ANATOMY

There are 26 (25 with variant) main bones in the foot (seven tarsal bones, ﬁve metatarsals and 14 phalanges [13 in the biphalangeal ﬁfth toe variant]) plus the two sesamoids of the hallux and a variable number of other sesamoid and accessory bones. Movements at the ankle joint are mainly dorsiﬂexion and plantarﬂexion, but are more complex than this. The joint is actually a truncated section of a cone, meaning that the motion is not simply a hinge; in addition, movement of the ankle leads to rotation of the ﬁb ula at the syndesmosis. This means that the foot externally rotates with dorsiﬂexion and internally rotates with plantarﬂexion. Stability is conferred upon the ankle by the congruence of the mortice and the integrity of principally the medial, lateral and inferior tibioﬁbular ligaments. The subtalar joint is divided into anterior, middle and posterior facets and, along with the talonavicular and calca neocuboid joints, makes up the triple joint complex. These joints are responsible f or inversion and eversion of the hind- and midfoot. The joints are co-dependent such that limitation of one a ﬀ ects movement at the others. Fusion of the triple complex slightly a ﬀ ects movement at the ankle and vice versa. The second tarsometatarsal (TMT) joint is recessed relative to the ﬁrst and third and acts as a ‘keystone’. Disruption of this joint (Lisfranc’s injury) leads to loss of the transverse arch and an acquired ﬂat foot. The lower leg is divided into f our compartments: /uni25CF the superﬁcial posterior – gastrocnemius, soleus and plantaris; Jacques Lisfranc , 1790–1847, Professor of Surgery and Operative Medicine, Paris, France. /uni25CF the deep posterior – tibialis posterior, ﬂexor digitorum longus and ﬂexor hallucis longus (FHL); /uni25CF the lateral – peroneus brevis and peroneus longus; /uni25CF the anterior – tibialis anterior, extensor hallucis longus, extensor digitorum longus and peroneus tertius. There is only one muscle on the dorsum of the foot, the extensor digitorum brevis. The muscles on the plantar aspect of the foot are divided into four layers, the ﬁrst being the most superﬁcial, and the course of the neur ovascular structures is a favourite examination topic. The plantar fascia is a very important structure that takes its origin from the heel and inserts into the bases of the proximal phalanges of the toes. At toe-o ﬀ , the fascia tightens and accentuates the medial plantar arch and helps provide a rigid lever arm, the so-called ‘windlass mechanism’. This is essential in the preservation of the integ - rity of the arch of the foot and function of the toes. The blood supply of the foot is from the anterior tibial, the posterior tibial and the peroneal arteries. The following nerves - supply sensation to the foot: posterior tibial, saphenous, sural, superﬁcial and deep peroneal ( Figure 41.1 ). Summary box 41.1 Anatomy of the foot /uni25CF /uni25CF /uni25CF

The principles behind the treatment of each condition, be • it conservative or surgical The signi /f_i cance of progressive neurological diseases • There are 26 major bones in the foot There are four layers of muscles in the sole of the foot The blood supply of the foot is from the anterior and posterior tibial arteries plus the peroneal artery

or medial plantar nerve (from tibial nerve) Medial plantar nerve (branch of tibial nerve) Lateral plantar branch of medial plantar nerve (branch of tibial nerve) Sural nerve Saphenous nerve Super /f_i cial peroneal nerve Medial calcaneal nerve (tibial nerve) Lateral plantar nerve Figure 41.1 Cutaneous nerve supply of the foot (courtesy of Bartleby.com).

ANATOMY

AVO I DA B L E FAC TO R S T H AT COMPOUND THE RESP

AVO I DA B L E FAC TO R S T H AT COMPOUND THE RESPONSE TO

Agonists and antagonists an uncertain balance

Alterations in hepatic protein metabolism the acu

Alterations in hepatic protein metabolism the acute-phase protein response

Alterations in skeletal muscle protein metabolism

C A a n

CHANGES IN BODY COMPOSITION FOLLOWING INJURY

ENHANCED RECOVERY AFTER SURGERY

FURTHER READING

Homeostasis

Hypothermia

INJURY

Immobilisation

Immobility

Introduction

Learning objectives

MANAGING THE CATABOLIC STRESS RESPONSE

MEDIATORS OF THE METABOLIC RESPONSE TO INJURY Tiss

MEDIATORS OF THE METABOLIC RESPONSE TO INJURY Tissue damage and inﬂammation

METABOLIC CHANGES AFTER SURGERY AND TRAUMA

Modern surgical care

Neuroendocrine response to injury

RESPONSE

Starvation

Systemic inﬂammation and tissue

Tissue oedema

Volume loss

b b o

l i i

s s m m

t a a

underperfusion

Analgesia

DEFINITION

DISCHARGE FROM HOSPITAL

Direct robotic systems and hybrid robotic surgery

Disadvantages of robotic surgery

Drains

Endoluminal endoscopy and natural oriﬁce surgery

Endoscopic surgery

FURTHER DEVELOPMENTS Augmented reality and minimal access surgical adjuncts

FURTHER DEVELOPMENTS Augmented reality and minimal

GENERAL INTRAOPERATIVE PRINCIPLES

History of minimal access surgery

History of robotic surgery

Hybrid minimal access surgery

Introduction

LIMITATIONS OF MINIMAL ACCESS SURGERY

Learning objectives

MINIMAL ACCESS APPROACHES Laparoscopy

Mobility and convalescence

Operative problems

Oral feeding

Oral ﬂuids

Orogastric or nasogastric tube

PERIOPERATIVE PLANNING FOR MINIMAL ACCESS SURGERY

POSTOPERATIVE CARE

Perivisceral endoscopy

Port site pain and numbness

Preparation of the patient

Principles of electrosurgery during laparoscopic s

Principles of electrosurgery during laparoscopic surgery

ROBOTIC SURGERY

SURGICAL TRAUMA IN OPEN, MINIMALL Y INVASIVE AND R

SURGICAL TRAUMA IN OPEN, MINIMALL Y INVASIVE AND ROBOTIC SURGERY

Shoulder tip pain

Single-incision minimal access surgery

Skin sutures

THE FUTURE

THEATRE SET-UP AND TOOLS

Thoracoscopy

Uptake of robotic surgery

Urinary catheter

surgery

ACKNOWLEDGEMENTS

ASSESSMENT Light microscopy

AUTOPSY

BRAF V600E mutation

Basic methods in diagnostic molecular pathology