14 - 44_Adverse_Drug_Reactions

01 - 1. Types of adverse reactions
1. Types of adverse reactions
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Types of adverse reactions
Type of reaction
Mnemonics
Features
A: dose-related
Augmented
e.g., Lithium toxicity – ataxia, coarse tremors, vomiting.
B: non-dose
related
Bizarre
Idiosyncratic e.g. malignant hyperthermia, or lamotrigine
induced Steven Johnson syndrome
C: dose and time
related
Continuous
use
Related to cumulative drug use—e.g. long term lithium use
and renal damage
D: delayed effect
Delayed
Not due to dose per se but due to the length of use of a
medication e.g. tardive dyskinesia in some cases.
E: Withdrawal
End of use
Related to abrupt discontinuation e.g. SSRI discontinuation
reaction, opioid withdrawal effects, etc.
Tolerance is defined as the need to use increased doses of a drug to maintain a clinical effect.
Tolerance is seen for both therapeutic effects and side effect. This may be due to decreased
sensitivity of the target receptors due to down-regulation (decrease in numbers in case of
agonists), up-regulation (increase in number of receptors in case of antagonists), or reduced
responsivity without alterations in receptor numbers.
Drugs with similar pharmacological actions can exhibit cross-tolerance e.g. benzodiazepines
and barbiturates.
Sensitization (aka reverse tolerance) manifests when sensitivity to a drug effect increases
over time i.e. the same dose typically produces more pronounced effects as treatment
progresses. This is reported with the street use of cocaine.
Note that up or down-regulation can be a mechanism of therapeutic effect e.g. in case of SSRIs, the 5HT1A
autoreceptors in somatodendritic zones undergo downregulation secondary to increased serotonin
availability in the vicinity when reuptake is blocked; this in turn leads to an increase in serotonergic tone
of the neurons.
Withdrawal: When drugs are administered for a reasonable period of time, a physiological
adaptation develops which on withdrawal of the drug can get disturbed and leads to
withdrawal symptoms. Abrupt withdrawal of treatment especially for an agent with shorter
elimination half-life leads to clinically significant withdrawal symptoms. Hypnotics, opiates,
barbiturates, SSRIs, Venlafaxine are some of the drugs associated with discontinuation
reaction or withdrawal symptoms. The variables influencing withdrawal symptoms are listed
below:
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Half life
Methadone has less withdrawal than heroin as methadone has longer
t1/2
Range of action
Paroxetine has anticholinergic properties; withdrawal causes cholinergic
rebound=d symptoms
Enzyme
interference
Paroxetine inhibits its own metabolism via CYP2D6. So withdrawal
leads to loss of inhibition Æ excessive paroxetine breakdown Æ sudden
steep drop in levels Æ withdrawal symptoms
Active metabolites
Fluoxetine has active metabolite norfluoxetine with long half-life –
hence it produces fewer withdrawal symptoms
Rate of withdrawal
Slow, gradual tapering is the best. 10% dose reduction every 2 weeks is
advocated for benzodiazepines.
Co-prescribed drug
effects
Prescribing an enzyme inducer can reduce the effects of a drug acutely if
its metabolism depends on the induced enzyme; Similarly prescribing
an antagonist can precipitate withdrawal symptoms. This is the
rationale for leaving at least 72 hours before prescribing naltrexone for
an opioid detoxified patient.
Receptor profile
Full agonists on withdrawal produce more discontinuation reactions
than partial agonists e.g. clonazepam produces lesser benzodiazepine
withdrawal symptoms.
Sustained-release preparations influence the absorption kinetics– not elimination kinetics, hence
upon withdrawal, the drop in plasma levels occur at same rate in both XL and plain preparations;
e.g. venlafaxine XL has similar discontinuation reaction as venlafaxine normal release. But depot
preparations have less withdrawal propensity that corresponding oral drugs.

02 - 2. Mechanism of adverse effects
2. Mechanism of adverse effects
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2. Mechanism of adverse effects
Side effect
Receptor
Agitation
α  2 blockade, 5HT2A/2C stimulation, DRI
Akathisia
D2 blockade, 5HT2A stimulation (hence some data on
mirtazapine, 5HT2A antagonist, reducing akathisia)
Delirium
Anticholinergic effect (antimuscarinic)
EPSE
D2 blockade reduces with 5HT2A antagonism
Hyperthermia
Antimuscarinic action, in serotonin syndrome, may be mediated
via 5HT2A/2C
Insomnia
α 1 stimulation, 5HT2Astimulation (hence SSRIs cause insomnia)
Amnesia (memory defects)
Anticholinergic effects, GABAA stimulation
Hyperprolactinaemia
D2 blockade, 5HT1A stimulation
Disrupted slow wave sleep SWS is maintained by 5HT2A inhibition; 5HT2A stimulation
disrupts sleep architecture
Sweating
Cholinergic effect and increases with noradrenaline reuptake
inhibition
Postural hypotension
α  1  antagonism
Appetite loss
5HT2A stimulation (antihistaminics can increase appetite)
GI discomfort, nausea,
vomiting
5HT3 stimulation
Weight gain
5HT2C antagonism and antihistaminic effects
Anticholinergic effects
Blurred vision, exacerbation of narrow-angle glaucoma,
delirium, and photophobia due to mydriasis, dry secretions,
constipation, tachycardia, decreased sweating, urinary retention
and hyperthermia.
Anorgasmia
α  1  antagonism,  5HT2A/2C  stimulation  (delayed  ejaculation  in  
SSRIs).  Retrograde  ejaculation  due  to  α  1  block,  anticholinergic  
and antihistaminic effects.
Tardive dyskinesia
Supersensitivity of dopamine receptors, which develops
because of prolonged therapy with dopamine-blocking drugs
Impotence
α  2  blockade,  5HT2A/2C  stimulation.  5HT2A/2c  stimulation  can  
also reduce libido.
Priapism
α  1  blockade
Obsessions
5HT1D stimulation can induce obsessions. 5HT1A and 2A
stimulation reduce OCD.
Pathological gambling
Habituation of dopamine receptors on repeated use of
dopamine agonists (e.g. levodopa) leading to dopamine
dysregulation syndrome (DDS)
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Weight gain: No single mechanism can explain the complex metabolic phenomenon of weight
gain. Antihistaminic effects, 5HT2A/2C antagonism, insulin resistance (valproate and olanzapine)
are noted. Genetic factors seem to involve 5-HT2C receptor. Drugs with a strong 5-HT2C affinity
will have a greater impact on body weight of patients with a specific variant of polymorphism of
the 5-HT2C receptor promoter regions. Low-potency antipsychotics (chlorpromazine and
thioridazine) produce more weight gain and sedation than high-potency agents (haloperidol and
fluphenazine).

03 - 3. Antipsychotics adverse effects
3. Antipsychotics - adverse effects

04 - Extrapyramidal effects
Extrapyramidal effects
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3. Antipsychotics - adverse effects
Extrapyramidal effects
Acute extrapyramidal syndromes such as acute dystonia, akathisia and parkinsonism are noted
with high potency drugs more than low-potency drugs. Tardive dyskinesia and dystonia,
perioral tremor (rabbit syndrome) are chronic late side effects.
PET studies have indicated that 60%–80% occupation of D2 receptors is associated with
antipsychotic efficacy. Higher occupancy levels are associated with an increased risk of acute
extrapyramidal symptoms as well as hyperprolactinemia from the blocking of D2 receptors on
anterior pituitary mammotrophic cells that normally are tonically inhibited by dopamine
produced in the hypothalamic arcuate nucleus.
Antipsychotic drugs which have the propensity to induce Parkinsonism (trifluoperazine,
chlorpromazine, raclopride, haloperidol, fluphenazine, risperidone) bind more tightly than the
endogenous ligand dopamine to D2, while the drugs with low Parkinsonism-inducing
propensity (quetiapine, clozapine etc) bind more loosely than dopamine to D2 receptors.
Compared to the tightly bound antipsychotic drugs, the loosely bound ones are weaker in
potency and thus require higher doses to be clinically effective, but can be titrated faster. These
loosely-bound drugs may also dissociate from the D2 receptor more rapidly and could lead to
clinical relapse somewhat earlier than the traditional tightly bound antipsychotic drugs (though
ths does not seem to be the case for clozapine).
Drug-induced parkinsonism is seen in 15-20% of patients treated with antipsychotics, seen
within 90 days of treatment (5 to 90) and is characterized by muscle stiffness, cogwheel rigidity,
shuffling gait, stooped posture, and drooling. The pill-rolling tremor of idiopathic Parkinsonism
is not seen in drug-induced EPSEs - but a regular coarse tremor is seen. Elderly and female are
under higher risk. Low potency drugs and those with higher anticholinergic effects cause less
EPSEs. It is thought that higher than 80% receptor occupancy of brain D2 by antipsychotics can
cause EPSEs. Atypical drugs cause low EPSEs probably due to anticholinergic effects, HT2A
antagonism or less avidity of binding i.e. hit and run profile especially for clozapine and
quetiapine. Anticholinergics can be used for short period of up to 6 weeks to treat the
parkinsonian symptoms. As tolerance can develop for EPSE, the anticholinergics should be
withdrawn after 4 to 6 weeks; also, longer chronic anticholinergic prescription increases the risk
of TD.
The rabbit syndrome is a tremor affecting the lips and perioral muscles and occurs late in the
course of treatment.
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Dystonias are brief or prolonged contractions of specific groups of muscles resulting in
symptoms such as oculogyric crises, tongue protrusion, trismus, torticollis, blepharospasm.
Rarely pharyngeal dystonia can occur resulting in dysarthria, dysphagia, and even respiratory
choking. Dystonias occur early in treatment course and can reduce compliance. It is often seen in
younger men receiving a high dose of high-potency medications. It is more common with IM
administration. Dopaminergic hyperactivity in the basal ganglia occurring when plasma levels
fluctuate may be the mechanism behind dystonias. Dystonias show spontaneous fluctuations,
response to reassurance and to anticholinergic drugs.
Akathisia includes both subjective and objective - feelings and signs of restlessness. (Possibly due
to higher D2 occupancy in striatum). Patients may exhibit inability to relax, jitteriness, pacing,
rocking with alternation of sitting and standing. Akathisia
can be caused by not only neuroleptics but also
antidepressants and sympathomimetics. Dose reduction,
changing the drug or adding beta blocker/anticholinergic
drugs or benzodiazepines or cyproheptadine are
recommended. Akathisia may be associated with an increase
in absconsion, suicides and violence if left undiagnosed and
untreated in some cases.
Tardive dyskinesia is a late side effect occurring in nearly 25%
patients usually only after (at least 6 months) 1 – 2 years of
treatment. It presents as abnormal, involuntary, irregular
choreoathetotic movements of the muscles of the head, limbs,
and trunk. Perioral movements are the most common. In
some serious cases, patients may have breathing and
swallowing muscles involved leading to aerophagia and
grunting. TD is exacerbated by stress but is absent during sleep. The absence of insight about the
movement disorder is striking in patients.
Most cases remit spontaneously. Elderly have a poor spontaneous resolution. Tardive dyskinesia
is less likely to remit in elderly patients than in young patients, however. Clozapine can reduce
the risk and also treat TD. Dose reduction, withdrawal of the drug, switch to newer atypicals or
adding clonazepam can be considered.
Neuroleptic Malignant Syndrome
Can occur at any time during treatment with neuroleptics
RISK FACTORS FOR TARDIVE
DYSKINESIA
Female gender
Elderly
Diabetics
Previous brain damage
Affective illness rather than pure
psychotic disorder
Children
Learning disabled
Afro-Caribbean race
Long term co-prescription of
anticholinergics
Frequent drug holidays – will lead
to high dose prescription with each
relapse

05 - Agranulocytosis
Agranulocytosis
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Consists of the tetrad of extreme hyperthermia, severe muscular rigidity and confusion, and
autonomic fluctuations (BP and pulse rate). Patients may be akinetic and mute.
Increased WBC count, creatinine phosphokinase, liver enzymes, plasma myoglobin, and
myoglobinuria are noted.
Subacute onset in 24 to 72 hours, and if untreated lasts 10 to 14 days.
More common in young men, after agitation and when using high potency drugs especially in
rapid tranquillisation situations. Dopaminergic drugs on withdrawal can produce NMS.
The mechanism may be related to dopamine blockade or hypothalamic sympathetic
dysregulation.
The mortality rate is around 20-30% if untreated and higher if depot is used.
Symptomatic management of vital signs instability, fluid replacement and prevention of renal
failure secondary to myoglobinuria and prevention of aspiration pneumonia are main
treatment methods after immediate stopping of offending psychotropic. Dantrolene,
Bromocriptine or amantadine can be used. Low potency or atypical must be used following
recovery for an antipsychotic prescription.
Agranulocytosis
Occurs in around 1 per 100 patients on clozapine. This is 15 to 30 times higher than the risk
associated with phenothiazines and olanzapine. The maximum risk is between 4 and 18 weeks,
and after a year the risk is same as with phenothiazines.
Weekly monitoring of the white cell count is required for 26 weeks in most countries, with the
frequency decreasing to biweekly or monthly thereafter.
In the UK, yellow, green and red signals are used in WBC
monitoring. When a result is red, clozapine must be
stopped and never tried again. If yellow, then monitoring
frequency must be increased until a green signal is
obtained again.
Benign neutropenia is common especially in south Asian and Afro-Caribbean race. Lithium can
increase WBC count albeit transiently. Some anecdotal evidence supports using lithium in
patients with benign ethnic neutropenia in preparation for clozapine use. But lithium and
clozapine together can increase the risk of seizures and confusion.
Clozapine, when combined with carbamazepine, phenytoin, propylthiouracil, sulfonamides, and
captopril, can increase the risk of agranulocytosis further.
Paroxetine may precipitate clozapine-associated neutropenia.
Many side effects of clozapine such as
salivation, sedation, and weight gain,
fatigue and lowering of seizure threshold
are dose related. But agranulocytosis
and myocarditis can occur at any dose.

06 - Sexual dysfunction
Sexual dysfunction:

07 - Other side effects
Other side effects
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Transient leucopenia can occur with typical neuroleptics. But agranulocytosis is the rare effect.
Sexual dysfunction:
Increased dopaminergic transmission can enhance sexual arousal and penile erection.
Hyperprolactinaemia can result in loss of sexual arousal and erectile dysfunction in men;
amenorrhoea, reduced sexual desire and hirsutism in women. Antipsychotics reduce sexual
performance both directly by reducing dopaminergic transmission and indirectly through
inducing hyperprolactinaemia. 43% of those taking antipsychotics report sexual dysfunction at
some point, not all of this attributable to the drug.
Neuroleptic agents commonly cause ejaculatory problems. Total inhibition of ejaculation (dryejaculation),  reduced  ejaculatory  volume  and  ‘retrograde’  ejaculation  are  the  various  effects  
associated with conventional neuroleptics and also clozapine, risperidone and olanzapine.
Drug-induced priapism is  related  to  simultaneous  α1-adrenergic blockade and anticholinergic
activity. The most commonly reported associations are with antipsychotic drugs (20% of all
reported priapisms) followed by trazodone. Antipsychotics implicated in this problem include
risperidone, chlorpromazine clozapine, olanzapine and thioridazine. The risk is doseindependent and can occur at any time during the course of treatment (duration-independent).
Priapism is a urological emergency and can lead to permanent impotence if untreated.
Dopaminergic agonist bromocriptine is used to treat sexual dysfunction in men that is associated
with hyperprolactinaemia.
Other side effects
Seizure threshold is lowered especially by low potency antipsychotics. Molindone may be
the least epileptogenic. This is a dose-dependent effect.
Chlorpromazine is the most sedating typical antipsychotic – mediated by H1
antihistaminic action – tolerance usually develops for this effect.
Low potency agents can also cause anticholinergic syndrome (see TCAs).
Neuroleptics can decrease cardiac contractility, increase circulating levels of
catecholamines, and prolong atrial and ventricular conduction time. Low-potency drugs
are more cardiotoxic than high-potency drugs. ECG shows QT and PR prolongation,
blunting of the T waves, and ST depression. Thioridazine and droperidol, in particular,
can cause torsade de pointes.
Antipsychotic related sudden death may be due to cardiac arrhythmias or even seizures
asphyxiation or malignant hyperthermia. Drugs causing QT prolongation are associated
with more sudden deaths (e.g. thioridazine). Postural hypotension is most common with
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low-potency drugs, and tolerance develops soon. Patients should avoid all caffeine and
alcohol, drink plenty of fluid and liberal salt in food.
Low-potency drugs can cause weight gain but not as much as is atypical drugs.
Nearly 50% of men taking antipsychotics report ejaculatory and erectile disturbances.
Thioridazine is particularly associated with decreased libido and retrograde ejaculation in
men.
Allergic dermatitis and photosensitivity can occur with low-potency agents. Long-term
chlorpromazine use can cause blue-gray discoloration of skin areas exposed to sunlight.
This is reversible. Irreversible retinal pigmentation is associated with the use of high dose
thioridazine (above 1000 mg a day). An early symptom of the side effect can sometimes be
nocturnal confusion associatd to difficulty with night vision. This pigmentation is
irreversible and can progress even after stopping thioridazine. Chlorpromazine related
pigmentation of the anterior lens and the posterior cornea is seen as whitish brown stellate
granular deposits noted in slit lamp – this is benign and not vision impairing. This can
resolve gradually unlike thioridazine related retinal damage.
Chlorpromazine is associated with cases of obstructive or cholestatic jaundice especially
in the first month of treatment associated with rash and eosinophilia. Immediate
discontinuation and avoidance of rechallenge are advised.
Haloperidol isone of the safest typical antipsychotics in overdose. After an overdose, the
electroencephalogram (EEG) shows diffuse slowing and low voltage.
QT prolongation: Prolongation of the QT interval is mediated by blockade of the rapid
component of the delayed rectifier potassium current (IKr) responsible for repolarisation
of cardiac Purkinje cells and myocardial cells. Many drugs, including certain
antipsychotics and antidepressants, bind to this potassium channel and thereby decrease
the outward movement of potassium. Some antipsychotics – especially droperidol,
pimozide, sertindole and thioridazine – have a greater capacity than others to cause IKr
blockade.
InAdvertent IntraVascular injection event (IAIV) or postinjection delirium sedation
syndrome (PDSS) has been described after olanzapine pamoate (long-acting depot)
injections. Within 20 min to 3 hours of injection, patients present with sedation, confusion,
dizziness, altered speech/dysarthria, and somnolence, symptoms that are consistent with
those reported in the case of oral olanzapine overdose. Rarely deep coma may ensue.
Medical hospitalization and supportive medical care are usually sufficient to ensure full
recovery (usually within 3–72 hours). This effect is linked to accidental punctures of a
vessel or injections into a rich capillary bed during administration, leading to quick
dissolution and release of free olanzapine. Eli Lilly has recommended a postinjection

08 - Metabolic syndrome
Metabolic syndrome
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observation period of at least 1 - 3 hours in a healthcare facility and to avoid driving or
operating heavy machinery in the 24 hours after injection.
Metabolic syndrome
Metabolic syndrome is a cluster of disorders comprising obesity (central and abdominal),
dyslipidaemias, glucose intolerance, insulin resistance (or hyperinsulinaemia) and hypertension.
It is highly predictive of type 2 diabetes mellitus and cardiovascular disease.
Diabetes Mellitus is twice as prevalent among schizophrenia cohorts than in the general
population
Unaffected first-degree relatives of patients with schizophrenia share a propensity for type
2 diabetes mellitus (19-30%); this suggests a genetic association between these two
disorders
Schizophrenia patients have 3 times greater intra-abdominal fat (IAF) than the control
group, increasing the risk for metabolic syndrome.
In the pre-antipsychotic era over 15% of drug-naïve individuals with first-episode
schizophrenia had impaired fasting glucose levels, hyperinsulinaemia and high levels of
cortisol.
Both typicals and atypicals increase the risk of metabolic syndrome in schizophrenia
manifold. But antipsychotics cannot explain all the metabolic dysfunctions noted in
schizophrenia.
The frequency of metabolic syndrome was 2-4 times higher in a group of people with
schizophrenia treated with either typical or atypical antipsychotics.
MOST
Olanzapine /
clozapine
quetiapine
risperidone
ziprasidone
aripiprazole/
lurasidone
LEAST
World Health Organization criteria for metabolic syndrome
World Health Organization criteria for metabolic syndrome
•Insulin resistance and/or impaired fasting glucose and/or impaired glucose tolerance
AND two or more of the following:
•Waist - hip ratio >0.90 (men), >0.85 (women) OR body mass index 30 kg/m2;
•Triglyceride level 1.7 mmol/l OR high-density lipoprotein <0.9 mml/l (men), <1.0 mmol/l
(women);
•Blood pressure 140/90 mmHg (or treated hypertension);
•Microalbuminuria. (This is not presented in some revised criteria for metabolic
syndrome)
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In Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE) Schizophrenia Trial
baseline data (n = 689), the metabolic syndrome was prevalent in 51.6% of female patients
and 36.0% of male patients.
Females with schizophrenia have a higher risk than males with schizophrenia when
compared with a reference population.
Mean weight increases during the first year of therapy
o 12 to 14lb for clozapine (5 to 6 kg)
o 15 to 26lb for olanzapine (7 to 12kg)
o 6 to 12lb for quetiapine (2.5 to 5kg)
o Up to 5lb for risperidone (2 to 2.5kg)
o Less than 2lb for Ziprasidone and aripiprazole
For patients with schizophrenia, the best-studied options for weight control include diet and
exercise. But controlled behavioral programs for weight reduction in schizophrenia have high
dropout rates and are not always accessible. Switch to relatively weight neutral drugs can be
considered in resistant cases.
CATIE summary
CATIE stands for Clinical Antipsychotic Trials of Intervention Effectiveness.
The study design was double-blind pragmatic RCT.
1493 patients with chronic schizophrenia (mean duration of illness = 14 years), 57 sites, 2001 to 2004
Olanzapine, quetiapine, Risperidone, ziprasidone (added later in the trial), perphenazine
Primary  outcome  is  a  ‘real-world’  measure  – discontinuation for any reason, either patient-initiated or
physician initiated
76% power to detect 12% difference in primary outcome
Irrespective of the prescribed drug – 74% discontinued treatment in 18 months (surprisingly high despite
naturalistic design). The median time to stop was 4.6 months.
Olanzapine had lowest discontinuation rate (still 64%) – but highest side effect burden. 64% discontinued
olanzapine; 75%, perphenazine; 82%, quetiapine; 74%, risperidone; and 79%, ziprasidone.
Olanzapine caused most weight gain while quetiapine caused most anticholinergic symptoms; perphenazine
had highest EPSE related discontinuation.
Those who did not respond after 18 months (those who discontinued for the ineffectiveness of therapy) were
re-randomised in phase 2 trial (n=99), and Clozapine was compared to other atypical agents (efficacy
pathway). Clozapine had lowest discontinuation rate – median at 10 months. This time-to-discontinuation
was nearly 3 times longer than time-to-discontinuation with the other SGAs. Quetiapine had comparatively
less EPSEs.
As a part of the phase 2 CATIE study (tolerance pathway) those who terminated phase 1  for  ‘‘intolerable  side  
effects’’  (444  volunteers)  were  tested  with  olanzapine,  risperidone,  quetiapine,  or  ziprasidone. Of these
treatments, olanzapine and risperidone had equivalent effectiveness, and both were better than quetiapine or
ziprasidone by significant but modest margins.
CATIE Controversies
o
Quite complicated study design and many outcomes were analysed from the dataset.
o
Decisions to add ziprasidone to the protocol was made after recruitment began
o
Perphenazine was used only in one randomized phase (phase 1) of the study generating controversy.
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o
The decision to use double-blinded treatments decreased the resemblance of the study procedures to
those of routine clinical care
The mean doses used remain controversial though it is claimed that the study was designed
to be pragmatic and not purely experimental.
CUtLASS summary:
CUtLASS stands for Cost Utility of the Latest Antipsychotic Drugs in Schizophrenia Study
It is an unblinded randomised controlled trial comparing first-generation v. second-generation antipsychotics
The primary outcome was the quality of life at 1 year and symptom measures were the main secondary
outcome.
1, 227 people with schizophrenia who were being assessed by their clinical team for medication review
because of poor response or adverse effects were randomised.
The second-generation drugs were amisulpride, olanzapine, quetiapine or risperidone.
The rate of follow-up interview was 81% at 1 year.
The results showed no advantage of second-generation drugs in terms of quality of life or symptom burden
over 1 year with those on first-generation antipsychotic doing relatively better.
Participants reported no clear preference for either class of drug.
The second phase - CUtLASS 2 trial was of similar design and compared clozapine with other secondgeneration drugs in 136 patients who had not responded well to two or more previous drugs. Results
showed that there was a significant advantage for clozapine in symptom improvements over 1 year;
moreover, patients significantly preferred it.

09 - 4. Antidepressants adverse effects
4. Antidepressants - adverse effects

10 - Tricyclic agents
Tricyclic agents
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4. Antidepressants - adverse effects
Tricyclic agents
Side effects of TCAs are related to anticholinergic, antihistaminic and antiadrenergic
properties. Clomipramine is a more selective inhibitor of serotonergic reuptake selective;
desipramine is the most noradrenergic selective of TCAs. Amoxapine, nortriptyline,
desipramine, and maprotiline have the least anticholinergic activity; doxepin has the most
antihistaminic activity.
The TCAs are less likely to cause sexual dysfunction and insomnia than the SSRIs.
Amitriptyline is associated with weight gain (antihistaminic effect – weight gain can also
occur secondary to 5HTc antagonism in other antidepressants).
TCAs may cause QT prolongation. Even at therapeutic doses, the TCAs cause tachycardia,
flattened T waves, prolonged QT intervals, and depressed ST segment.
TCAs are lethal in overdose, causing cardiac arrhythmias and anticholinergic delirium.
This may occur 3-4 days after overdose due to the long half-life. No specific antidote
available; needs lavage and QRS monitoring.
Anticholinergic delirium is characterized by symptoms often described  as    ‘Mad as a hatter,
(confusion, disorientation, visual hallucinations), Hot as a hare (hyperpyrexia), Blind as a bat (loss
of visual accommodation), Red as a beet (peripheral vasodilatation) and Dry as a bone (drying of
mucous membranes)’.
Amoxapine can cause hyperprolactinemia as it has dopamine antagonistic effects.
SIADH and hyponatremia can occur with TCAs.
Fine rapid tremor and dysarthria are sometimes reported with TCAs.
Tricyclic agents such as amitriptyline and imipramine and the nontricyclic agents such as
mianserin hydrochloride have been documented to precipitate an attack of angle closure
glaucoma.
TCA discontinuation: Can cause cholinergic rebound – best to reduce 25 to 50mg per 2-3
days. Discontinuation reaction may occur as early as 48 hours or as late as 2 weeks after
discontinuation. Propantheline or reinstitution of withdrawn TCA can reduce cholinergic
rebound symptoms.
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NMS vs. serotonin syndrome
NMS
Serotonin syndrome
Dopamine antagonism and suspected
hypothalamic mediated sympathetic
overdrive.
Excess serotonin availability
Onset subacute – days to weeks
Sudden minutes to hours onset
Resolves in 2 weeks - depending on t1/2
of offending drug
Resolves as soon as excess serotonin is
reduced – in 24 hours generally
No myoclonus
Myoclonus prominent
Hypomania, not a feature
Hypomania may be seen
Reflexes normal or absent
Hyperreflexia seen
Rhabdomyolysis, resultant renal failure
and acidosis occur commonly
Muscle breakdown not common
•Serotonin syndrome is a result of excessive serotonergic transmission in brain. Although no single
mechanism appears to be responsible for all of the noted effects, most CNS symptoms are possibly
mediated via 5HT 2A receptor stimulation.
Mechanism of Serotonin Syndrome
Mechanism of Serotonin Syndrome
•It is characterized by diarrhea, myoclonus, diaphoresis, hyperactive reflexes, ataxia, hypomanic or labile
mood, tremors and disorientation.
• It may mimic NMS or anticholinergic syndrome in those receiving psychotropics.
Features of serotonin syndrome
Features of serotonin syndrome
•Any serotonergic agent on overdose – including SSRI and TCA antidepressants, fenfluramine, LSD,
ecstasy, anti-migraine (e.g. sumatriptan) drugs.
•High risk with combinations of SSRI and MAOI or RIMA or SSRI themselves, or TCAs especially
serotonergic, or SNRI, lithium or l-tryptophan. TCA and MAOI combinations. Tramadol, pethidine,
meperidine can also cause serotonin syndrome on combination with the above agents.
•Oxazolidinone antibacterial linezolid (which is a reversible non-selective MAOI), tetrabenazine (acts via
dopamine and serotonin depletion at nerve endings), entacapone (COMT inhibitor) and selegiline are also
implicated.
Drugs with high risk of serotonin syndrome:
Drugs with high risk of serotonin syndrome:
•Withdraw the offending agent
•Supportive care: correction of vital signs
•Benzodiazepines
•5HT2A antagonists: cyproheptadine, atypical antipsychotics, chlorpromazine (? mirtazapine –
controversial reports)
•In severe cases neuromuscular paralysis and intubation may be required
Treatment of Serotonin syndrome:
Treatment of Serotonin syndrome:

11 - SSRI antidepressants
SSRI antidepressants
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CPK elevation common; WBC also
elevated
These laboratory abnormalities are less
frequent in serotonin syndrome
SSRI antidepressants
Nausea, vomiting, anorexia, and diarrhea are common side effects of SSRIs – these are
somewhat dose-dependent and can be lessened by dose reduction or a slower titration.
SSRIs (similar to TCAs, but less frequently) cause weight gain in up to 30% of patients
especially in long-term maintenance phase.
During initial treatment insomnia and anorexia are often present. Desensitization and
down-regulation of receptors may explain the reversal of the initial SSRI appetitesuppressing effects, which can ultimately lead to weight gain late during therapy.
Sexual difficulties such as reduced libido, impotence, ejaculatory dysfunction, and
anorgasmia are reported with SSRIs. The incidence of sexual dysfunction is nearly every 1
in 3 patients treated.
Akathisia like effects, EPSEs and galactorrhea are rarely reported with SSRIs.
Also, fluoxetine is associated with a change in the duration of menstrual period –
significance of this is unknown.
SSRIs can cause functional impairment of platelet aggregation (thrombasthenia), but not a
reduction in platelet number. This can cause easy bruising or prolonged bleeding in those
with gastric ulcers or bleeding diathesis.
SIADH is also reported; this is often troublesome in alcoholics and the elderly causing
hyponatremia, hyperkalemia, hypo-osmolality in serum and increased osmolality of urine.
Stopping the offending drug, using demeclocycline and fluid restriction can help.
Severe sweating especially nocturnally is seen in some patients; Terazosin is effective in
counteracting sweating.
Nocturnal myoclonus is reported with SSRIs. The repetitive leg movements occur every 20
to 60 seconds, with extensions of the large toe and flexion of the ankle, the knee, and the
hips. Benzodiazepines and levodopa may be tried.
In restless leg syndrome, patients complain of creeping deep sensations that cause an
irresistible urge to move the legs – disturbing sleep. It is associated with SSRIs and
treatment is possible using ropinirole or benzodiazepines and levodopa.
Duloxetine, venlafaxine, citalopram, fluoxetine and paroxetine can induce acute angleclosure glaucoma. The pathophysiological mechanism of SSRI –precipitated glaucoma
remains unclear; anticholinergic effects or increased level of serotonin, which cause partial
pupillary dilation have been implicated.
SSRI discontinuation syndrome: The abrupt withdrawal of SSRI especially paroxetine
(additional cholinergic rebound) or fluvoxamine (shorter half-life), is associated with a
discontinuation syndrome. It usually requires at least 4-6 weeks of treatment before
© SPMM Course
discontinuation and resolves spontaneously in 3 weeks. Those who have significant SSRI
intolerance during treatment onset will have more discontinuation reactions. Fluoxetine is
the SSRI least likely to cause withdrawal syndrome as its metabolite has a long half-life
(more than 1 week), producing a slow self-tapering effect in plasma. Fluoxetine in some
cases can be used to even treat discontinuation syndrome or to prevent it when stopping
another SSRI agent. But a delayed withdrawal syndrome has been reported with
fluoxetine in some cases.
SSRI discontinuation syndrome
Criterion A
Discontinuation or reduction of dose of SSRI after at least 1 month use
Criterion B
2 or more of the following seen within 1-7days of criterion A causing significant
functional impairment and not due to a general medical condition:
x Dizziness, lightheadedness, shock-like sensations (paresthesias), diarrhea,
fatigue, gait instability, headache, insomnia, nausea, tremors, visual
disturbances
Suicide risk and SSRIs: A link between antidepressant use and suicidal ideation among those
up to age 24 in short-term (4 to 16 weeks), placebo-controlled trials of nine antidepressant
drugs has been reported. The average risk of suicidal thinking or behavior during the first few
months of treatment in those receiving antidepressants was 4 percent while placebo produces
a risk of 2 percent. Ecological studies indicate that since the introduction of large scale SSRI
prescription for every 10% rise in prescription 3% decline in suicide rates has happened in
certain countries. It is also noted that patients were significantly more likely to
attempt/commit suicide in the month before they began drug therapy than in the 6 months
after starting it. But the issue still remains controversial, and MHRA has advised against
certain SSRI prescriptions in children and adolescents.
SSRIs increase the risk of upper GI bleeding especially in the elderly and in those using
NSAIDs. SSRIs inhibit the uptake of serotonin into platelets; serotonin is crucial for the
haemostatic response of promoting platelet aggregation. Further, SSRIs also increase gastric
acid secretion thus elevating the risk of gastric erosion, ulcer and bleeding. Alcohol intake and
being positive for H.pylori will also increase the risk of GI bleeding when prescribing SSRIs.
Antidepressants with low inhibition of serotonin reuptake (e.g. nortriptyline, doxepin,
trazodone) are safer in this regard when compared to those with high inhibition of serotonin
reuptake (e.g. clomipramine, paroxetine, sertraline, fluoxetine).
Increased serotonergic neurotransmission can adversely affect sexual performance; this
explains SSRI-induced sexual dysfunction. Some antidepressants (bupropion, mirtazapine,
moclobemide, nefazodone and reboxetine) may be associated with a relatively lower
incidence of sexual dysfunction. 5-HT2 antagonists, (e.g. cyproheptadine, mirtazapine), 5-HT1a

12 - Other antidepressants
Other antidepressants
© SPMM Course
agonists, (e.g. buspirone) and bupropion (being a dopamine reuptake inhibitor) can reverse
sexual dysfunction related to SSRI use.
A nitric oxide-dependent second messenger (cGMP) mediates penile vasodilatation. cGMP is
eventually broken down by phosphodiesterase type 5 enzyme. Sildenafil is an inhibitor of
phosphodiesterase type 5, an action that enhances penile erection in patients with erectile
dysfunction. Sildenafil (Viagra) has been tried successfully in the treatment of SSRI-induced
erectile dysfunction. The side effects of sildenafil include headaches (most common),
dizziness, blurred vision and a blue tinge to vision. Very rarely, persistent painful erection
(priapism) can occur. Sildenafil must be avoided by patients with arrhythmias, unstable
angina / uncontrolled hypertension.
Other antidepressants
Venlafaxine: Sweating is more common than in SSRIs and is treated by terazosin. Significant
numbers of patients receiving doses above 300mg/day experience an increase in diastolic
blood pressure. This risk is not restricted to those with preexisting hypertension. Mydriasis
and exacerbation of angle closure glaucoma are reported with venlafaxine; significant
discontinuation reactions are reported due to the shorter half-life of venlafaxine – tapering
gradually over 2-4 weeks is recommended. Duloxetine has side effects similar to venlafaxine,
but fewer propensities to affect blood pressure.
Trazodone is associated with priapism that can be serious if unattended. The first step in the
emergency management of priapism is the intracavernosal injection of an alpha1 agonist such
as metaraminol or epinephrine. The risk of priapism is greatest during the early phase of
treatment. Nefazodone inhibits CYP3A4 and can cause serious hepatic damage and hence not
used as often now. Though anticholinergic effects are predominantly absent, alpha1
antiadrenergic effects can produce pseudo-anticholinergic symptoms. Afterimage formation
similar to the LSD related tracking phenomenon is reported in up to 12% patients on
nefazodone. Both trazodone and nefazodone have a favourable profile for elderly and those
with cardiac illness.
Bupropion has a very different side-effect profile than the conventional antidepressants. It
has no anticholinergic effects, does not cause sedation or weight gain and cause almost
negligible sexual side effects compared to other classes of antidepressants. It does not cause
orthostatic hypotension or cardiac side effects. It can exacerbate ADHD, eating disorders and
tics in those with ADHD. It can enhance sexual activity unlike SSRIs; it increases the risk of
seizures in a dose-dependent fashion. Headache, insomnia, dry mouth, tremor, and nausea
are the most common side effects of bupropion. Severe anxiety or panic can be exacerbated by
bupropion. Due to its effects on dopaminergic neurotransmission bupropion can cause
© SPMM Course
psychotic symptoms as well as delirium. Bupropion can cause word-finding difficulties in
some patients.
Agranulocytosis is reported with mirtazapine use. Hence, signs of infection need to be
promptly followed.
Buspirone can increase concentrations of haloperidol. Buspirone + MAOI can cause serotonin
syndrome; 2-week washout period is recommended. CYP3A4 inhibitors such as
erythromycin, itraconazole, nefazodone and grapefruit juice, increase buspirone plasma
concentrations. Buspirone does not cause weight gain, sexual dysfunction, discontinuation
symptoms, or significant sleep disturbance. It does not produce sedation.
Mianserin and mirtazapine produce drowsiness during the first weeks of treatment but has a
low propensity to produce orthostatic hypotension or cardiac effects. Increased weight gain
and appetite are also noted while sexual side effects are minimal. 5-HT3 blockade is
associated with a reduction in nausea and vomiting; hence to treat depression associated with
cancer chemotherapy, mirtazapine is a preferred option.
Reboxetine is a noradrenaline reuptake inhibitor (NARI) with negligible serotonergic effects.
It has a safe cardiovascular profile and can be used in the elderly. Atomoxetine belongs to the
same group but not used as an antidepressant; it is used in ADHD. Reboxetine has a specific
side-effect profile linked to the noradrenergic system. Urinary hesitancy has been observed in
around 10% of male patients taking part in the clinical trials. Relief from this side effect could
be achieved by using tamsulosin, a peripheral alpha1-receptor blocker or doxazosin with a
similar mechanism of action as tamsulosin.
MAOIs such as phenelzine can induce orthostatic hypotension, pedal edema and insomnia.
Apart from cheese reaction, MAOIs can also cause serotonin syndrome in combination with
serotonergic agents. Tranylcypromine, and phenelzine to some extent can have stimulating
effects leading to insomnia – hence the last dose is best given before 6 PM. Weight gain and
sexual dysfunction are also reported.
Cheese reaction:
o MAOIs and tyramine (and other monoamine) rich foods interact to cause cheese reaction
or tyramine reaction.
o Tyramine has both direct and indirect (via vesicular release) sympathomimetic actions
that develop 20 min to 1 h following ingestion of food.
o It is characterized by nausea, apprehension, occasional chills, sweating, restlessness and
hypotension with occipital headache, palpitations, and vomiting.
o Sympathetic overdrive manifests as piloerection dilated pupils and fever. If severe
cerebral hemorrhage and death can occur.
© SPMM Course
o In terms of the frequency and severity of the hypertensive crisis, the reversible MAOIs are
safer.
o Food materials to be avoided include any mature cheese such as Stilton, blue cheese, old
cheddar and mozzarella. Fish, cured meats, sausage must be avoided together with
mature poultry, wild game etc., liqueurs and concentrated yeast extract.
o An MAOI-induced hypertensive crisis can be treated with alpha-adrenergic antagonists
such as phentolamine or even chlorpromazine, which is immediately available in most
psychiatric wards. This can lower blood pressure in few minutes.

13 - 5. Antimanic agents adverse effects
5. Antimanic agents - adverse effects

14 - Renal effects
Renal effects

15 - Cardiac effects
Cardiac effects

16 - Endocrine effects
Endocrine effects
© SPMM Course
5. Antimanic agents - adverse effects
Renal effects
Certain side effects including polyuria seems to be associated with peak lithium levels; once daily
instead of twice daily dosing can reduce these problems. Nearly 1/3rd of those treated will have
this side effect, but tolerance develops in due course; functional antagonism of ADH by lithium
ion is considered to be the underlying mechanism. Use of K+ sparing diuretics such as amiloride
or spironolactone can control polyuria.
Renal damage may occur in severe, prolonged toxicity – but cumulative lithium use rather than
toxicity leads more commonly to renal failure in lithium users. Chronic exposure longer than 10
years induces interstitial fibrosis resulting in chronic renal damage.
Lithium has a narrow therapeutic index. Lithium toxicity occurs in conditions of overdose or
dehydration. Non-specific gastrointestinal symptoms usually precede the more serious
neurological symptoms and renal shutdown. Immediate cessation of lithium followed by urgent
medical attention is required as some patients may require a hemodialysis if levels exceed
4mEq/L.
Topiramate is a weak inhibitor of carbonic anhydrase and can promote the development of renal
stones.
SIADH may be seen with valproate use though more common with carbamazepine; it is
dependent on the dose prescribed.
Oxcarbazepine is a 10-keto derivative of CBZ with an identical profile but less enzyme induction
and fewer drug–drug interactions. It produces less rash and neurotoxicity but more
hyponatremia than CBZ.
Cardiac effects
ECG effects of therapeutic lithium dose are similar to hypokalemia – with flat T waves, or
inverted T. Lithium can depress sinus node activity and so is contraindicated in sick sinus
syndrome.
Endocrine effects
Lithium can cause a variety of thyroid problems – the most common being a benign hypothyroid
state. 5% patients may develop goiter, and overt hyperthyroidism is also reported in some cases.
Thyroid deficiency is common in those with high risk for preexisting antithyroid antibodies
(especially middle-aged women). The risk is 3-4:1 in women and is high in first 2 years of
treatment. Rapid cycling patients are at higher risk. High TSH is seen in nearly 1/3rd of chronic
lithium-treated patients even in the absence of clinical hypothyroidism. In resistant depression

17 - Haematological effects
Haematological effects

18 - Neurological effects
Neurological effects
© SPMM Course
and in non-responsive rapid cyclers with bipolar disorder, using thyroxine to treat subclinical
hypothyroidism may be beneficial for the mood disorder.
Polycystic ovaries (PCO): 25 - 33% UK population of adult females have PCO morphology
notable in ultrasound. 5-26% may have actual PCOD, which is defined as having PCO in
ultrasound with hyperandrogenism or LH disturbance. 10% woman on valproate have new onset
PCOD. The relative risk is 7.5 for PCOD. On stopping most people remit from PCOD.
The exact mechanism by which valproate might causes PCOD remains unknown, although
several mechanisms are proposed. For example, valproate increases ovarian androgen
production. It also can result in weight gain and insulin resistance, both risk factors for PCOD. In
the liver, the drug can increase unbound testosterone.
Epilepsy, for which valproate is widely used, is tipped to increase PCOD occurrence. Such
association has not been established so far for bipolar disorder.
Almost all patients who develop oligomenorrhea develop it in first year of treatment with
valproate.
Haematological effects
Lithium can cause leucocytosis that can be therapeutically utilized in some cases of benign
neutropenia related to clozapine use. This is not widely practiced.
Around 10% of individuals taking carbamazepine will see gradual onset leucopenia in first
3months of treatment. This is reversible on continued treatment or dose reduction.
Thrombocytopenia is a dose-related effect of valproate and carbamazepine – a reduction in dose
is required if bruising, or bleeding gums is noted.
Neurological effects
Fine tremor is a common benign side effect of lithium, and coarse tremor is a sign of toxicity.
Propranolol can be used in treating lithium-induced fine tremor at therapeutic levels.
Lamotrigine is generally well tolerated but can cause dizziness, ataxia, headache, sedation,
tremor, and nausea.
Topiramate can produce word finding difficulties (anomia) and poor concentration
Vigabatrin, an antiepileptic with no significant antimanic efficiency, has been tried in some openlabel trials. It has a peculiar side effect of causing visual field defects.

19 - Gastrointestinal effects
Gastrointestinal effects

20 - Teratogenic effects
Teratogenic effects

21 - Skin effects
Skin effects
© SPMM Course
Gastrointestinal effects
Valproate inhibits hepatic enzymes; in some cases the acute liver injury may occur though this is
rare in clinical practice. Of persons taking valproate, 5 to 40 percent experience a persistent but
clinically insignificant elevation in liver transaminases up to three times the upper limit of
normal, which is usually asymptomatic and resolves after discontinuation of the drug (termed
‘transaminitis’).
Liver failure is reported with valproate, lamotrigine, topiramate and carbamazepine. Risk factors
include young age and combination therapy. This is caused by 2 mechanisms: 1. Metabolic
toxicity e.g. due to 4-en valproate, a metabolite of valproate. 2. Hypersensitivity - doseindependent effect is resulting in fulminant failure. Severe hepatic damage associated with
valproate is seen especially in those with learning disability when undiagnosed urea cycle
disorders are present (less than 2 years often).
Another rare side effect of valproate is acute pancreatitis. This is a hypersensitivity reaction; dose
reduction will not be helpful.
Hyperammonemia can be associated with coarse tremor and carbamazepine co-prescription; it
may respond to L-carnitine administration. Valproate competes with carnitine transport and can
induce a state of carnitine depletion especially in children and in epileptics.
Teratogenic effects
The most common teratogenic effect of lithium involves cardiac valves especially Ebstein's
anomaly of the tricuspid valves. The risk of Ebstein's malformation in lithium-exposed fetuses is
1 of 1,000 (20 times the risk in the general population).  Lithium’s  teratogenic  effects  are  somewhat  
lower than that caused by the use of valproate or carbamazepine. Lithium is excreted into breast
milk, and signs of lithium toxicity in infants include lethargy, cyanosis and sluggish neonatal
reflexes.
Valproate causes neural tube defects as a teratogenic effect in 1% to 4% mothers. Folate-vitamin
B complex supplementation for all young women of childbearing potential may reduce risk
though it is best to avoid valproate totally.
Learning disability and low IQ in children is the most common teratogenic effect of valproate.
Skin effects
Exacerbation of acne and psoriasis are associated with lithium therapy.
Alopecia / hair loss occurs in 5 to 10 percent. It is not clear if zinc and selenium supplementation
can reverse or prevent the latter effect.

22 - Weight related effects
Weight related effects
© SPMM Course
Valproate can cause obesity, hyperandrogenism and PCOD associated with hirsutism.
Anticonvulsant hypersensitivity syndrome is seen in 0.1% of patients taking anticonvulsants.
Aromatic compounds (lamotrigine, carbamazepine, phenytoin and phenobarbitone) are
especially risky.
5 to 20% of those taking aromatic anticonvulsants will experience a rash. Lamotrigine can cause a
rash in 10% of patients. Risk factors for rash include rapid initial dose escalation, concurrent VPA,
and age less than 16 years. As benign rashes cannot be distinguished from potentially serious
ones, any rash requires discontinuation of the drug.
Lamotrigine carries a significant risk of Steven Johnson Syndrome (SJS – risk of 1 in 3000)
especially if administered together with Valproate as the enzyme inhibiting effects of Valproate
may increase lamotrigine levels. SJS starts with a rash, pharyngitis and fever. Systemic
involvement follows quickly if the drug is not stopped.
Drug
Dose-related effects
Idiosyncratic reactions
Carbamazepine Visual disturbances, GI
disturbances, cognitive
impairment, vertigo and, dizziness.
Hematological reactions including
agranulocytosis or aplastic anemia, idiosyncratic
Stevens-Johnson syndrome, fulminant hepatic
damage, and pancreatitis. SIADH is more
common in the elderly
Valproate
Hyperammonemia, Teratogenicity,
Sedation, Thrombocytopenia
Hepatotoxicity, pancreatitis, rash and rarely acute
dermatitis.
Weight related effects
Weight gain is common (70% of those taking valproate and 40% of those taking carbamazepine over 12
months will experience weight gain); valproate induced weight gain is considered to be due to impaired
beta-oxidation of fatty acids, and thus independent of calorie intake. Lamotrigine is often weight neutral
Topiramate is weight neutral and can even cause weight loss. Topiramate can be potentially used to
counteract the weight gain caused by many psychotropic drugs.

23 - 6. Other agents adverse effects
6. Other agents - adverse effects
© SPMM Course
6. Other agents - adverse effects
Cholinesterase inhibitors: Donepezil causes nausea, diarrhea, insomnia, vomiting, muscle
cramps commonly. Rivastigmine causes similar symptoms albeit at a higher frequency of some.
Galantamine too has a similar profile. Tacrine is not used anymore in UK due to reports of fatal
hepatotoxicity.
By increasing central and peripheral cholinergic stimulation cholinesterase inhibitors, can
Increase the risk for GI bleeding especially in NSAID users or patients with
peptic ulcer.
Produce bradycardia, especially in those with supraventricular conduction
delay,
Exacerbate COPD
Cause urinary retention
Increase seizure risk
Prolong the effects of succinylcholine-type muscle relaxants
Rivastigmine’s  metabolism  does  not  depend  on  liver  P450  enzymes,  and, therefore, no drug
interactions related to the P450 system have been observed. Memantine does not inhibit or
induce hepatic microsomal enzymes; because it is excreted in the urine predominantly as
unchanged drug, it is unlikely to be affected by drugs that affect hepatic enzyme function.
Stimulants and other drugs used for ADHD: The most common adverse effects are anxiety,
irritability, insomnia, tachycardia, cardiac arrhythmias, and dysphoria with decreased appetite.
Tolerance usually develops for appetite loss. Less commonly self-limited exacerbation of
movement disorders, such as tics and dyskinesias, may occur.
Stimulants are linked to growth suppression. Bruxism and restlessness are also reported.
Pemoline is associated with fulminant hepatic failure and is no longer used widely. Dependence
can occur with methylphenidate though this is rare at doses used for ADHD.
Side effects of atomoxetine are appetite loss, sexual dysfunction and dizziness; severe liver injury
in has also been reported.
Clonidine is not a popular option for treating tics/ADHD due to high rates of hypotension
associated with it.
Hypnotics: Overdose of benzodiazepines can produce slurred speech, incoordination, unsteady
gait, nystagmus, impairment in attention or memory, stupor or coma and behavioural changes
(inappropriate sexual or aggressive behaviour, mood lability, impaired judgment etc.).

24 - 7. Psychiatric effects of non psychiatric dru
7. Psychiatric effects of non-psychiatric drugs
© SPMM Course
High-potency benzodiazepines such as triazolam can cause anterograde amnesia.
Paradoxical disinhibition is seen in a few patients especially when preexisting brain damage is
present. Triazolam is banned in UK since 1991 following reports of disinhibition and aggression.
Benzodiazepines can produce respiratory impairment especially in those with COPD or sleep
apnea. Benzodiazepines are better avoided in those with myasthenia gravis, head injury or
porphyria due to this risk.
Alprazolam can cause weight gain via appetite stimulation.
Cleft palate and lips are teratogenic effects associated with benzodiazepines; withdrawal
syndrome is seen in a neonate with third trimester use.
Z-hypnotics have more potential to cause upset stomach and diarrhea compared with
benzodiazepines.
Eszopiclone’s  unique  temporary  side  effect  is  an  unpleasant taste. It can also cause dry mouth
especially in the elderly in a dose-dependent fashion.
The occurrence of benzodiazepine withdrawal syndrome depends on
The duration of treatment,
The dosage prescribed,
The rate of tapering and
The half-life of the compound.
Benzodiazepine withdrawal is characterized by anxiety, diaphoresis, kinaesthetic hallucinations,
restlessness, irritability, light-headedness, tremor, insomnia, autonomic hyperactivity, and
weakness. In severe cases, depression, paranoia, delirium, and grand mal seizures are seen. The
syndrome can occur after 1 or 2 weeks in long-acting benzodiazepines. Alprazolam and
lorazepam are associated with immediate and severe withdrawal syndrome and should be
tapered gradually.
Using prescribed benzodiazepines for 4 weeks or less rarely results in significant withdrawal
symptoms. But if used for 4 months – 5-10% have withdrawals; in 2 years – 25-45% and in 68years – 75% develop withdrawal syndrome and dependence pattern (Law et al. 2004).
Slow taper at a rate of 25% per week, use of longer acting agents when tapering, avoiding longterm use of short-acting benzodiazepines, use of carbamazepine to assist discontinuation are the
various strategies employed to manage withdrawal symptoms.
7. Psychiatric effects of non-psychiatric drugs
© SPMM Course
Non-psychiatric drugs
Psychiatric side effects
Beta-blockers
Sedation, nightmares, dysphoria (nearly 50% in some samples) and depression.
Psychiatric effects are seen only with lipophilic compounds e.g. metoprolol and
propranolol.
Angiotensinconverting enzyme
(ACE) inhibitors
Increased arousal, anxiety, fatigue, insomnia and increased psychomotor
activity (4-8%)
Clonidine
Sedation or lethargy (35%); anxiety (3%), agitation (3%), depression (1%), and
insomnia (1%).
Nitrates/nitrites
Delirium, psychosis (including delusions), anxiety, restlessness, agitation, and
hypomania.
Digoxin
Depression and delirium (even in therapeutic levels)
Statins
Uncertain association with depression (evidence inconclusive)
Corticosteroids
Mood changes (mania more than depression), anxiety, agitation, lethargy.
Dose-dependent. 1 in 6 patients has psychiatric side effects if prednisolone is
prescribed in doses above 80mg/day. Symptoms start within 2 weeks. More
common in females and those with past psychiatric history.
Anabolic androgenic
steroids
Acute paranoia, delirium, mania or hypomania, homicidal rage, aggression,
and extreme mood swings, as well as a marked increase in libido, irritability,
agitation, and anger. Usually dose-dependent and resolve in 1-4 weeks after
stopping the steroids.
Gonadotropinreleasing hormone
(GnRH) agonists (e.g.
leuprolide)
Depressive symptoms
Interferon-alpha
Nearly 40% develop psychiatric side effects; ~20% experience depression. Seen
in first 12 weeks of treatment.
Penicillin
Sedation, anxiety and hallucinations
Cephalosporins
Delirium
Ciprofloxacin and
ofloxacin
Restlessness, irritability, lethargy, tremors, insomnia, mania, depression,
psychosis,  delirium,  seizures,  or  catatonia  (incidence  ≤1%)
Isoniazid
Delirium, mania, depression, and psychosis.
Tetracyclines
Depression, insomnia, and irritability at high dosages.
Antihistamines and
Atropine-like psychosis
© SPMM Course
decongestants
Proton pump
inhibitors & H2antagonists used for
peptic ulcer disease
Confusion, agitation, depression, and hallucinations— mainly in geriatric
patients with impaired hepatic-renal function.
Ondansetron
Anxiety
Isotretinoin
Severe depression and suicidal behavior.
Aminophylline and
salbutamol
Agitation, insomnia, euphoria, and delirium
Depressogenic drugs
x Beta blockers
x Calcium channel blockers
x Interferons (alpha > beta)
x Steroids
x Cyproterone, progesterone
x Varenicline
x Isotretinoin
x Ezetimibe
Rimonabant: Two endocannabinoid receptors CB1 and CB2 are identified; based on the clinical
observations of cannabis related increase in appetite  (the  “munchies”), researchers have studied
the involvement of endocannabinoid system in the control of energy balance. Rimonabant, the
first  of  the  CB1-receptor antagonists, was developed as an anti-obesity agent on the premise that
blocking central cannabinoid activity might reduce food intake. But there is compelling evidence
that rimonabant is associated with the development of severe adverse psychiatric events (2.5
times more depression; suicidal ideas and 3 times more anxiety).
Animal studies have consistently shown that pharmacological blockade of the CB1 receptor
impaired the anti depressant-reducing or anxiety-reducing actions of endocannabinoids. FDA
has issued a warning now on the use of this agent.

25 - 8. Prescribing controlled drugs
8. Prescribing controlled drugs
© SPMM Course
8. Prescribing controlled drugs
1971 MISUSE OF DRUGS ACT UK
Class A drugs: Ecstasy, LSD, heroin, cocaine, crack, magic mushrooms (whether prepared or fresh),
methylamphetamine (crystal meth), other amphetamines if prepared for injection
o Penalties for possession: Up to seven years in prison or an unlimited fine. Or both
o Penalties for dealing: Up to life in prison or an unlimited fine. Or both
Class B drugs: Amphetamines, Methylphenidate (Ritalin), Pholcodine
o Penalties for possession: Up to five years in prison or an unlimited fine. Or both
o Penalties for dealing: Up to 14 years in prison or an unlimited fine. Or both.
Class C drugs: Cannabis, tranquilisers, some painkillers, GHB (Gamma-hydroxybutyrate), ketamine
o Penalties for possession: Up to two years in prison or an unlimited fine. Or both
o Penalties for dealing: Up to 14 years in prison or an unlimited fine. Or both
2001 MISUSE OF DRUGS REGULATIONS
Schedule
Examples
Regulations
Coca leaf, cannabis, LSD, mescaline
No recognized medicinal use. Supply is limited to
research or other special purposes judged to be in the
public interest.
 Requires Home Office licence to
possess.
Diamorphine, dipipanone,
morphine, remifentanil, pethidine,
secobarbital, glutethimide,
amphetamine and cocaine
Subject to special prescription requirements and safe
custody requirements (with the exception of
secobarbital). Stock drugs must be recorded in a
register that meets the requirements of the 2001
Regulations, and drug stock must only be destroyed
in the presence of an appropriately authorized person.
The barbiturates (except
secobarbital), buprenorphine,
diethylpropion, mazindol,
meprobamate, pentazocine,
phentermine, and temazepam
These drugs are subject to the special prescription
requirements (except for temazepam) but not to the
safe custody requirements (except for buprenorphine,
diethylpropion, flunitrazepam and temazepam) or to
the need to keep a register, although there are
requirements for the retention of invoices for 2 years
Part 1
Benzodiazepines (not temazepam)
and zolpidem
These drugs are not subject to the special prescription
requirements or to safe custody requirements. There
© SPMM Course
Part 2
Androgenic and anabolic steroids,
clenbuterol, chorionic
gonadotrophin (HCG), non-human
chorionic gonadotrophin,
somatotropin, somatrem, and
somatropin
is no need to keep a register, although there are
requirements for the retention of invoices for 2 years
Weak preparations of drugs usually
in other schedules, for example,
morphine, codeine
Exempt from all controlled drug regulations except
the need to keep invoices for at least 2 years
All controlled drug prescriptions should have
The  patient’s  full  name,  address  and  age
If  a  patient  is  homeless,  ‘no  fixed  abode’  is  an  acceptable  address  
The name and form of the drug MUST be written
The strength of the preparation, where appropriate
The dose to be taken MUST be written
The total quantity of the preparation, or the number of 
dose units, to be supplied in both
words and figures 

A patient identifier number (e.g. NHS number) should be included on prescriptions for
controlled drugs
Prescriptions must be signed by the prescriber with their usual signature (this must be
handwritten) along with GMC number as a good practice
The validity period of prescriptions for Schedule 1, 2, 3 and 4 controlled drugs have been
restricted to 28 days.
Schedule 2 and 3 drugs cannot be prescribed on repeat prescriptions or under repeat
dispensing schemes.
Patients ideally should collect the controlled drug in person after showing their
identification on the first occasion and signing the back of the prescription form.
Substitute opioids should be prescribed in daily instalments whenever required.
Prescriptions of instalments must specify
o The number of instalments
o The interval between instalments,
o Instructions for supplies at weekends or bank 
holidays
o The total quantity to provide 
treatment for a period (this must not be exceeding 14
days generally)
o The quantity to be supplied in each instalment along with the duration of the
instalments  to  be  set  out  on  the  prescription,  for  example  ‘dispense  daily  for
fourteen days starting on 3rd September  2015’.

26 - 9. ADR Databases
9. ADR Databases
© SPMM Course
9. ADR Databases
It is vital that adverse drug reactions (ADRs) that are hitherto unreported are detected rapidly
and recorded to reduce the hazards of medical prescribing. Such reports will also trigger
regulatory action to ensure further patient safety.
MHRA encourages reporting adverse reaction through Yellow Card system even if it is not
certain that the drug has caused it, or if the reaction is well recognised, if an overdose has been
taken or if other drugs have been given at the same time. Prescribers, patients, carers and
pharmacists can all use the yellow card scheme.
The black triangle symbol is used to inform that a preparation is newly licensed and requires
additional monitoring by the European Medicines Agency. For medicines with the black triangle
symbol, the MHRA requires that all suspected reactions (including those that are not serious) be
reported. For all other drugs, the yellow cards can be sued to report side effects that are serious,
medically significant, or result in harm. Adverse drug reactions that result from a medication
error are also reportable using Yellow cards.
Term used to describe frequency
Rates observed
Very common
Greater than 1 in 10
Common
1 in 100 to 1 in 10
Uncommon or ‘less  commonly’  in  BNF
1 in 1000 to 1 in 100
Rare
1 in 10 000 to 1 in 1000
Very rare
Less than 1 in 10 000
WHO established an international system for monitoring adverse reactions to drugs (ADRs) in
1971. This is located at WHO Collaborating Centre for International Drug Monitoring, Uppsala
Monitoring Centre, (UMC), in Sweden. The ADRs database held by WHO contains over three
million reports of suspected ADRs. Similar reporting systems exist in many other developed
nations. The Canada Vigilance Adverse Reaction Online Database and the European
Medicines Agency ADR Reporting systems are some examples of other well-developed
national/international ADR databases.
Worsening of glaucoma: paroxetine,
quetiapine, TCAs
Retinal pigmn: Thioridazine
Corneal deposits: CPZ
Visual field defects: vigabatrin
Osteoporosis: hyperprolatinaemic
antipsychotics
WBC suppression: ^zapines(olanz, mirtaz,
cloz, carbama), mianserin
Haemolytic anaemia: nomifensine
Myocarditis / Pul Embolism: clozapine
QT prolong: all antipsychotics esp
.Thioridazine, Pimozide, droperidol
Arrythmias: high dose TCAs
High BP: VFX, TCAs
Hypersalivation: clozapine
Bruxism: stimulants
Hypothyroidism: Li
Fine tremors: therapeutic dose of lithium,
TCAs
Coarse tremors: antipsychotic Parkinsonism,
Wt gain: all antipsychotics (less for APZ,
ZPD), TCAs, Li, VPA, CBZ
Wt loss: Topiramate, Bupropion
Guillian Barre: Zimeldine
Pedal oedema: MAOIs
Cramps: AchEs
Orthostatic hypotension: all TCAs, all
antipsychotics
Priapism: Trazodone, risperidone
PCOD: Valproate
Erectile dysfunction: all TCAs,
antipsychotics
Delayed ejacln or anorgasmia: SSRIs
Hepatic damage: nefazodone, VPA, tacrine
Enz induction: CBZ, phenytoin, barbiturates
Ac. Pancreatitis: VPA
P.ileus: clozapine
GI bleed: SSRIs, AChEs
Renal damage: Lithum
Nephrolithiasis: topiramate
EPSEs: all neuroleptics (less for
Anticholinergic neuroleptics e.g. CPZ), higher
dose atypicals
Delirium: Anticholinergic TCAs, Anticholinergic
antipsychotics
Seizures: bupropion, clozapine
Tics: stimulants
Amnesia: BDZ
Rashes, SJS: CBZ, Lamotrigine
Thrombocytopenia: Valproate
Sweating: all SSRIs, TCAs, esp. VFX
Acne, psoriasis: Li
Psychotropics Adverse Effects Chart
© SPMM Course
AchEs: Anticholinesterases, BDZ: Benzodiazepines, CBZ: carbamazepine, CPZ: Chlorpromazine VFX: Venlafaxine VPA:
Valproate, SJS: Steven Johnson Syndrome,
© SPMM Course
Notes prepared using excerpts from:
Ashton, H & Young, A. SSRIs, drug withdrawal and abuse: Problem or treatment? Selective
Serotonin Reuptake Inhibitors (SSRIs): Past, Present and Future, Chapter 5, 1999.
http://www.benzo.org.uk/ssri.htm
Bolland, W., & Simon, C. (2008). Controlled drugs: regulations and prescribing. InnovAiT: The
RCGP Journal for Associates in Training, 1(2), 163-171.
Brown E & Chanlder S. Mood and Cognitive Changes During Systemic Corticosteroid Therapy.
Prim Care Companion J Clin Psychiatry. 2001 Feb; 3(1): 17–21.
Di Lorenzo, R & Brogli, A. Neuropsychiatr Dis Treat. 2010; 6: 573–581.
Edwards IR, Aronson JK. Adverse drug reactions: definitions, diagnosis and management. Lancet
2000; 356:1255-9.
http://www.evidence.nhs.uk/formulary/bnf/current/yellow-card-scheme
Jones, O. Managing a suspected adverse drug reaction. Student BMJ 2001; 09:261-304
Kaplan & Sadock's Synopsis of Psychiatry: Behavioral Sciences/Clinical Psychiatry, 10th Edition.
Lippincott Williams & Wilkins 2007. Pg 982.
Kasper, S. (2002) Managing reboxetine-associated urinary hesitancy in a patient with major
depressive disorder: a case study. Psychopharmacology, 159, 445-446.
Lewis S & Lieberman, J. T he British Journal of Psychiatry Mar 2008, 192 (3) 161-163
Paton C, Ferrier IN. SSRIs and gastrointestinal bleeding BMJ 2005; 331 :529
Seeman P, Tallerico, P. Mol Psychiatry. 1998 Mar;3(2):123-34.
Shiloh, R., Nutt, D. & Weizman, A. (2000). Atlas of psychiatric pharmacotherapy. Martin Dunitz,
London. Page 18
Sidhu KS & Balon R (2008). Watch for nonpsychotropics causing psychiatric side effects. Current
Psychiatry; 7(4); 61
Swann, A. Major system toxicities and side effects of anticonvulsants. J Clin Psych 2001; 62 [16-21]
Szabadi, E. (1998) Doxazosin for reboxetine-induced urinary hesitancy. The British Journal of
Psychiatry, 173, 441b-442.
Thakore, JH. The British Journal of Psychiatry Jun 2005, 186 (6) 455-456;
UK Home Office http://drugs.homeoffice.gov.uk/drugs-laws/misuse-of-drugs-act/
DISCLAIMER: This material is developed from various revision notes assembled while preparing for
MRCPsych exams. The content is periodically updated with excerpts from various published
sources including peer-reviewed journals, websites, patient information leaflets and books. These
sources are cited and acknowledged wherever possible; due to the structure of this material,
acknowledgements have not been possible for every passage/fact that is common knowledge
in psychiatry. We do not check the accuracy of drug related information using external sources;
no part of these notes should be used as prescribing information.