be managed with appropriate resuscitation and insertion of  an intercostal drain. If  a sucking chest wound is present, this should not be fully closed but should be covered with a piece of  plastic, closed on three sides to form a one-way valve, and ther eafter an underwater chest drain should be inserted remote from the - wound. No attempt should be made to close a sucking chest wound until controlled drainage has been achieved, in case a stable patient with an open pneumothorax is converted into an ture, unstable patient with a tension pneumothorax. In blunt injury , most bleeding occurs from the intercostal or internal mammary vessels and it is relatively rare for these to require surgery . If  bleeding does not stop spontaneously , the v essels can be embolised, via an interventional radiological approach, or treated operatively , during which the vessels can be tied o ﬀ or encircled. In blunt chest compressive injury , particularly in the presence of  a ﬂail chest, there can be an associated lung contusion. - The patient in extremis with exsanguinating chest haemor - rhage is discussed in Emergency department thoracotomy or sternotomy . oper Life-threatening injuries can be remembered as the ‘deadly dozen’. Six are immediately life-threatening and should be 

Directly or indirectly involved in >50% of trauma deaths
More than 80% can be managed non-operatively
A chest radiograph is the investigation of
/f_i
rst choice
Finger thoracostomy can be diagnostic and therapeutic
A pan-CT scan provides rapid diagnosis

Closed management of chest injuries /uni25CF /uni25CF /uni25CF sought and managed during the primary survey and six are potentially life-threatening and should be detected during the secondary survey ( Table 29.3 ). A high index of  suspicion must be maintained thereafter to diagnose the potential threats to life, as their symptoms and signs can be very subtle. Early con sultation and referral to a trauma centre is advised in cases of doubt. 

More than 80% of chest injuries can be managed with the
insertion of an intercostal drain only
Do not close a sucking chest wound until a drain is in place
If bleeding persists, the chest will need to be opened and
direct haemostatic control is obtained

Investigation

Investigations are driven by the cardiovascular status of  the patient. In torso trauma, the best and most sensitive modality is a CT scan with intravenous contrast; however, in the unstable - patient, this is generally not possible. In patients with penetrating injury , metal markers (e.g. bent paper clips) should be placed on all external wounds before plain ﬁlms are taken, irrespective of  the area being radiographed, as this allows an assessment of  the trajectory and helps to correla te the number of  holes and the number of missiles that can be seen within the patient. This will help determine whether two holes are indicative of one missile pass - ing through the patient, or two missiles, both retained inter - nally ( Figure 29.7 ). A single hole implies that the projectile has been retained. Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) Focused abdominal sonography for trauma (FAST) is a tech - nique whereby ultrasound (sonography) imaging is used to assess the torso for the presence of  free ﬂuid in the abdominal cavity , and is extended into the thoracic cavities and peri - cardium (eFAST). There should be no attempt to determine the natur e or extent of  the speciﬁc injury . eFAST is usually a rapid, reproducible, portable and non-invasive bedside test and can be performed at the same time as resuscitation. eFAST is accurate at detecting >100 /uni00A0 mL of  free blood; however, it is very operator dependent and, especially if  the patient is very obese or the bowel is full of  gas, it may be unreliable. Hollow viscus injury and solid organ injury are di ﬃ cult to diagnose, even in Sydney Ringer , 1835–1910, Professor of  Clinical Medicine, University College Hospital, London, UK. to assess and eFAST has a low sensitivity (29–35%) for organ injury without haemoperitoneum. eFAST is also unreliable for excluding injury in penetrating trauma. If  there is doubt, the xamination can be repeated. eF AST e Summary box 29.5 Utilisation of eFAST /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

(b)
Figure 29.7
(a)
Chest radiograph showing a gunshot wound with
bullet markers.
(b)
Abdominal radiograph of a gunshot wound
showing bullet markers.
Detects free
/f_l
uid in the abdomen or pericardium
Will not reliably detect less than 100
/uni00A0
mL of free blood
Does not directly identify injury to hollow viscus
Cannot reliably exclude injury in penetrating trauma
May need repeating or supplementing with other investigations
Is unreliable for assessment of the retroperitoneum

Investigation

Routine investigation in the emergency department of  injury to the chest is based on clinical examination, supplemented by appropriate imaging. 

Figure 29.2
The anatomical extent of the
abdomen.

with sonography for trauma (eFAST) Ultrasound can be used to di ﬀ erentiate between contusion and the actual presence of  blood. Extended focused assessment with sonography for trauma (eFAST) is becoming the most common investigation. The technique uses sonographic assess ment in the chest, looking for a cardiac tamponade or free blood and air in the hemithoraces, and assessment for blood in the abdominal cavity , in the paracolic gutters, subdiaphrag matic spaces and pelvis. Finger thoracostomy In the physiologically grossly unstable patient, where physical examination is inconclusive and there is no time for radiological investigations, bilateral ﬁnger thoracostomy can be a diagnos tic procedure as well as a therapeutic one, and the beneﬁts of undertaking it often outweigh the risks. It is undertaken by making a 5-cm skin incision on the ﬁfth rib just anterior to the mid-axillary line. The intercostal muscles are then separated just above the ﬁfth rib and the pleural cavity entered. A ﬁnger is then inserted and a pleural swee p made to ensure the pleural cavity has been entered. Chest radiograph In those cases where the patient is physiologically non- compromised or the spine is at risk, an anteroposterior (AP) supine chest radiograph is usually the simplest initial investigation. It will provide good information regarding tracheal deviation, lung and mediastinal pathology as well as skeletal injury . In penetrating injury , it may be more helpful for the radio graph to be performed with the patient positioned erect, as this will best reveal a small pneumothorax, ﬂuid meniscus, air–ﬂuid level or the presence of  free gas under the diaphragm, indi ca ting the presence of  a hollow abdominal viscus perforation. Note that up to 300 /uni00A0 mL of  blood may pool behind the domes of  the diaphragm, and may not be visible even in the erect view . T he presence of  thoracic skeletal injury should alert the clinician to the possibility of  adjacent thoracic or abdominal visceral injury . Rupture of  the thoracic aorta can be related to fractures of  the ﬁrst and second rib, bilateral clavicular fracture and fracture of the sternum, thoracic spine or scapula. Frac ture of  the lower ribs can be related to injury of  the liver or spleen. Fracture of  the ribs, irrespective of  site, can be related to injury to the lung parenchyma or thoracic wall vascula causing pneumothorax, haemothorax or lung contusion. Computed tomography scan The computed tomography (CT) scan with contrast allows for three-dimensional reconstruction of the chest and abdomen, as well as of  the bony skeleton. It has become the principal and most reliable examination for major injury in trauma. In blunt chest trauma, the CT scan will allow the deﬁnition of  frac tures, as well as showing haematomas, pneumothoraces and pulmonary contusion. In penetrating trauma, the scan may show the track or presence of the missile and allow the pr planning of  deﬁnitive surgery . However, although the presence of  an isolated rupture of  the diaphragm with migration of in injury without migration the diagnosis will not be obvious. The pitfalls of  investigation are: /uni25CF failure to assess tracheal shift immediately above the sternal notch clinically (deviation of  the trachea occurs away from the a ﬀ ected side in tension pneumothorax and towards the - a ﬀ ected side in lung collapse); /uni25CF failure to percuss and auscultate both front and back in a supine patient (an inﬂated lung will ‘ﬂoat’ on a haemo - - thorax, so auscultation from the front may sound normal); /uni25CF failure to pass a nasogastric tube if  rupture of  the dia - phragm is suspected; a chest radiograph will show the nasogastric tube apparently within the chest cavity; /uni25CF a supine chest radiograph can show a haemothorax as a homogeneous increase in opacity of  the hemithorax – this - can cause confusion between the darker side and the lighter side as to which may be a haemothorax (less radiolucent) or a pneumothorax (more radiolucent); look carefully for lung markings and do not drain the wrong side; /uni25CF pursuing radiological investigation (radiography or CT scan) instead of  resuscitation in the unstable patient. Summary box 29.2 Investigation of chest injuries /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF - Management - In penetrating injury , most patients who have su ﬀ ered injury to the chest can be managed with appropriate resuscitation and insertion of  an intercostal drain. If  a sucking chest wound is present, this should not be fully closed but should be covered with a piece of  plastic, closed on three sides to form a one-way valve, and ther eafter an underwater chest drain should be inserted remote from the - wound. No attempt should be made to close a sucking chest wound until controlled drainage has been achieved, in case a stable patient with an open pneumothorax is converted into an ture, unstable patient with a tension pneumothorax. In blunt injury , most bleeding occurs from the intercostal or internal mammary vessels and it is relatively rare for these to require surgery . If  bleeding does not stop spontaneously , the v essels can be embolised, via an interventional radiological approach, or treated operatively , during which the vessels can be tied o ﬀ or encircled. In blunt chest compressive injury , particularly in the presence of  a ﬂail chest, there can be an associated lung contusion. - The patient in extremis with exsanguinating chest haemor - rhage is discussed in Emergency department thoracotomy or sternotomy . oper Life-threatening injuries can be remembered as the ‘deadly dozen’. Six are immediately life-threatening and should be 

Directly or indirectly involved in >50% of trauma deaths
More than 80% can be managed non-operatively
A chest radiograph is the investigation of
/f_i
rst choice
Finger thoracostomy can be diagnostic and therapeutic
A pan-CT scan provides rapid diagnosis

Closed management of chest injuries /uni25CF /uni25CF /uni25CF sought and managed during the primary survey and six are potentially life-threatening and should be detected during the secondary survey ( Table 29.3 ). A high index of  suspicion must be maintained thereafter to diagnose the potential threats to life, as their symptoms and signs can be very subtle. Early con sultation and referral to a trauma centre is advised in cases of doubt. 

More than 80% of chest injuries can be managed with the
insertion of an intercostal drain only
Do not close a sucking chest wound until a drain is in place
If bleeding persists, the chest will need to be opened and
direct haemostatic control is obtained

Investigation

Investigations are driven by the cardiovascular status of  the patient. In torso trauma, the best and most sensitive modality is a CT scan with intravenous contrast; however, in the unstable - patient, this is generally not possible. In patients with penetrating injury , metal markers (e.g. bent paper clips) should be placed on all external wounds before plain ﬁlms are taken, irrespective of  the area being radiographed, as this allows an assessment of  the trajectory and helps to correla te the number of  holes and the number of missiles that can be seen within the patient. This will help determine whether two holes are indicative of one missile pass - ing through the patient, or two missiles, both retained inter - nally ( Figure 29.7 ). A single hole implies that the projectile has been retained. Focused abdominal sonography for trauma and extended FAST (FAST and eFAST) Focused abdominal sonography for trauma (FAST) is a tech - nique whereby ultrasound (sonography) imaging is used to assess the torso for the presence of  free ﬂuid in the abdominal cavity , and is extended into the thoracic cavities and peri - cardium (eFAST). There should be no attempt to determine the natur e or extent of  the speciﬁc injury . eFAST is usually a rapid, reproducible, portable and non-invasive bedside test and can be performed at the same time as resuscitation. eFAST is accurate at detecting >100 /uni00A0 mL of  free blood; however, it is very operator dependent and, especially if  the patient is very obese or the bowel is full of  gas, it may be unreliable. Hollow viscus injury and solid organ injury are di ﬃ cult to diagnose, even in Sydney Ringer , 1835–1910, Professor of  Clinical Medicine, University College Hospital, London, UK. to assess and eFAST has a low sensitivity (29–35%) for organ injury without haemoperitoneum. eFAST is also unreliable for excluding injury in penetrating trauma. If  there is doubt, the xamination can be repeated. eF AST e Summary box 29.5 Utilisation of eFAST /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

(b)
Figure 29.7
(a)
Chest radiograph showing a gunshot wound with
bullet markers.
(b)
Abdominal radiograph of a gunshot wound
showing bullet markers.
Detects free
/f_l
uid in the abdomen or pericardium
Will not reliably detect less than 100
/uni00A0
mL of free blood
Does not directly identify injury to hollow viscus
Cannot reliably exclude injury in penetrating trauma
May need repeating or supplementing with other investigations
Is unreliable for assessment of the retroperitoneum

# Junctional zones

Junctional zones

The key junctional zones are: ). /uni25CF between the neck and the thorax; /uni25CF between the thorax and the upper limbs; /uni25CF between the thorax and the abdomen; /uni25CF between the abdominopelvic structures and the groin. These zones represent surgical challenges in terms of both diagnosis of  the area of  injury and the required surgical approach. Such factors have to be balanced against the physi - ). ological stability of  the pa tient. Root of the neck Most injuries a ﬀ ecting the base of  the neck may also a ﬀ ect the upper mediastinum and thoracic inlet. Choice of  access is determined by the need for surgical control of  the vascular structures contained within. The mediastinum The mediastinum, with its major vessels and the heart, is also an extremely high-risk area for penetrating wounds. Any wound in this region should immediately raise the suspicion of  a major vascular or an associated cardiac injury , even in the absence of  initial gross physical signs. Diaphragm The thorax and abdomen are separated by the diaphragm, which is mainly responsible for breathing, allowing movement space. Any penetrating injury below the nipples on the chest may therefore have penetrated the diaphragm and entered the abdomen. Injuries in this junctional zone, therefore, should be investigated as if  both cavities had been penetrated ( Figure 29.2 ). In blunt trauma, rupture of  the diaphragm can result in migration of  abdominal viscera into the chest, with left-sided hemidiaphragm rupture being more common. Pelvic structures The pelvis contains a large plexus of  vessels, both venous and arterial. Should injury occur, control of  haemorrhage can prove to be exceptionally di ﬃ cult and may require control of both arterial inﬂow and venous outﬂow . Angioembolisation can be a very useful adjunct to treatment, especially with deep pelvic injuries. Summary box 29.1 Junctional zones /uni25CF /uni25CF /uni25CF /uni25CF 

Between neck and the thorax
Between thorax and upper limbs
Between thorax and the abdomen
Between the abdominopelvic structures and the groin

Junctional zones

The key junctional zones are: ). /uni25CF between the neck and the thorax; /uni25CF between the thorax and the upper limbs; /uni25CF between the thorax and the abdomen; /uni25CF between the abdominopelvic structures and the groin. These zones represent surgical challenges in terms of both diagnosis of  the area of  injury and the required surgical approach. Such factors have to be balanced against the physi - ). ological stability of  the pa tient. Root of the neck Most injuries a ﬀ ecting the base of  the neck may also a ﬀ ect the upper mediastinum and thoracic inlet. Choice of  access is determined by the need for surgical control of  the vascular structures contained within. The mediastinum The mediastinum, with its major vessels and the heart, is also an extremely high-risk area for penetrating wounds. Any wound in this region should immediately raise the suspicion of  a major vascular or an associated cardiac injury , even in the absence of  initial gross physical signs. Diaphragm The thorax and abdomen are separated by the diaphragm, which is mainly responsible for breathing, allowing movement space. Any penetrating injury below the nipples on the chest may therefore have penetrated the diaphragm and entered the abdomen. Injuries in this junctional zone, therefore, should be investigated as if  both cavities had been penetrated ( Figure 29.2 ). In blunt trauma, rupture of  the diaphragm can result in migration of  abdominal viscera into the chest, with left-sided hemidiaphragm rupture being more common. Pelvic structures The pelvis contains a large plexus of  vessels, both venous and arterial. Should injury occur, control of  haemorrhage can prove to be exceptionally di ﬃ cult and may require control of both arterial inﬂow and venous outﬂow . Angioembolisation can be a very useful adjunct to treatment, especially with deep pelvic injuries. Summary box 29.1 Junctional zones /uni25CF /uni25CF /uni25CF /uni25CF 

Between neck and the thorax
Between thorax and upper limbs
Between thorax and the abdomen
Between the abdominopelvic structures and the groin

Junctional zones

The key junctional zones are: ). /uni25CF between the neck and the thorax; /uni25CF between the thorax and the upper limbs; /uni25CF between the thorax and the abdomen; /uni25CF between the abdominopelvic structures and the groin. These zones represent surgical challenges in terms of both diagnosis of  the area of  injury and the required surgical approach. Such factors have to be balanced against the physi - ). ological stability of  the pa tient. Root of the neck Most injuries a ﬀ ecting the base of  the neck may also a ﬀ ect the upper mediastinum and thoracic inlet. Choice of  access is determined by the need for surgical control of  the vascular structures contained within. The mediastinum The mediastinum, with its major vessels and the heart, is also an extremely high-risk area for penetrating wounds. Any wound in this region should immediately raise the suspicion of  a major vascular or an associated cardiac injury , even in the absence of  initial gross physical signs. Diaphragm The thorax and abdomen are separated by the diaphragm, which is mainly responsible for breathing, allowing movement space. Any penetrating injury below the nipples on the chest may therefore have penetrated the diaphragm and entered the abdomen. Injuries in this junctional zone, therefore, should be investigated as if  both cavities had been penetrated ( Figure 29.2 ). In blunt trauma, rupture of  the diaphragm can result in migration of  abdominal viscera into the chest, with left-sided hemidiaphragm rupture being more common. Pelvic structures The pelvis contains a large plexus of  vessels, both venous and arterial. Should injury occur, control of  haemorrhage can prove to be exceptionally di ﬃ cult and may require control of both arterial inﬂow and venous outﬂow . Angioembolisation can be a very useful adjunct to treatment, especially with deep pelvic injuries. Summary box 29.1 Junctional zones /uni25CF /uni25CF /uni25CF /uni25CF 

Between neck and the thorax
Between thorax and upper limbs
Between thorax and the abdomen
Between the abdominopelvic structures and the groin

# Laparoscopy

Laparoscopy

Laparoscopy or thoracoscopy may be a valuable screening investigation in physiologically non-compromised patients with penetrating trauma to detect or exclude peritoneal penetration and/or diaphragmatic injury . Laparoscopy may be divided into: /uni25CF screening: used to exclude a penetrating injury with breach of  the peritoneum; /uni25CF diagnostic: ﬁnding evidence of  injury to viscera; /uni25CF therapeutic: used to repair the injury . In most institutions, evidence of penetration requires a lap arotomy to evaluate organ injury as it is di ﬃ cult to exclude all intra-abdominal injuries laparoscopically . When used in this role laparoscopy reduces the non-therapeutic laparotomy rate. There is no place for laparoscopy in the unstable patient. Laparoscopy

Laparoscopy or thoracoscopy may be a valuable screening investigation in physiologically non-compromised patients with penetrating trauma to detect or exclude peritoneal penetration and/or diaphragmatic injury . Laparoscopy may be divided into: /uni25CF screening: used to exclude a penetrating injury with breach of  the peritoneum; /uni25CF diagnostic: ﬁnding evidence of  injury to viscera; /uni25CF therapeutic: used to repair the injury . In most institutions, evidence of penetration requires a lap arotomy to evaluate organ injury as it is di ﬃ cult to exclude all intra-abdominal injuries laparoscopically . When used in this role laparoscopy reduces the non-therapeutic laparotomy rate. There is no place for laparoscopy in the unstable patient. Laparoscopy

Laparoscopy or thoracoscopy may be a valuable screening investigation in physiologically non-compromised patients with penetrating trauma to detect or exclude peritoneal penetration and/or diaphragmatic injury . Laparoscopy may be divided into: /uni25CF screening: used to exclude a penetrating injury with breach of  the peritoneum; /uni25CF diagnostic: ﬁnding evidence of  injury to viscera; /uni25CF therapeutic: used to repair the injury . In most institutions, evidence of penetration requires a lap arotomy to evaluate organ injury as it is di ﬃ cult to exclude all intra-abdominal injuries laparoscopically . When used in this role laparoscopy reduces the non-therapeutic laparotomy rate. There is no place for laparoscopy in the unstable patient.

# Learning objectives

Learning objectives

To understand: The importance of physiology over anatomy in the • management of trauma The gross surgical anatomy of the chest and abdomen • The pathophysiology of torso injury • The clinical assessment in the injured patient • The use of special investigations and their limitations • Learning objectives

To understand: The importance of physiology over anatomy in the • management of trauma The gross surgical anatomy of the chest and abdomen • The pathophysiology of torso injury • The clinical assessment in the injured patient • The use of special investigations and their limitations • Learning objectives

To understand: The importance of physiology over anatomy in the • management of trauma The gross surgical anatomy of the chest and abdomen • The pathophysiology of torso injury • The clinical assessment in the injured patient • The use of special investigations and their limitations •

# Management

Management

The operative management of  liver injuries can be summarised as ‘the four Ps’: /uni25CF Pressure; /uni25CF Pringle; /uni25CF Plug; /uni25CF Pack. At laparotomy the liver is reconstituted and bleeding is con - trolled by direct bimanual compression to achieve its normal architecture as best as possible (Pressure). The inﬂow from the portal triad is contr olled by a Pringle’s manoeuvre, with direct compression of the portal triad, either digitally or using a soft clamp ( Figure 29.9 ). This has the e ﬀ ect of  reducing arterial and portal venous inﬂow into the liver, although it does not control the backﬂow from the inferior vena cava and hepatic veins. Any holes due to penetrating injury can be plugged directly using silicone tubing or a Sengstaken–Blakemore tube; after controlling any arterial bleeding, the liver can then be - packed (see Damage control surgery ). Bleeding points should be controlled locally when possible, and such patients, if  required, subsequently undergo angioembolisation. It is not usually necessary to suture penetrating injuries of  the liver unless haemostasis cannot be controlled by other means . If  there has been direct damage to the hepatic artery , it can be tied o ﬀ . Damage to the portal vein must be repaired, as tying o ﬀ the portal vein carries a greater than 50% mortality rate. If  it is not technically feasible to repair the vein at the time of  surgery , it should be shunted and the patient referred to a specialist centre. A drainage system must be left in situ following hepatic surgery . Finally , the liver can be deﬁnitively packed, restoring the anatomy as closely as possible. Placing omentum into cracks in the liver is not recommended. Arthur Hendley Blakemore , 1897–1970, Associate Professor of Surgery , Summary box 29.6 Liver trauma /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Hepatic artery
Portal vein
Figure 29.9
The Pringle manoeuvre.
Blunt trauma occurs as the result of direct compression
Penetrating trauma of the upper abdomen or lower thorax can
damage the liver
CT scanning is the investigation of choice in a stable patient
Surgical management consists of: Pressure, Pringle, Plug and
Pack
The hepatic artery can be tied off but not the portal vein (which
should be stented)
Closed drainage should always be used

Management

The treatment for bleeding is to stop the bleeding! The priorities for resuscitating patients with pelvic fractures are no di ﬀ erent from the standard. These injuries can produce a real thr eat to the circulation, and management is geared towards controlling this threat. Initial management requires the use of  a compression binder or a sheet, applied around the true pelvis at the level of the greater trochanters (‘reduce the pelvic volume’), a potentially life-saving procedure that has to - be done in the emergency department. Eighty-ﬁve per cent of  bleeding originating from the pelvis is of  venous origin and can be controlled by non-operative means, including compression either by binding or external ﬁxator or by extraperitoneal pelvic packing (i.e. packing the loose space between the bon y wall of  the pelvis and the perito - neum) to compress the pelvic veins. If  other sources of  bleed - ing have been ruled out, the extraperitoneal pelvic packing is done without entering the peritoneal cavity . This may be combined with external ﬁxation. - If  the b leeding is of  arterial origin, interventional angio - embolisation is the next choice for bleeding control. The tech - - niques for bleeding control (compression, packing, ﬁxation and angioembolisation) do not exclude each other but rather may complement each other. Persistent bleeding after packing may require angioembolisation and vice v ersa. Severe pelvic injuries require a multidisciplinary team approach. If  adequate orthopaedic experience is unavailable, consideration should be given towards early transfer of  this pa tient to an institution with the necessary expertise. If  the source of  the bleeding is in doubt or FAST/CT results are positive, showing a signiﬁcant amount of  blood in the peritoneal cavity , concurrent intra-abdominal injury can - not be excluded and it is wise to perfor m an exploratory lapa - rotomy to treat or rule out intra-abdominal bleeding. Management

The operative management of  liver injuries can be summarised as ‘the four Ps’: /uni25CF Pressure; /uni25CF Pringle; /uni25CF Plug; /uni25CF Pack. At laparotomy the liver is reconstituted and bleeding is con - trolled by direct bimanual compression to achieve its normal architecture as best as possible (Pressure). The inﬂow from the portal triad is contr olled by a Pringle’s manoeuvre, with direct compression of the portal triad, either digitally or using a soft clamp ( Figure 29.9 ). This has the e ﬀ ect of  reducing arterial and portal venous inﬂow into the liver, although it does not control the backﬂow from the inferior vena cava and hepatic veins. Any holes due to penetrating injury can be plugged directly using silicone tubing or a Sengstaken–Blakemore tube; after controlling any arterial bleeding, the liver can then be - packed (see Damage control surgery ). Bleeding points should be controlled locally when possible, and such patients, if  required, subsequently undergo angioembolisation. It is not usually necessary to suture penetrating injuries of  the liver unless haemostasis cannot be controlled by other means . If  there has been direct damage to the hepatic artery , it can be tied o ﬀ . Damage to the portal vein must be repaired, as tying o ﬀ the portal vein carries a greater than 50% mortality rate. If  it is not technically feasible to repair the vein at the time of  surgery , it should be shunted and the patient referred to a specialist centre. A drainage system must be left in situ following hepatic surgery . Finally , the liver can be deﬁnitively packed, restoring the anatomy as closely as possible. Placing omentum into cracks in the liver is not recommended. Arthur Hendley Blakemore , 1897–1970, Associate Professor of Surgery , Summary box 29.6 Liver trauma /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Hepatic artery
Portal vein
Figure 29.9
The Pringle manoeuvre.
Blunt trauma occurs as the result of direct compression
Penetrating trauma of the upper abdomen or lower thorax can
damage the liver
CT scanning is the investigation of choice in a stable patient
Surgical management consists of: Pressure, Pringle, Plug and
Pack
The hepatic artery can be tied off but not the portal vein (which
should be stented)
Closed drainage should always be used

Management

The treatment for bleeding is to stop the bleeding! The priorities for resuscitating patients with pelvic fractures are no di ﬀ erent from the standard. These injuries can produce a real thr eat to the circulation, and management is geared towards controlling this threat. Initial management requires the use of  a compression binder or a sheet, applied around the true pelvis at the level of the greater trochanters (‘reduce the pelvic volume’), a potentially life-saving procedure that has to - be done in the emergency department. Eighty-ﬁve per cent of  bleeding originating from the pelvis is of  venous origin and can be controlled by non-operative means, including compression either by binding or external ﬁxator or by extraperitoneal pelvic packing (i.e. packing the loose space between the bon y wall of  the pelvis and the perito - neum) to compress the pelvic veins. If  other sources of  bleed - ing have been ruled out, the extraperitoneal pelvic packing is done without entering the peritoneal cavity . This may be combined with external ﬁxation. - If  the b leeding is of  arterial origin, interventional angio - embolisation is the next choice for bleeding control. The tech - - niques for bleeding control (compression, packing, ﬁxation and angioembolisation) do not exclude each other but rather may complement each other. Persistent bleeding after packing may require angioembolisation and vice v ersa. Severe pelvic injuries require a multidisciplinary team approach. If  adequate orthopaedic experience is unavailable, consideration should be given towards early transfer of  this pa tient to an institution with the necessary expertise. If  the source of  the bleeding is in doubt or FAST/CT results are positive, showing a signiﬁcant amount of  blood in the peritoneal cavity , concurrent intra-abdominal injury can - not be excluded and it is wise to perfor m an exploratory lapa - rotomy to treat or rule out intra-abdominal bleeding. Management

The operative management of  liver injuries can be summarised as ‘the four Ps’: /uni25CF Pressure; /uni25CF Pringle; /uni25CF Plug; /uni25CF Pack. At laparotomy the liver is reconstituted and bleeding is con - trolled by direct bimanual compression to achieve its normal architecture as best as possible (Pressure). The inﬂow from the portal triad is contr olled by a Pringle’s manoeuvre, with direct compression of the portal triad, either digitally or using a soft clamp ( Figure 29.9 ). This has the e ﬀ ect of  reducing arterial and portal venous inﬂow into the liver, although it does not control the backﬂow from the inferior vena cava and hepatic veins. Any holes due to penetrating injury can be plugged directly using silicone tubing or a Sengstaken–Blakemore tube; after controlling any arterial bleeding, the liver can then be - packed (see Damage control surgery ). Bleeding points should be controlled locally when possible, and such patients, if  required, subsequently undergo angioembolisation. It is not usually necessary to suture penetrating injuries of  the liver unless haemostasis cannot be controlled by other means . If  there has been direct damage to the hepatic artery , it can be tied o ﬀ . Damage to the portal vein must be repaired, as tying o ﬀ the portal vein carries a greater than 50% mortality rate. If  it is not technically feasible to repair the vein at the time of  surgery , it should be shunted and the patient referred to a specialist centre. A drainage system must be left in situ following hepatic surgery . Finally , the liver can be deﬁnitively packed, restoring the anatomy as closely as possible. Placing omentum into cracks in the liver is not recommended. Arthur Hendley Blakemore , 1897–1970, Associate Professor of Surgery , Summary box 29.6 Liver trauma /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Hepatic artery
Portal vein
Figure 29.9
The Pringle manoeuvre.
Blunt trauma occurs as the result of direct compression
Penetrating trauma of the upper abdomen or lower thorax can
damage the liver
CT scanning is the investigation of choice in a stable patient
Surgical management consists of: Pressure, Pringle, Plug and
Pack
The hepatic artery can be tied off but not the portal vein (which
should be stented)
Closed drainage should always be used

Management

The treatment for bleeding is to stop the bleeding! The priorities for resuscitating patients with pelvic fractures are no di ﬀ erent from the standard. These injuries can produce a real thr eat to the circulation, and management is geared towards controlling this threat. Initial management requires the use of  a compression binder or a sheet, applied around the true pelvis at the level of the greater trochanters (‘reduce the pelvic volume’), a potentially life-saving procedure that has to - be done in the emergency department. Eighty-ﬁve per cent of  bleeding originating from the pelvis is of  venous origin and can be controlled by non-operative means, including compression either by binding or external ﬁxator or by extraperitoneal pelvic packing (i.e. packing the loose space between the bon y wall of  the pelvis and the perito - neum) to compress the pelvic veins. If  other sources of  bleed - ing have been ruled out, the extraperitoneal pelvic packing is done without entering the peritoneal cavity . This may be combined with external ﬁxation. - If  the b leeding is of  arterial origin, interventional angio - embolisation is the next choice for bleeding control. The tech - - niques for bleeding control (compression, packing, ﬁxation and angioembolisation) do not exclude each other but rather may complement each other. Persistent bleeding after packing may require angioembolisation and vice v ersa. Severe pelvic injuries require a multidisciplinary team approach. If  adequate orthopaedic experience is unavailable, consideration should be given towards early transfer of  this pa tient to an institution with the necessary expertise. If  the source of  the bleeding is in doubt or FAST/CT results are positive, showing a signiﬁcant amount of  blood in the peritoneal cavity , concurrent intra-abdominal injury can - not be excluded and it is wise to perfor m an exploratory lapa - rotomy to treat or rule out intra-abdominal bleeding.

# Planned emergency thoracotomy

Planned emergency thoracotomy

Planned emergency thoracotomy implies an emergency thora cotomy performed as a planned procedure in the operating theatre, directed at the management of a speciﬁc injury . As such, the approach c hosen is dependent on the indication for surgery and the organ injured ( Table 29.5 ). Some organs are best approached through a median sternotomy . Otherwise the thoracotomy may be right or left sided, and these may be joined, producing the so-called ‘clamshell incision’. This gives excellent exposure for any surgeon who is not routinely entering the chest. Posterolateral thoracotomy is not used in the emergency situation because of  the di ﬃ culties in positioning of  the patient, except for speciﬁc access to certain posterior media stinal organs. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF Patients who have su ﬀ ered abdominal trauma can generally be classiﬁed into the following categories based on their physio - logical condition after initial resuscitation: /uni25CF physiologically ‘normal’ – investigation can be completed before treatment is planned; /uni25CF physiologically ‘non-compromised’ – investigation is more limited; it is aimed at establishing whether the patient can be managed non-operatively , whether angioembolisation can be used or whether surgery is required; /uni25CF physiologically ‘compromised’ – investigations need to be suspended as immediate surgical correction of  the bleed - ing is required. A trauma laparotomy is the ﬁnal step in the pathway to delineate intra-abdominal injury . Occasionally it is di ﬃ cult to determine the source of  bleeding in the shocked, multiple injured patient. If  doubt still e xists, especially in the presence of  other injuries, a laparotomy may still be the safest option. - The key is to make a decision, as indecision leads to delay in - deﬁnitive control. - The patient’s physiology must be assessed constantly; if there is an indication that the patient is still actively bleeding, the source must be identiﬁed unless the patient is unstable and requires immediate surgery . Blood loss into the abdomen can be subtle and there may be no clear clinical signs. Blood - is not an irritant and does not initially cause any abdominal pain. Distension is subjective, and a drop in the blood pressure may be a very late sign in a young ﬁt patient. Examination in compromised patients should take place either in the emergency department or in the operating theatre if the patient is deteriorating rapidly . 

TABLE 29.5
Different approaches to the contents of the
chest cavity.
Approach
Best for
Left anterolateral
Left lung and lung hilum
thoracotomy
Thoracic aorta
Origin of left subclavian artery
Left side of heart
Lower oesophagus
Right anterolateral
Right lung and lung hilum
thoracotomy
Azygos veins
Superior vena cava
Infracardiac inferior vena cava
Upper oesophagus
Thoracic trachea
Median sternotomy
Anterior aspect of heart
Anterior mediastinum
Ascending aorta and arch of aorta
Pulmonary arteries
Carina of the trachea

Planned emergency thoracotomy

Planned emergency thoracotomy implies an emergency thora cotomy performed as a planned procedure in the operating theatre, directed at the management of a speciﬁc injury . As such, the approach c hosen is dependent on the indication for surgery and the organ injured ( Table 29.5 ). Some organs are best approached through a median sternotomy . Otherwise the thoracotomy may be right or left sided, and these may be joined, producing the so-called ‘clamshell incision’. This gives excellent exposure for any surgeon who is not routinely entering the chest. Posterolateral thoracotomy is not used in the emergency situation because of  the di ﬃ culties in positioning of  the patient, except for speciﬁc access to certain posterior media stinal organs. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF Patients who have su ﬀ ered abdominal trauma can generally be classiﬁed into the following categories based on their physio - logical condition after initial resuscitation: /uni25CF physiologically ‘normal’ – investigation can be completed before treatment is planned; /uni25CF physiologically ‘non-compromised’ – investigation is more limited; it is aimed at establishing whether the patient can be managed non-operatively , whether angioembolisation can be used or whether surgery is required; /uni25CF physiologically ‘compromised’ – investigations need to be suspended as immediate surgical correction of  the bleed - ing is required. A trauma laparotomy is the ﬁnal step in the pathway to delineate intra-abdominal injury . Occasionally it is di ﬃ cult to determine the source of  bleeding in the shocked, multiple injured patient. If  doubt still e xists, especially in the presence of  other injuries, a laparotomy may still be the safest option. - The key is to make a decision, as indecision leads to delay in - deﬁnitive control. - The patient’s physiology must be assessed constantly; if there is an indication that the patient is still actively bleeding, the source must be identiﬁed unless the patient is unstable and requires immediate surgery . Blood loss into the abdomen can be subtle and there may be no clear clinical signs. Blood - is not an irritant and does not initially cause any abdominal pain. Distension is subjective, and a drop in the blood pressure may be a very late sign in a young ﬁt patient. Examination in compromised patients should take place either in the emergency department or in the operating theatre if the patient is deteriorating rapidly . 

TABLE 29.5
Different approaches to the contents of the
chest cavity.
Approach
Best for
Left anterolateral
Left lung and lung hilum
thoracotomy
Thoracic aorta
Origin of left subclavian artery
Left side of heart
Lower oesophagus
Right anterolateral
Right lung and lung hilum
thoracotomy
Azygos veins
Superior vena cava
Infracardiac inferior vena cava
Upper oesophagus
Thoracic trachea
Median sternotomy
Anterior aspect of heart
Anterior mediastinum
Ascending aorta and arch of aorta
Pulmonary arteries
Carina of the trachea

Planned emergency thoracotomy

Planned emergency thoracotomy implies an emergency thora cotomy performed as a planned procedure in the operating theatre, directed at the management of a speciﬁc injury . As such, the approach c hosen is dependent on the indication for surgery and the organ injured ( Table 29.5 ). Some organs are best approached through a median sternotomy . Otherwise the thoracotomy may be right or left sided, and these may be joined, producing the so-called ‘clamshell incision’. This gives excellent exposure for any surgeon who is not routinely entering the chest. Posterolateral thoracotomy is not used in the emergency situation because of  the di ﬃ culties in positioning of  the patient, except for speciﬁc access to certain posterior media stinal organs. /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF Patients who have su ﬀ ered abdominal trauma can generally be classiﬁed into the following categories based on their physio - logical condition after initial resuscitation: /uni25CF physiologically ‘normal’ – investigation can be completed before treatment is planned; /uni25CF physiologically ‘non-compromised’ – investigation is more limited; it is aimed at establishing whether the patient can be managed non-operatively , whether angioembolisation can be used or whether surgery is required; /uni25CF physiologically ‘compromised’ – investigations need to be suspended as immediate surgical correction of  the bleed - ing is required. A trauma laparotomy is the ﬁnal step in the pathway to delineate intra-abdominal injury . Occasionally it is di ﬃ cult to determine the source of  bleeding in the shocked, multiple injured patient. If  doubt still e xists, especially in the presence of  other injuries, a laparotomy may still be the safest option. - The key is to make a decision, as indecision leads to delay in - deﬁnitive control. - The patient’s physiology must be assessed constantly; if there is an indication that the patient is still actively bleeding, the source must be identiﬁed unless the patient is unstable and requires immediate surgery . Blood loss into the abdomen can be subtle and there may be no clear clinical signs. Blood - is not an irritant and does not initially cause any abdominal pain. Distension is subjective, and a drop in the blood pressure may be a very late sign in a young ﬁt patient. Examination in compromised patients should take place either in the emergency department or in the operating theatre if the patient is deteriorating rapidly . 

TABLE 29.5
Different approaches to the contents of the
chest cavity.
Approach
Best for
Left anterolateral
Left lung and lung hilum
thoracotomy
Thoracic aorta
Origin of left subclavian artery
Left side of heart
Lower oesophagus
Right anterolateral
Right lung and lung hilum
thoracotomy
Azygos veins
Superior vena cava
Infracardiac inferior vena cava
Upper oesophagus
Thoracic trachea
Median sternotomy
Anterior aspect of heart
Anterior mediastinum
Ascending aorta and arch of aorta
Pulmonary arteries
Carina of the trachea

# Potentially life-threatening injuries

Potentially life-threatening injuries

Thoracic aortic disruption Traumatic aortic rupture is a common cause of  sudden death after a vehicle collision or fall from a great height. The vessel is relatively ﬁxed distal to the ligamentum arteriosum, just distal to the origin of  the left subclavian artery . The shear forces from a sudden impact disrupt the intima and media. If  the adventitia is intact, the patient may remain physiologically non-compromised. Thoracic aortic injury should be clinically suspected in patients with gross asymmetry in systolic blood pressure (between the two upper limbs, or between upper and lower limbs), widened pulse pressure and chest wall contusion. Erect c hest radiography can also suggest thoracic aortic disruption, the most common radiological ﬁnding being a widened media stinum ( Figure 29.4 ). The diagnosis is conﬁrmed by a CT scan of  the mediastinum ( Figure 29.5 ). In the hypotensive patient, widening of  the mediastinum and aortic injury is not the cause of  the hypotension. Inv ariably , these patients have other inju ries causing hypotension as patients with complete aortic dis ruption rarely , if  ever, survive to reach hospital. In the presence of  thoracic aortic injury , initial manage ment consists of  control of  the systolic arterial blood pres sure (to less than 120 /uni00A0 mmHg). Thereafter, an endovascular intra-aortic stent ( Figure 29.6 ) can be placed, or the tear can be operatively repaired by direct repair or by excision and grafting using a Dacron g raft. Tracheobronchial injuries Severe subcutaneous emphysema with respiratory compromise can suggest tracheobronchial disruption. A chest drain placed on the a ﬀ ected side will reveal a large air leak and the collapsed lung may fail to re-expand. Bronchoscopy is diagnostic. Treat ment involves intubation of  the una ﬀ ected bronchus followed by operative repair. Referral to a trauma centre is advised. - - - - - - 

Figure 29.5
Computed tomography scan showing aortic disruption
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).
(a)
(b)
Figure 29.6
(a)
Aortic tear showing the presence of a prein
/f_l
ation
stent and test run.
(b)
Aortic tear post in
/f_l
ation of the stent and test
run (courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

Signiﬁcant blunt cardiac injury that causes haemodynamic and physiological instability is rare. Blunt myocardial injury should be suspected in any patient sustaining blunt trauma who develops early electrocardiogram abnormalities. Transthoracic echocardiography may show wall motion abnormalities. A transoesophageal echocardiogram may also be helpful. There is very little evidence that enzyme estima tions have any place in diagnosis . All patients with myocardial contusion diagnosed with con duction abnormalities are at risk of  developing sudden dys rhythmias and should be closely monitored. Diaphragmatic injuries Any penetrating injury below the ﬁfth intercostal space should raise suspicion of  diaphragmatic penetration and, therefore, injury to abdominal contents. Blunt injury to the diaphragm is usually caused by a com pressive force applied to the torso. The diaphragmatic rupture is usually large, with herniation of  the abdominal contents into the chest. Diagnosis of  diaphragmatic rupture can easily be missed in the acute phase, and may only be discovered at oper ation or thr ough the presentation of  complications. Most diaphragmatic injuries are silent and the presenting features are those of  injury to the surrounding organs. There is no single standard investig ation. Historically and in limited resource environments, chest radiography after placement of  a nasogastric tube may be helpful (as this may show the stomach herniated into the chest). CT scan and ultrasound scan all lack positive or negative predictive value. The most accurate evalu ation is by video-assisted thoracoscopy or laparoscopy , the lat ter o ﬀ ering the advantage of  allowing the surgeon to proceed to a repair and additional evaluation of  the abdominal organs. The thorax is at negative pressure and the abdomen is a positive pressure. A complication of  a breach of  the diaphragm is herniation of  abdominal contents into the chest. This may present m uch later, and strangulation of  any of  the contents can then occur, with a high mortality rate. Operative repair is recommended in all cases. All penetrating diaphragmatic injury must be repaired via the abdomen – and not the chest – to rule out penetrating hollow viscus injury . Oesophageal injury Most oesophageal injuries result from penetrating trauma; blunt injury is rare but should be suspected in patients exposed to barotrauma. A high index of  suspicion is required. The patient can present with odynophagia (pain on swallowing saliva, foods or ﬂuids), subcutaneous or mediastinal emphy sema, pleural e ﬀ usion, air in the perioesophageal space and unexplained fever. Mediastinal and deep cervical emphysema are evidence of  an aerodigestive injury until proven otherwise. T he mortality rate rises exponentially if  treatment is delayed. A combination of  CT with oral contrast and oesoph agoscopy conﬁrms the diagnosis in the great majority of  cases. The treatment is operativ e repair of  any defect and drainage. Pulmonary contusion Pulmonary contusion occurs more frequently following blunt trauma, and is usually associated with a ﬂail segment injury and the major cause of  hypoxaemia after blunt trauma. Following gunshot wounds, there is an area of  contusion from the shock wave of  the b ullet. The natural progression of  pulmonary contusion is worsen - ing hypoxaemia for the ﬁrst 24–48 hours. Chest radiographic ﬁndings may be typically delayed. Contrast CT scanning can be conﬁrmatory . Haemoptysis or blood in the endotracheal - tube is a sign of  pulmonary contusion. In mild contusion, the treatment is oxy gen administration, pulmonary toilet and ade - - quate analgesia. In more severe cases mechanical ventilation is - necessary . Normovolaemia is critical for adequate tissue perfu - sion and ﬂuid restriction is not advised. Potentially life-threatening injuries

Thoracic aortic disruption Traumatic aortic rupture is a common cause of  sudden death after a vehicle collision or fall from a great height. The vessel is relatively ﬁxed distal to the ligamentum arteriosum, just distal to the origin of  the left subclavian artery . The shear forces from a sudden impact disrupt the intima and media. If  the adventitia is intact, the patient may remain physiologically non-compromised. Thoracic aortic injury should be clinically suspected in patients with gross asymmetry in systolic blood pressure (between the two upper limbs, or between upper and lower limbs), widened pulse pressure and chest wall contusion. Erect c hest radiography can also suggest thoracic aortic disruption, the most common radiological ﬁnding being a widened media stinum ( Figure 29.4 ). The diagnosis is conﬁrmed by a CT scan of  the mediastinum ( Figure 29.5 ). In the hypotensive patient, widening of  the mediastinum and aortic injury is not the cause of  the hypotension. Inv ariably , these patients have other inju ries causing hypotension as patients with complete aortic dis ruption rarely , if  ever, survive to reach hospital. In the presence of  thoracic aortic injury , initial manage ment consists of  control of  the systolic arterial blood pres sure (to less than 120 /uni00A0 mmHg). Thereafter, an endovascular intra-aortic stent ( Figure 29.6 ) can be placed, or the tear can be operatively repaired by direct repair or by excision and grafting using a Dacron g raft. Tracheobronchial injuries Severe subcutaneous emphysema with respiratory compromise can suggest tracheobronchial disruption. A chest drain placed on the a ﬀ ected side will reveal a large air leak and the collapsed lung may fail to re-expand. Bronchoscopy is diagnostic. Treat ment involves intubation of  the una ﬀ ected bronchus followed by operative repair. Referral to a trauma centre is advised. - - - - - - 

Figure 29.5
Computed tomography scan showing aortic disruption
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).
(a)
(b)
Figure 29.6
(a)
Aortic tear showing the presence of a prein
/f_l
ation
stent and test run.
(b)
Aortic tear post in
/f_l
ation of the stent and test
run (courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

Signiﬁcant blunt cardiac injury that causes haemodynamic and physiological instability is rare. Blunt myocardial injury should be suspected in any patient sustaining blunt trauma who develops early electrocardiogram abnormalities. Transthoracic echocardiography may show wall motion abnormalities. A transoesophageal echocardiogram may also be helpful. There is very little evidence that enzyme estima tions have any place in diagnosis . All patients with myocardial contusion diagnosed with con duction abnormalities are at risk of  developing sudden dys rhythmias and should be closely monitored. Diaphragmatic injuries Any penetrating injury below the ﬁfth intercostal space should raise suspicion of  diaphragmatic penetration and, therefore, injury to abdominal contents. Blunt injury to the diaphragm is usually caused by a com pressive force applied to the torso. The diaphragmatic rupture is usually large, with herniation of  the abdominal contents into the chest. Diagnosis of  diaphragmatic rupture can easily be missed in the acute phase, and may only be discovered at oper ation or thr ough the presentation of  complications. Most diaphragmatic injuries are silent and the presenting features are those of  injury to the surrounding organs. There is no single standard investig ation. Historically and in limited resource environments, chest radiography after placement of  a nasogastric tube may be helpful (as this may show the stomach herniated into the chest). CT scan and ultrasound scan all lack positive or negative predictive value. The most accurate evalu ation is by video-assisted thoracoscopy or laparoscopy , the lat ter o ﬀ ering the advantage of  allowing the surgeon to proceed to a repair and additional evaluation of  the abdominal organs. The thorax is at negative pressure and the abdomen is a positive pressure. A complication of  a breach of  the diaphragm is herniation of  abdominal contents into the chest. This may present m uch later, and strangulation of  any of  the contents can then occur, with a high mortality rate. Operative repair is recommended in all cases. All penetrating diaphragmatic injury must be repaired via the abdomen – and not the chest – to rule out penetrating hollow viscus injury . Oesophageal injury Most oesophageal injuries result from penetrating trauma; blunt injury is rare but should be suspected in patients exposed to barotrauma. A high index of  suspicion is required. The patient can present with odynophagia (pain on swallowing saliva, foods or ﬂuids), subcutaneous or mediastinal emphy sema, pleural e ﬀ usion, air in the perioesophageal space and unexplained fever. Mediastinal and deep cervical emphysema are evidence of  an aerodigestive injury until proven otherwise. T he mortality rate rises exponentially if  treatment is delayed. A combination of  CT with oral contrast and oesoph agoscopy conﬁrms the diagnosis in the great majority of  cases. The treatment is operativ e repair of  any defect and drainage. Pulmonary contusion Pulmonary contusion occurs more frequently following blunt trauma, and is usually associated with a ﬂail segment injury and the major cause of  hypoxaemia after blunt trauma. Following gunshot wounds, there is an area of  contusion from the shock wave of  the b ullet. The natural progression of  pulmonary contusion is worsen - ing hypoxaemia for the ﬁrst 24–48 hours. Chest radiographic ﬁndings may be typically delayed. Contrast CT scanning can be conﬁrmatory . Haemoptysis or blood in the endotracheal - tube is a sign of  pulmonary contusion. In mild contusion, the treatment is oxy gen administration, pulmonary toilet and ade - - quate analgesia. In more severe cases mechanical ventilation is - necessary . Normovolaemia is critical for adequate tissue perfu - sion and ﬂuid restriction is not advised. Potentially life-threatening injuries

Thoracic aortic disruption Traumatic aortic rupture is a common cause of  sudden death after a vehicle collision or fall from a great height. The vessel is relatively ﬁxed distal to the ligamentum arteriosum, just distal to the origin of  the left subclavian artery . The shear forces from a sudden impact disrupt the intima and media. If  the adventitia is intact, the patient may remain physiologically non-compromised. Thoracic aortic injury should be clinically suspected in patients with gross asymmetry in systolic blood pressure (between the two upper limbs, or between upper and lower limbs), widened pulse pressure and chest wall contusion. Erect c hest radiography can also suggest thoracic aortic disruption, the most common radiological ﬁnding being a widened media stinum ( Figure 29.4 ). The diagnosis is conﬁrmed by a CT scan of  the mediastinum ( Figure 29.5 ). In the hypotensive patient, widening of  the mediastinum and aortic injury is not the cause of  the hypotension. Inv ariably , these patients have other inju ries causing hypotension as patients with complete aortic dis ruption rarely , if  ever, survive to reach hospital. In the presence of  thoracic aortic injury , initial manage ment consists of  control of  the systolic arterial blood pres sure (to less than 120 /uni00A0 mmHg). Thereafter, an endovascular intra-aortic stent ( Figure 29.6 ) can be placed, or the tear can be operatively repaired by direct repair or by excision and grafting using a Dacron g raft. Tracheobronchial injuries Severe subcutaneous emphysema with respiratory compromise can suggest tracheobronchial disruption. A chest drain placed on the a ﬀ ected side will reveal a large air leak and the collapsed lung may fail to re-expand. Bronchoscopy is diagnostic. Treat ment involves intubation of  the una ﬀ ected bronchus followed by operative repair. Referral to a trauma centre is advised. - - - - - - 

Figure 29.5
Computed tomography scan showing aortic disruption
(courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).
(a)
(b)
Figure 29.6
(a)
Aortic tear showing the presence of a prein
/f_l
ation
stent and test run.
(b)
Aortic tear post in
/f_l
ation of the stent and test
run (courtesy of Dr Elizabeth Dick, Consultant Radiologist, Imperial
College Healthcare NHS Trust, London, UK).

Signiﬁcant blunt cardiac injury that causes haemodynamic and physiological instability is rare. Blunt myocardial injury should be suspected in any patient sustaining blunt trauma who develops early electrocardiogram abnormalities. Transthoracic echocardiography may show wall motion abnormalities. A transoesophageal echocardiogram may also be helpful. There is very little evidence that enzyme estima tions have any place in diagnosis . All patients with myocardial contusion diagnosed with con duction abnormalities are at risk of  developing sudden dys rhythmias and should be closely monitored. Diaphragmatic injuries Any penetrating injury below the ﬁfth intercostal space should raise suspicion of  diaphragmatic penetration and, therefore, injury to abdominal contents. Blunt injury to the diaphragm is usually caused by a com pressive force applied to the torso. The diaphragmatic rupture is usually large, with herniation of  the abdominal contents into the chest. Diagnosis of  diaphragmatic rupture can easily be missed in the acute phase, and may only be discovered at oper ation or thr ough the presentation of  complications. Most diaphragmatic injuries are silent and the presenting features are those of  injury to the surrounding organs. There is no single standard investig ation. Historically and in limited resource environments, chest radiography after placement of  a nasogastric tube may be helpful (as this may show the stomach herniated into the chest). CT scan and ultrasound scan all lack positive or negative predictive value. The most accurate evalu ation is by video-assisted thoracoscopy or laparoscopy , the lat ter o ﬀ ering the advantage of  allowing the surgeon to proceed to a repair and additional evaluation of  the abdominal organs. The thorax is at negative pressure and the abdomen is a positive pressure. A complication of  a breach of  the diaphragm is herniation of  abdominal contents into the chest. This may present m uch later, and strangulation of  any of  the contents can then occur, with a high mortality rate. Operative repair is recommended in all cases. All penetrating diaphragmatic injury must be repaired via the abdomen – and not the chest – to rule out penetrating hollow viscus injury . Oesophageal injury Most oesophageal injuries result from penetrating trauma; blunt injury is rare but should be suspected in patients exposed to barotrauma. A high index of  suspicion is required. The patient can present with odynophagia (pain on swallowing saliva, foods or ﬂuids), subcutaneous or mediastinal emphy sema, pleural e ﬀ usion, air in the perioesophageal space and unexplained fever. Mediastinal and deep cervical emphysema are evidence of  an aerodigestive injury until proven otherwise. T he mortality rate rises exponentially if  treatment is delayed. A combination of  CT with oral contrast and oesoph agoscopy conﬁrms the diagnosis in the great majority of  cases. The treatment is operativ e repair of  any defect and drainage. Pulmonary contusion Pulmonary contusion occurs more frequently following blunt trauma, and is usually associated with a ﬂail segment injury and the major cause of  hypoxaemia after blunt trauma. Following gunshot wounds, there is an area of  contusion from the shock wave of  the b ullet. The natural progression of  pulmonary contusion is worsen - ing hypoxaemia for the ﬁrst 24–48 hours. Chest radiographic ﬁndings may be typically delayed. Contrast CT scanning can be conﬁrmatory . Haemoptysis or blood in the endotracheal - tube is a sign of  pulmonary contusion. In mild contusion, the treatment is oxy gen administration, pulmonary toilet and ade - - quate analgesia. In more severe cases mechanical ventilation is - necessary . Normovolaemia is critical for adequate tissue perfu - sion and ﬂuid restriction is not advised.

# Rectum

Rectum

Approximately 5% of colon injuries involve the rectum. These are generally from a penetrating injury , although occasionally the rectum may be damaged following fracture of  the pelvis. Digital rectal examination will reveal the pres ence of  blood, which is evidence of  intestinal or rectal injury . These injuries are often associated with bladder and proximal urethral injury . W ith intraperitoneal injuries, the rectum is managed as for colonic injuries. Full-thickness extraperitoneal rectal injuries can be managed with primary repair and drainage depending on the type of  injury , i.e. suitable for knife wounds but not bal listic trauma. Where there is extensive tissue loss, this should be managed with either a diverting end-colostomy and closure of  the distal end (Hartmann’s procedure) or a loop colostomy . Presacral drainage is no longer used. Rectum

Approximately 5% of colon injuries involve the rectum. These are generally from a penetrating injury , although occasionally the rectum may be damaged following fracture of  the pelvis. Digital rectal examination will reveal the pres ence of  blood, which is evidence of  intestinal or rectal injury . These injuries are often associated with bladder and proximal urethral injury . W ith intraperitoneal injuries, the rectum is managed as for colonic injuries. Full-thickness extraperitoneal rectal injuries can be managed with primary repair and drainage depending on the type of  injury , i.e. suitable for knife wounds but not bal listic trauma. Where there is extensive tissue loss, this should be managed with either a diverting end-colostomy and closure of  the distal end (Hartmann’s procedure) or a loop colostomy . Presacral drainage is no longer used. Rectum

Approximately 5% of colon injuries involve the rectum. These are generally from a penetrating injury , although occasionally the rectum may be damaged following fracture of  the pelvis. Digital rectal examination will reveal the pres ence of  blood, which is evidence of  intestinal or rectal injury . These injuries are often associated with bladder and proximal urethral injury . W ith intraperitoneal injuries, the rectum is managed as for colonic injuries. Full-thickness extraperitoneal rectal injuries can be managed with primary repair and drainage depending on the type of  injury , i.e. suitable for knife wounds but not bal listic trauma. Where there is extensive tissue loss, this should be managed with either a diverting end-colostomy and closure of  the distal end (Hartmann’s procedure) or a loop colostomy . Presacral drainage is no longer used.

# Renal and urological tract injury

Renal and urological tract injury

In physiologically non-compromised patients, CT scanning with contrast is the investigation of  choice. For assessment of bladder injury a cystogram should be performed at the time of  CT . A minimum of  300 /uni00A0 mL of  contrast is instilled into the bladder via a urethral catheter. The large volume is essential because a small volume may not distend the bladder enough to produce a leak from a small bladder injury , once the cystic muscle is contracted. Generally , renal injury is managed non-operatively unless the patient is physiologically compromised. The kidney can be angioembolised if  required. Henri Albert Charles Antoine Hartmann , 1860–1952, Professor of  Clinical Surgery , Faculty of  Medicine, University of  Paris, Paris, France. - Ureteric injury is rare and is generally due to penetrating trauma. Most ureters can be repaired or diverted if necessary , or may even be ligated as part of  damage control procedures. Intraperitoneal rupture of  the bladder, usually from direct blunt injury , will require surgical repair. Extraperitoneal rup - ture is usually associated with a fracture of  the pelvis and will heal with adequate urine drainage via the transurethral route . Suprapubic drainage is reserved for when this is not possible. - Summary box 29.7 Injuries to structures in the abdomen /uni25CF - /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

2
2
3
Figure 29.10
The zones of the retroperitoneum. Zone 1, central; zone
2, lateral; zone 3, pelvic.
In children, splenic injury can be managed non-operatively in
most cases, but not if physiologically compromised
Duodenal injuries are often associated with pancreatic trauma
Bowel injuries need urgent de
/f_i
nitive repair, or isolation using
resection or by stapling
Rectal injuries are managed depending on whether intra- or
extraperitoneal
Kidney and urinary tract injuries are best diagnosed with
contrast CT scanning
Intraperitoneal bladder tears need formal repair and drainage

Renal and urological tract injury

In physiologically non-compromised patients, CT scanning with contrast is the investigation of  choice. For assessment of bladder injury a cystogram should be performed at the time of  CT . A minimum of  300 /uni00A0 mL of  contrast is instilled into the bladder via a urethral catheter. The large volume is essential because a small volume may not distend the bladder enough to produce a leak from a small bladder injury , once the cystic muscle is contracted. Generally , renal injury is managed non-operatively unless the patient is physiologically compromised. The kidney can be angioembolised if  required. Henri Albert Charles Antoine Hartmann , 1860–1952, Professor of  Clinical Surgery , Faculty of  Medicine, University of  Paris, Paris, France. - Ureteric injury is rare and is generally due to penetrating trauma. Most ureters can be repaired or diverted if necessary , or may even be ligated as part of  damage control procedures. Intraperitoneal rupture of  the bladder, usually from direct blunt injury , will require surgical repair. Extraperitoneal rup - ture is usually associated with a fracture of  the pelvis and will heal with adequate urine drainage via the transurethral route . Suprapubic drainage is reserved for when this is not possible. - Summary box 29.7 Injuries to structures in the abdomen /uni25CF - /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

2
2
3
Figure 29.10
The zones of the retroperitoneum. Zone 1, central; zone
2, lateral; zone 3, pelvic.
In children, splenic injury can be managed non-operatively in
most cases, but not if physiologically compromised
Duodenal injuries are often associated with pancreatic trauma
Bowel injuries need urgent de
/f_i
nitive repair, or isolation using
resection or by stapling
Rectal injuries are managed depending on whether intra- or
extraperitoneal
Kidney and urinary tract injuries are best diagnosed with
contrast CT scanning
Intraperitoneal bladder tears need formal repair and drainage

Renal and urological tract injury

In physiologically non-compromised patients, CT scanning with contrast is the investigation of  choice. For assessment of bladder injury a cystogram should be performed at the time of  CT . A minimum of  300 /uni00A0 mL of  contrast is instilled into the bladder via a urethral catheter. The large volume is essential because a small volume may not distend the bladder enough to produce a leak from a small bladder injury , once the cystic muscle is contracted. Generally , renal injury is managed non-operatively unless the patient is physiologically compromised. The kidney can be angioembolised if  required. Henri Albert Charles Antoine Hartmann , 1860–1952, Professor of  Clinical Surgery , Faculty of  Medicine, University of  Paris, Paris, France. - Ureteric injury is rare and is generally due to penetrating trauma. Most ureters can be repaired or diverted if necessary , or may even be ligated as part of  damage control procedures. Intraperitoneal rupture of  the bladder, usually from direct blunt injury , will require surgical repair. Extraperitoneal rup - ture is usually associated with a fracture of  the pelvis and will heal with adequate urine drainage via the transurethral route . Suprapubic drainage is reserved for when this is not possible. - Summary box 29.7 Injuries to structures in the abdomen /uni25CF - /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

2
2
3
Figure 29.10
The zones of the retroperitoneum. Zone 1, central; zone
2, lateral; zone 3, pelvic.
In children, splenic injury can be managed non-operatively in
most cases, but not if physiologically compromised
Duodenal injuries are often associated with pancreatic trauma
Bowel injuries need urgent de
/f_i
nitive repair, or isolation using
resection or by stapling
Rectal injuries are managed depending on whether intra- or
extraperitoneal
Kidney and urinary tract injuries are best diagnosed with
contrast CT scanning
Intraperitoneal bladder tears need formal repair and drainage

# Retroperitoneum

Retroperitoneum

Injury to the retroperitoneum is often di ﬃ cult to diagnose, especially in the presence of  other injury , when the signs may be masked. Diagnostic tests (such as ultrasound and DPL) may be negative. The best diagnostic modality is CT , but this requires a physiologically stable patient. The retroperitoneum is divided into three zones ( Figure 29.10 ) for the purposes of intraoperative management in blunt trauma: explored, once proximal and distal vascular control has been obtained. /uni25CF Zone 2 (lateral): lateral haematomas should only be ex plored if  they are expanding or pulsatile or penetrating injury is present. They are usually renal in origin and can be managed non-operatively , although they may some times require angioembolisation. /uni25CF Zone 3 (pelvic): as with zone 2, these should only be explored if  they are expanding or pulsatile or penetrating injury is present. Pelvic haematomas are exceptionally di ﬃ cult to control and, whenever possible, should not be opened; they are best controlled with compression or extraperitoneal packing, or, if  the bleeding is arterial in origin, with angioembolisation. Retroperitoneum

Injury to the retroperitoneum is often di ﬃ cult to diagnose, especially in the presence of  other injury , when the signs may be masked. Diagnostic tests (such as ultrasound and DPL) may be negative. The best diagnostic modality is CT , but this requires a physiologically stable patient. The retroperitoneum is divided into three zones ( Figure 29.10 ) for the purposes of intraoperative management in blunt trauma: explored, once proximal and distal vascular control has been obtained. /uni25CF Zone 2 (lateral): lateral haematomas should only be ex plored if  they are expanding or pulsatile or penetrating injury is present. They are usually renal in origin and can be managed non-operatively , although they may some times require angioembolisation. /uni25CF Zone 3 (pelvic): as with zone 2, these should only be explored if  they are expanding or pulsatile or penetrating injury is present. Pelvic haematomas are exceptionally di ﬃ cult to control and, whenever possible, should not be opened; they are best controlled with compression or extraperitoneal packing, or, if  the bleeding is arterial in origin, with angioembolisation. Retroperitoneum

Injury to the retroperitoneum is often di ﬃ cult to diagnose, especially in the presence of  other injury , when the signs may be masked. Diagnostic tests (such as ultrasound and DPL) may be negative. The best diagnostic modality is CT , but this requires a physiologically stable patient. The retroperitoneum is divided into three zones ( Figure 29.10 ) for the purposes of intraoperative management in blunt trauma: explored, once proximal and distal vascular control has been obtained. /uni25CF Zone 2 (lateral): lateral haematomas should only be ex plored if  they are expanding or pulsatile or penetrating injury is present. They are usually renal in origin and can be managed non-operatively , although they may some times require angioembolisation. /uni25CF Zone 3 (pelvic): as with zone 2, these should only be explored if  they are expanding or pulsatile or penetrating injury is present. Pelvic haematomas are exceptionally di ﬃ cult to control and, whenever possible, should not be opened; they are best controlled with compression or extraperitoneal packing, or, if  the bleeding is arterial in origin, with angioembolisation.

# Small bowel

Small bowel

- The small bowel is frequently injured as a result of blunt trauma. - The individual loops may be trapped, causing high-pressure rupture of  a loop or tearing of  the mesentery . Penetrating trauma is also a common cause of  injury . control takes priority and these wounds can be temporarily controlled with simple sutures. In blunt trauma with mesenteric vessel damage, the bowel ischaemia that results will dictate the extent of  a resection. Resections should be carefully planned to limit the loss of  viable small bowel, but should be weighed against an excessive number of  repairs or anastomoses. Haematomas in the small bowel mesenteric border need to be explored to rule out perforation. With low-energy wounds, primary repair can be performed, whereas more destructive wounds associated with military-type weapons require resection and anastomosis. Damage control ‘clip and drop’ of damaged or resected bowel may be necessary . Small bowel

- The small bowel is frequently injured as a result of blunt trauma. - The individual loops may be trapped, causing high-pressure rupture of  a loop or tearing of  the mesentery . Penetrating trauma is also a common cause of  injury . control takes priority and these wounds can be temporarily controlled with simple sutures. In blunt trauma with mesenteric vessel damage, the bowel ischaemia that results will dictate the extent of  a resection. Resections should be carefully planned to limit the loss of  viable small bowel, but should be weighed against an excessive number of  repairs or anastomoses. Haematomas in the small bowel mesenteric border need to be explored to rule out perforation. With low-energy wounds, primary repair can be performed, whereas more destructive wounds associated with military-type weapons require resection and anastomosis. Damage control ‘clip and drop’ of damaged or resected bowel may be necessary . Small bowel

- The small bowel is frequently injured as a result of blunt trauma. - The individual loops may be trapped, causing high-pressure rupture of  a loop or tearing of  the mesentery . Penetrating trauma is also a common cause of  injury . control takes priority and these wounds can be temporarily controlled with simple sutures. In blunt trauma with mesenteric vessel damage, the bowel ischaemia that results will dictate the extent of  a resection. Resections should be carefully planned to limit the loss of  viable small bowel, but should be weighed against an excessive number of  repairs or anastomoses. Haematomas in the small bowel mesenteric border need to be explored to rule out perforation. With low-energy wounds, primary repair can be performed, whereas more destructive wounds associated with military-type weapons require resection and anastomosis. Damage control ‘clip and drop’ of damaged or resected bowel may be necessary .

# Spleen

Spleen

Splenic injury occurs from direct blunt trauma. Most isolated splenic injuries, especially in children, can be managed non-operatively . However, in adults, especially in the presence of  other injury or physiological compromise, laparotomy should be considered. The spleen can be theoretically packed, repaired or placed in a mesh bag. However, in reality , splenec tomy is the safer option, especially in the compromised patient with multiple potential sites of  bleeding. In certain situations, selective angioembolisation of  the spleen can play a role. Following splenectomy there are signiﬁcant, though tran sient, changes to blood physiology . The platelet and white count rise and may mimic sepsis. Inoculation against Pneumo coccus is advisable within 2–3 weeks, by which time the patient’s immune system has recovered. Allen Oldfather Whipple , 1881–1963, V alentine Mott Professor of  Surgery , The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA. Most pancreatic injury occurs as a result of  blunt trauma. The major problem is that of  diagnosis because the pancreas is a retroperitoneal organ. CT remains the mainstay of  accurate diagnosis. Amylase or lipase estimation is insensitive. In pene - trating trauma, injury may only be detected during laparotomy . Classically the pancreas should be treated with conser - vative surgery and closed, low-suction drainage. Injuries are treated according to the ISS system of the AAST . Injuries to the pancreatic body to the left of the superior mesenteric ves - sels and to the tail are treated by closed drainage alone, with distal pancreatectomy if  the duct is involved. Proximal injuries (to the right of  the superior mesenteric artery) are treated as conservativ ely as possible, although partial pancreatectomy may be necessary . The role of  pyloric exclusion remains con - troversial and remains surgeon dependent. A Whipple’s proce - dure (pancreaticoduodenectomy) is rarely needed and should not be performed in the emergency situation because of the very high associated mortality rate . A damage control proce - dure with packing and drainage should be performed and the patient referred for deﬁnitive surgery once stabilised. Spleen

Splenic injury occurs from direct blunt trauma. Most isolated splenic injuries, especially in children, can be managed non-operatively . However, in adults, especially in the presence of  other injury or physiological compromise, laparotomy should be considered. The spleen can be theoretically packed, repaired or placed in a mesh bag. However, in reality , splenec tomy is the safer option, especially in the compromised patient with multiple potential sites of  bleeding. In certain situations, selective angioembolisation of  the spleen can play a role. Following splenectomy there are signiﬁcant, though tran sient, changes to blood physiology . The platelet and white count rise and may mimic sepsis. Inoculation against Pneumo coccus is advisable within 2–3 weeks, by which time the patient’s immune system has recovered. Allen Oldfather Whipple , 1881–1963, V alentine Mott Professor of  Surgery , The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA. Most pancreatic injury occurs as a result of  blunt trauma. The major problem is that of  diagnosis because the pancreas is a retroperitoneal organ. CT remains the mainstay of  accurate diagnosis. Amylase or lipase estimation is insensitive. In pene - trating trauma, injury may only be detected during laparotomy . Classically the pancreas should be treated with conser - vative surgery and closed, low-suction drainage. Injuries are treated according to the ISS system of the AAST . Injuries to the pancreatic body to the left of the superior mesenteric ves - sels and to the tail are treated by closed drainage alone, with distal pancreatectomy if  the duct is involved. Proximal injuries (to the right of  the superior mesenteric artery) are treated as conservativ ely as possible, although partial pancreatectomy may be necessary . The role of  pyloric exclusion remains con - troversial and remains surgeon dependent. A Whipple’s proce - dure (pancreaticoduodenectomy) is rarely needed and should not be performed in the emergency situation because of the very high associated mortality rate . A damage control proce - dure with packing and drainage should be performed and the patient referred for deﬁnitive surgery once stabilised. Spleen

Splenic injury occurs from direct blunt trauma. Most isolated splenic injuries, especially in children, can be managed non-operatively . However, in adults, especially in the presence of  other injury or physiological compromise, laparotomy should be considered. The spleen can be theoretically packed, repaired or placed in a mesh bag. However, in reality , splenec tomy is the safer option, especially in the compromised patient with multiple potential sites of  bleeding. In certain situations, selective angioembolisation of  the spleen can play a role. Following splenectomy there are signiﬁcant, though tran sient, changes to blood physiology . The platelet and white count rise and may mimic sepsis. Inoculation against Pneumo coccus is advisable within 2–3 weeks, by which time the patient’s immune system has recovered. Allen Oldfather Whipple , 1881–1963, V alentine Mott Professor of  Surgery , The College of  Physicians and Surgeons, Columbia University , New Y ork, NY , USA. Most pancreatic injury occurs as a result of  blunt trauma. The major problem is that of  diagnosis because the pancreas is a retroperitoneal organ. CT remains the mainstay of  accurate diagnosis. Amylase or lipase estimation is insensitive. In pene - trating trauma, injury may only be detected during laparotomy . Classically the pancreas should be treated with conser - vative surgery and closed, low-suction drainage. Injuries are treated according to the ISS system of the AAST . Injuries to the pancreatic body to the left of the superior mesenteric ves - sels and to the tail are treated by closed drainage alone, with distal pancreatectomy if  the duct is involved. Proximal injuries (to the right of  the superior mesenteric artery) are treated as conservativ ely as possible, although partial pancreatectomy may be necessary . The role of  pyloric exclusion remains con - troversial and remains surgeon dependent. A Whipple’s proce - dure (pancreaticoduodenectomy) is rarely needed and should not be performed in the emergency situation because of the very high associated mortality rate . A damage control proce - dure with packing and drainage should be performed and the patient referred for deﬁnitive surgery once stabilised.

# Stomach

Stomach

Most stomach injuries are caused by penetrating trauma. Blood presence is diagnostic if  found in the nasogastric tube, in the absence of  bleeding from other sources. Surgical repair is required but great care must be taken to examine the stomach fully , as an injury to the front of  the stomach can be expected to have an ‘exit’ wound elsewhere on the organ. Stomach

Most stomach injuries are caused by penetrating trauma. Blood presence is diagnostic if  found in the nasogastric tube, in the absence of  bleeding from other sources. Surgical repair is required but great care must be taken to examine the stomach fully , as an injury to the front of  the stomach can be expected to have an ‘exit’ wound elsewhere on the organ. Stomach

Most stomach injuries are caused by penetrating trauma. Blood presence is diagnostic if  found in the nasogastric tube, in the absence of  bleeding from other sources. Surgical repair is required but great care must be taken to examine the stomach fully , as an injury to the front of  the stomach can be expected to have an ‘exit’ wound elsewhere on the organ.

# Summary

Summary

In summary , a haemodynamically normal patient can be safely transferred for stabilisation of  unstable fractures within hours after injury and following control of  the associated damage. Pelvic injury /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Associated injuries can only be managed once the patient is
physiologically non-compromised
Decision on the stability is of paramount importance
Procedures for damage control may be the only available
option
External stabilisation of the pelvic ring is the basis of all
treatment
If necessary, further bleeding control can be achieved either by
angioembolisation or by extraperitoneal packing

Summary

In summary , a haemodynamically normal patient can be safely transferred for stabilisation of  unstable fractures within hours after injury and following control of  the associated damage. Pelvic injury /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Associated injuries can only be managed once the patient is
physiologically non-compromised
Decision on the stability is of paramount importance
Procedures for damage control may be the only available
option
External stabilisation of the pelvic ring is the basis of all
treatment
If necessary, further bleeding control can be achieved either by
angioembolisation or by extraperitoneal packing

Summary

In summary , a haemodynamically normal patient can be safely transferred for stabilisation of  unstable fractures within hours after injury and following control of  the associated damage. Pelvic injury /uni25CF /uni25CF /uni25CF /uni25CF /uni25CF 

Associated injuries can only be managed once the patient is
physiologically non-compromised
Decision on the stability is of paramount importance
Procedures for damage control may be the only available
option
External stabilisation of the pelvic ring is the basis of all
treatment
If necessary, further bleeding control can be achieved either by
angioembolisation or by extraperitoneal packing

# THE PEL VIS

THE PEL VIS

Although mortality following severe pelvic fractures has decreased dramatically with better methods of  controlling haemorrhage, these patients still represent a signiﬁcant challenge to every link of  the treatment chain. Mortality rates exceeding 40% have recently been reported. Further, pelvic bleeding as one of  the ‘hidden bleeding sources’ is still underestimated or missed, as retrospective chart analyses of potentially preventable deaths have revealed. Extreme force is required to disrupt the pelvic ring, and associated injuries and extrapelvic bleeding sources are common (up to 50% of cases). The haemodynamically unstable patient with severe pelvic fracture has a 90% risk of  associated injuries and a 30% risk of  intra-abdominal bleeding. To save these patients, three questions need to be addressed: /uni25CF Is the patient at high risk of  massive bleeding? /uni25CF Where is the source of  the bleeding? /uni25CF How to stop the bleeding? THE PEL VIS

Although mortality following severe pelvic fractures has decreased dramatically with better methods of  controlling haemorrhage, these patients still represent a signiﬁcant challenge to every link of  the treatment chain. Mortality rates exceeding 40% have recently been reported. Further, pelvic bleeding as one of  the ‘hidden bleeding sources’ is still underestimated or missed, as retrospective chart analyses of potentially preventable deaths have revealed. Extreme force is required to disrupt the pelvic ring, and associated injuries and extrapelvic bleeding sources are common (up to 50% of cases). The haemodynamically unstable patient with severe pelvic fracture has a 90% risk of  associated injuries and a 30% risk of  intra-abdominal bleeding. To save these patients, three questions need to be addressed: /uni25CF Is the patient at high risk of  massive bleeding? /uni25CF Where is the source of  the bleeding? /uni25CF How to stop the bleeding? THE PEL VIS

Although mortality following severe pelvic fractures has decreased dramatically with better methods of  controlling haemorrhage, these patients still represent a signiﬁcant challenge to every link of  the treatment chain. Mortality rates exceeding 40% have recently been reported. Further, pelvic bleeding as one of  the ‘hidden bleeding sources’ is still underestimated or missed, as retrospective chart analyses of potentially preventable deaths have revealed. Extreme force is required to disrupt the pelvic ring, and associated injuries and extrapelvic bleeding sources are common (up to 50% of cases). The haemodynamically unstable patient with severe pelvic fracture has a 90% risk of  associated injuries and a 30% risk of  intra-abdominal bleeding. To save these patients, three questions need to be addressed: /uni25CF Is the patient at high risk of  massive bleeding? /uni25CF Where is the source of  the bleeding? /uni25CF How to stop the bleeding?

# THORACIC INJURY

THORACIC INJURY

Thoracic injury accounts for 25% of  all severe injuries. In a - further 25%, it may be a signiﬁcant contributor to the subse - quent death of  the patient. In most of  these patients, the cause of  death is haemorrhage. In excess of  80% of  patients with chest injury can be managed non-operatively . The key to a good outcome is early physiological r esuscitation followed by a correct diagnosis. THORACIC INJURY

Thoracic injury accounts for 25% of  all severe injuries. In a - further 25%, it may be a signiﬁcant contributor to the subse - quent death of  the patient. In most of  these patients, the cause of  death is haemorrhage. In excess of  80% of  patients with chest injury can be managed non-operatively . The key to a good outcome is early physiological r esuscitation followed by a correct diagnosis. THORACIC INJURY

Thoracic injury accounts for 25% of  all severe injuries. In a - further 25%, it may be a signiﬁcant contributor to the subse - quent death of  the patient. In most of  these patients, the cause of  death is haemorrhage. In excess of  80% of  patients with chest injury can be managed non-operatively . The key to a good outcome is early physiological r esuscitation followed by a correct diagnosis.