Bazett’s formula adjusts the QT interval to account for variations in heart rate.

QTc Prolongation: Risks and Identification

The QT interval is a measure of the time it takes for the ventricles to repolarize and is calculated from the beginning of the QRS complex to the end of the T wave. However, the QT interval varies with the heart rate, making it difficult to use a single number as a cut-off for a prolonged QT. Instead, a corrected QT interval (QTc) is calculated for each heart rate using various formulas. A QTc over the 99th percentile is considered abnormally prolonged, with approximate values of 470 ms for males and 480 ms for females.

Prolonged QT intervals can lead to torsade de pointes (TdP), a polymorphic ventricular tachycardia that can be fatal if it degenerates into ventricular fibrillation. TdP is characterized by a twisting of the QRS complexes around an isoelectric line and is often asymptomatic but can also be associated with syncope and death. An accurate diagnosis requires an ECG to be recorded during the event. It is important to note that an increase in the QT interval due to a new conduction block should not be considered indicative of acquired LQTS and risk for TdP.

Mirtazapine and Mianserin are significant NaSSA’s (Noradrenergic and specific serotonergic antidepressants) that function by blocking adrenergic and serotonergic receptors. In contrast to the majority of antidepressants, they do not impact the reuptake of serotonin.

Mechanisms of Action of Different Drugs

Understanding the mechanisms of action of different drugs is crucial for medical professionals. It is a common topic in exams and can earn easy marks if studied well. This article provides a list of drugs and their mechanisms of action in different categories such as antidepressants, anti dementia drugs, mood stabilizers, anxiolytic/hypnotic drugs, antipsychotics, drugs of abuse, and other drugs. For example, mirtazapine is a noradrenaline and serotonin specific antidepressant that works as a 5HT2 antagonist, 5HT3 antagonist, H1 antagonist, alpha 1 and alpha 2 antagonist, and moderate muscarinic antagonist. Similarly, donepezil is a reversible acetylcholinesterase inhibitor used as an anti dementia drug, while valproate is a GABA agonist and NMDA antagonist used as a mood stabilizer. The article also explains the mechanisms of action of drugs such as ketamine, phencyclidine, buprenorphine, naloxone, atomoxetine, varenicline, disulfiram, acamprosate, and sildenafil.

Medication Types:

Atomoxetine (Strattera) is a medication used to treat ADHD by inhibiting the reuptake of noradrenaline. It has a similar structure to some antidepressants.

Acamprosate is a medication that acts as an antagonist at NMDA receptors and is the only medication licensed for the relief of cravings in alcohol dependence.

Alprazolam is a benzodiazepine medication.

Amisulpride is an atypical (second generation) antipsychotic medication that works as a serotonin and dopamine antagonist.

Aripiprazole is an atypical antipsychotic medication that acts as a partial agonist at dopamine receptors.

Alternative Routes of Administration for Antidepressants

While most antidepressants are taken orally, there are a few alternative routes of administration available. However, it is important to note that these non-oral preparations should only be used when absolutely necessary, as they may not have a UK licence.

One effective alternative route is sublingual administration of fluoxetine liquid. Buccal administration of selegiline is also available. Crushed amitriptyline has been shown to be effective when administered via this route.

Intravenous administration is another option, with several antidepressants available in IV preparations, including citalopram, escitalopram, mirtazapine, amitriptyline, clomipramine, and allopregnanolone (which is licensed in the US for postpartum depression). Ketamine has also been shown to be effective when administered intravenously.

Intramuscular administration of flupentixol has been shown to have a mood elevating effect, but amitriptyline was discontinued as an IM preparation due to the high volumes required.

Transdermal administration of selegiline is available, and suppositories containing amitriptyline, clomipramine, imipramine, and trazodone have been manufactured by pharmacies, although there is no clear data on their effectiveness. Sertraline tablets and doxepin capsules have also been given rectally.

Pharmacokinetics of Benzodiazepines

Benzodiazepines are a class of drugs that are easily absorbed when taken orally. They have a high affinity for plasma proteins, with diazepam showing a binding rate of 95%. These drugs are primarily metabolized in the liver. Due to their lipophilic nature, they can quickly cross the blood-brain barrier and placental barrier. This property makes them effective in treating anxiety and other related disorders. Understanding the pharmacokinetics of benzodiazepines is crucial in determining their efficacy and potential side effects.

Both lithium carbonate and citrate are used for the treatment and prevention of various mental health conditions, including mania, bipolar disorder, recurrent depression, and aggressive of self-harming behavior. Lithium carbonate is available in tablet form, while lithium citrate is a liquid medication.

Lithium – Pharmacology

Pharmacokinetics:
Lithium salts are rapidly absorbed following oral administration and are almost exclusively excreted by the kidneys unchanged. Blood samples for lithium should be taken 12 hours post-dose.

Ebstein’s:
Ebstein’s anomaly is a congenital malformation consisting of a prolapse of the tricuspid valve into the right ventricle. It occurs in 1:20,000 of the general population. Initial data suggested it was more common in those using lithium but this had not held to be true.

Contraindications:
Addison’s disease, Brugada syndrome, cardiac disease associated with rhythm disorders, clinically significant renal impairment, untreated of untreatable hypothyroidism, low sodium levels.

Side-effects:
Common side effects include nausea, tremor, polyuria/polydipsia, rash/dermatitis, blurred vision, dizziness, decreased appetite, drowsiness, metallic taste, and diarrhea. Side-effects are often dose-related.

Long-term use is associated with hypothyroidism, hyperthyroidism, hypercalcemia/hyperparathyroidism, irreversible nephrogenic diabetes insipidus, and reduced GFR.

Lithium-induced diabetes insipidus:
Treatment options include stopping lithium (if feasible), keeping levels within 0.4-0.8 mmol/L, once-daily dose of the drug taken at bedtime, amiloride, thiazide diuretics, indomethacin, and desmopressin.

Toxicity:
Lithium salts have a narrow therapeutic/toxic ratio. Risk factors for lithium toxicity include drugs altering renal function, decreased circulating volume, infections, fever, decreased oral intake of water, renal insufficiency, and nephrogenic diabetes insipidus. Features of lithium toxicity include GI symptoms and neuro symptoms.

Pre-prescribing:
Before prescribing lithium, renal function, cardiac function, thyroid function, FBC, and BMI should be checked. Women of childbearing age should be advised regarding contraception, and information about toxicity should be provided.

Monitoring:
Lithium blood levels should be checked weekly until stable, and then every 3-6 months once stable. Thyroid and renal function should be checked every 6 months. Patients should be issued with an information booklet, alert card, and record book.

Antipsychotic drugs are known to cause weight gain, but some more than others. The reason for this is not due to a direct metabolic effect, but rather an increase in appetite and a decrease in activity levels. The risk of weight gain appears to be linked to clinical response. There are several suggested mechanisms for this, including antagonism of certain receptors and hormones that stimulate appetite. The risk of weight gain varies among different antipsychotics, with clozapine and olanzapine having the highest risk. Management strategies for antipsychotic-induced weight gain include calorie restriction, low glycemic index diet, exercise, and switching to an alternative antipsychotic. Aripiprazole, ziprasidone, and lurasidone are recommended as alternative options. Other options include aripiprazole augmentation, metformin, orlistat, liraglutide, and topiramate.

Understanding Biotransformation: A Metabolic Process for Excretion

Biotransformation is a metabolic process that occurs primarily in the liver, but also in other organs such as the kidneys, intestine, adipose, skin, and lungs. Its main function is to facilitate the excretion of both exogenous and endogenous substances by altering their chemical structures through a series of reactions. Enzymes found in the cytoplasm, endoplasmic reticulum, and mitochondria of cells catalyze these reactions, which can cause the substrate to become inactive, active, of even toxic.

Biotransformation is divided into three phases. Phase I reactions involve oxidation, reduction, of hydrolysis of the drug, yielding a polar, water-soluble metabolite that is often still active. Phase II reactions consist of adding hydrophilic groups to the original molecule, a toxic intermediate, of a nontoxic metabolite formed in phase I, to increase its polarity. The most common method is conjugation with glucuronic acid, but other groups such as sulphate, amino acids, acetate, and methyl can also be added. Phase III reactions occur post-phase II, where a chemical substance can undergo further metabolism and excretion through active transport into the urinary of hepatobiliary system.

Understanding biotransformation is crucial in pharmacology and toxicology, as it affects the efficacy and toxicity of drugs and other substances. By facilitating the excretion of these substances, biotransformation helps maintain homeostasis in the body and prevent accumulation of potentially harmful compounds.

Charpentier synthesised Chlorpromazine in 1950, and it was subsequently introduced into clinical practice in the 1950s.

A Historical Note on the Development of Zimelidine, the First Selective Serotonin Reuptake Inhibitor

In 1960s, evidence began to emerge suggesting a significant role of serotonin in depression. This led to the development of zimelidine, the first selective serotonin reuptake inhibitor (SSRI). Zimelidine was derived from pheniramine and was marketed in Europe in 1982. However, it was removed from the market in 1983 due to severe side effects such as hypersensitivity reactions and Guillain-Barre syndrome.

Despite its short-lived availability, zimelidine paved the way for the development of other SSRIs such as fluoxetine, which was approved by the FDA in 1987 and launched in the US market in 1988 under the trade name Prozac. The development of SSRIs revolutionized the treatment of depression and other mood disorders, providing a safer and more effective alternative to earlier antidepressants such as the tricyclics and MAO inhibitors.

SNRIs are a type of antidepressant medication that work by blocking the reuptake of both serotonin and norepinephrine, providing two mechanisms to help with the antidepressant effect. They are particularly effective at inhibiting the norepinephrine transporter compared to the serotonin transporter. Examples of SNRIs include Venlafaxine, Desvenlafaxine, Duloxetine, and Milnacipran. Bupropion is a different type of antidepressant that works by inhibiting the reuptake of norepinephrine and dopamine (NDRI). Escitalopram is a selective serotonin reuptake inhibitor (SSRI), while Mirtazapine is a noradrenergic and specific serotonin antidepressant (NaSSA). Nefazodone is a serotonin antagonist/reuptake inhibitor (SARI).

As the concentration decreases, the half-life of a zero order reaction becomes shorter. This is because zero order kinetics involve constant elimination, meaning that the rate of elimination does not change with increasing concentration. Therefore, as the concentration decreases, there is less drug available to be eliminated at a constant rate, resulting in a shorter half-life.

The half-life of a drug is the time taken for its concentration to fall to one half of its value. Drugs with long half-lives may require a loading dose to achieve therapeutic plasma concentrations rapidly. It takes about 4.5 half-lives to reach steady state plasma levels. Most drugs follow first order kinetics, where a constant fraction of the drug in the body is eliminated per unit time. However, some drugs may follow zero order kinetics, where the plasma concentration of the drug decreases at a constant rate, despite the concentration of the drug. For drugs with nonlinear kinetics of dose-dependent kinetics, the relationship between the AUC of CSS and dose is not linear, and the kinetic parameters may vary depending on the administered dose.

Pemoline, a central nervous system stimulant that was once used to treat ADHD, is now known to cause severe liver failure that can be fatal. Due to this dangerous side effect, it was taken off the market in the UK in 1997. Although this information may no longer be applicable in a clinical setting, we have kept the question in our database as it may still appear in exams.

ADHD medications can be classified into stimulant and non-stimulant drugs. The therapeutic effects of these drugs are believed to be mediated through the action of noradrenaline in the prefrontal cortex. Common side effects of these drugs include decreased appetite, insomnia, nervousness, headache, and nausea. Stimulant drugs like dexamphetamine, methylphenidate, and lisdexamfetamine inhibit the reuptake of dopamine and noradrenaline. Non-stimulant drugs like atomoxetine, guanfacine, and clonidine work by increasing noradrenaline levels in the synaptic cleft through different mechanisms. The most common side effects of these drugs are decreased appetite, somnolence, headache, and abdominal pain.

Lithium has a tendency to remain unattached to proteins and instead remains unbound within the body, resulting in its efficient elimination from the bloodstream through haemodialysis.

Lithium – Pharmacology

Pharmacokinetics:
Lithium salts are rapidly absorbed following oral administration and are almost exclusively excreted by the kidneys unchanged. Blood samples for lithium should be taken 12 hours post-dose.

Ebstein’s:
Ebstein’s anomaly is a congenital malformation consisting of a prolapse of the tricuspid valve into the right ventricle. It occurs in 1:20,000 of the general population. Initial data suggested it was more common in those using lithium but this had not held to be true.

Contraindications:
Addison’s disease, Brugada syndrome, cardiac disease associated with rhythm disorders, clinically significant renal impairment, untreated of untreatable hypothyroidism, low sodium levels.

Side-effects:
Common side effects include nausea, tremor, polyuria/polydipsia, rash/dermatitis, blurred vision, dizziness, decreased appetite, drowsiness, metallic taste, and diarrhea. Side-effects are often dose-related.

Long-term use is associated with hypothyroidism, hyperthyroidism, hypercalcemia/hyperparathyroidism, irreversible nephrogenic diabetes insipidus, and reduced GFR.

Lithium-induced diabetes insipidus:
Treatment options include stopping lithium (if feasible), keeping levels within 0.4-0.8 mmol/L, once-daily dose of the drug taken at bedtime, amiloride, thiazide diuretics, indomethacin, and desmopressin.

Toxicity:
Lithium salts have a narrow therapeutic/toxic ratio. Risk factors for lithium toxicity include drugs altering renal function, decreased circulating volume, infections, fever, decreased oral intake of water, renal insufficiency, and nephrogenic diabetes insipidus. Features of lithium toxicity include GI symptoms and neuro symptoms.

Pre-prescribing:
Before prescribing lithium, renal function, cardiac function, thyroid function, FBC, and BMI should be checked. Women of childbearing age should be advised regarding contraception, and information about toxicity should be provided.

Monitoring:
Lithium blood levels should be checked weekly until stable, and then every 3-6 months once stable. Thyroid and renal function should be checked every 6 months. Patients should be issued with an information booklet, alert card, and record book.

Phase I metabolism involves the conversion of a parent drug into active metabolites that are polar, whereas phase II metabolism converts the parent drug into inactive metabolites that are also polar.

Understanding Biotransformation: A Metabolic Process for Excretion

Biotransformation is a metabolic process that occurs primarily in the liver, but also in other organs such as the kidneys, intestine, adipose, skin, and lungs. Its main function is to facilitate the excretion of both exogenous and endogenous substances by altering their chemical structures through a series of reactions. Enzymes found in the cytoplasm, endoplasmic reticulum, and mitochondria of cells catalyze these reactions, which can cause the substrate to become inactive, active, of even toxic.

Biotransformation is divided into three phases. Phase I reactions involve oxidation, reduction, of hydrolysis of the drug, yielding a polar, water-soluble metabolite that is often still active. Phase II reactions consist of adding hydrophilic groups to the original molecule, a toxic intermediate, of a nontoxic metabolite formed in phase I, to increase its polarity. The most common method is conjugation with glucuronic acid, but other groups such as sulphate, amino acids, acetate, and methyl can also be added. Phase III reactions occur post-phase II, where a chemical substance can undergo further metabolism and excretion through active transport into the urinary of hepatobiliary system.

Understanding biotransformation is crucial in pharmacology and toxicology, as it affects the efficacy and toxicity of drugs and other substances. By facilitating the excretion of these substances, biotransformation helps maintain homeostasis in the body and prevent accumulation of potentially harmful compounds.

Elevated levels of creatine phosphokinase (CPK) are observed in NMS.

Serotonin Syndrome and Neuroleptic Malignant Syndrome are two conditions that can be difficult to differentiate. Serotonin Syndrome is caused by excess serotonergic activity in the CNS and is characterized by neuromuscular abnormalities, altered mental state, and autonomic dysfunction. On the other hand, Neuroleptic Malignant Syndrome is a rare acute disorder of thermoregulation and neuromotor control that is almost exclusively caused by antipsychotics. The symptoms of both syndromes can overlap, but there are some distinguishing clinical features. Hyper-reflexia, ocular clonus, and tremors are more prominent in Serotonin Syndrome, while Neuroleptic Malignant Syndrome is characterized by uniform ‘lead-pipe’ rigidity and hyporeflexia. Symptoms of Serotonin Syndrome usually resolve within a few days of stopping the medication, while Neuroleptic Malignant Syndrome can take up to 14 days to remit with appropriate treatment. The following table provides a useful guide to the main differentials of Serotonin Syndrome and Neuroleptic Malignant Syndrome.

Antidepressants can cause discontinuation symptoms when patients stop taking them, regardless of the type of antidepressant. These symptoms usually occur within 5 days of stopping the medication and can last up to 3 weeks. Symptoms include flu-like symptoms, dizziness, insomnia, vivid dreams, irritability, crying spells, and sensory symptoms. SSRIs and related drugs with short half-lives, such as paroxetine and venlafaxine, are particularly associated with discontinuation symptoms. Tapering antidepressants at the end of treatment is recommended to prevent these symptoms. TCAs and MAOIs are also associated with discontinuation symptoms, with amitriptyline and imipramine being the most common TCAs and all MAOIs being associated with prominent discontinuation symptoms. Patients at highest risk for discontinuation symptoms include those on antidepressants with shorter half-lives, those who have been taking antidepressants for 8 weeks of longer, those using higher doses, younger people, and those who have experienced discontinuation symptoms before. Agomelatine is not associated with any discontinuation syndrome. If a discontinuation reaction occurs, restarting the antidepressant of switching to an alternative with a longer half-life and tapering more slowly may be necessary. Explanation and reassurance are often sufficient for mild symptoms. These guidelines are based on the Maudsley Guidelines 14th Edition and a study by Tint (2008).

Antipsychotics and Sudden Death: Thioridazine and QTc Prolongation

Antipsychotic medications are known to carry a risk of sudden death, particularly due to their effects on cardiac function. Thioridazine, in particular, has been found to have pronounced effects on potassium channels and significantly prolongs the QTc interval, which is a measure of the time it takes for the heart to repolarize after each beat. This prolongation can lead to a potentially fatal arrhythmia known as torsades de pointes. As a result, thioridazine is most strongly associated with sudden death among antipsychotics.

However, all antipsychotics carry some degree of risk for QTc prolongation and should be closely monitored for changes in this interval. This is especially important for patients with preexisting cardiac conditions of other risk factors for arrhythmias. Regular electrocardiogram (ECG) monitoring may be necessary to detect any changes in QTc interval and adjust medication accordingly. By carefully monitoring patients and taking appropriate precautions, healthcare providers can help minimize the risk of sudden death associated with antipsychotic use.

While there is some conflicting evidence, it is generally believed that tobacco smoking does not have a significant impact on the effectiveness of lithium.

Tobacco products predominantly smoked tobacco that burns the organic matter produces hydrocarbons. And these hydrocarbons lead to the induction of certain cytochrome p450 enzymes notably CYP1A2 predominantly but also CYP1A1 and also CYP2E1 or other major enzymes that are induced by tobacco. This will lead to the increased clearance of a variety of pharmacologic agents that are used especially in psychiatric populations. The most important ones to remember are antipsychotics and one of the antidepressants specifically fluvoxamine. When it comes to antipsychotics, clozapine and olanzapine are probably the most important ones to remember but also haloperidol and chlorpromazine could be affected as well. But for antidepressants, it’s really fluvoxamine that’s going to be mostly affected. And what this means is that while the person is actively smoking cigarettes, the clearance of these medications is increased probably anywhere from 20% to 50% or sometimes even more. And so what this means is those individuals may require higher doses than usual.

Lithium – Pharmacology

Pharmacokinetics:
Lithium salts are rapidly absorbed following oral administration and are almost exclusively excreted by the kidneys unchanged. Blood samples for lithium should be taken 12 hours post-dose.

Ebstein’s:
Ebstein’s anomaly is a congenital malformation consisting of a prolapse of the tricuspid valve into the right ventricle. It occurs in 1:20,000 of the general population. Initial data suggested it was more common in those using lithium but this had not held to be true.

Contraindications:
Addison’s disease, Brugada syndrome, cardiac disease associated with rhythm disorders, clinically significant renal impairment, untreated of untreatable hypothyroidism, low sodium levels.

Side-effects:
Common side effects include nausea, tremor, polyuria/polydipsia, rash/dermatitis, blurred vision, dizziness, decreased appetite, drowsiness, metallic taste, and diarrhea. Side-effects are often dose-related.

Long-term use is associated with hypothyroidism, hyperthyroidism, hypercalcemia/hyperparathyroidism, irreversible nephrogenic diabetes insipidus, and reduced GFR.

Lithium-induced diabetes insipidus:
Treatment options include stopping lithium (if feasible), keeping levels within 0.4-0.8 mmol/L, once-daily dose of the drug taken at bedtime, amiloride, thiazide diuretics, indomethacin, and desmopressin.

Toxicity:
Lithium salts have a narrow therapeutic/toxic ratio. Risk factors for lithium toxicity include drugs altering renal function, decreased circulating volume, infections, fever, decreased oral intake of water, renal insufficiency, and nephrogenic diabetes insipidus. Features of lithium toxicity include GI symptoms and neuro symptoms.

Pre-prescribing:
Before prescribing lithium, renal function, cardiac function, thyroid function, FBC, and BMI should be checked. Women of childbearing age should be advised regarding contraception, and information about toxicity should be provided.

Monitoring:
Lithium blood levels should be checked weekly until stable, and then every 3-6 months once stable. Thyroid and renal function should be checked every 6 months. Patients should be issued with an information booklet, alert card, and record book.

Pharmacological management of dementia involves the use of acetylcholinesterase inhibitors (AChE inhibitors) and memantine. AChE inhibitors prevent the breakdown of acetylcholine, which is deficient in Alzheimer’s due to the loss of cholinergic neurons. Donepezil, galantamine, and rivastigmine are commonly used AChE inhibitors in the management of Alzheimer’s. However, gastrointestinal side effects such as nausea and vomiting are common with these drugs.

Memantine, on the other hand, is an NMDA receptor antagonist that blocks the effects of pathologically elevated levels of glutamate that may lead to neuronal dysfunction. It has a half-life of 60-100 hours and is primarily renally eliminated. Common adverse effects of memantine include somnolence, dizziness, hypertension, dyspnea, constipation, headache, and elevated liver function tests.

Overall, pharmacological management of dementia aims to improve cognitive function and slow down the progression of the disease. However, it is important to note that these drugs do not cure dementia and may only provide temporary relief of symptoms.

Narrow Therapeutic Index Drugs

Narrow therapeutic index (NTI) drugs are medications that have a small difference between the amount that causes a therapeutic effect and the amount that causes toxicity. In other words, the therapeutic index (TI) of these drugs is narrow. The TI is a ratio that compares the blood concentration at which a drug causes a therapeutic effect to the amount that causes death of toxicity.

In clinical practice, the TI is the range of doses at which a medication appeared to be effective in clinical trials for a median of participants without unacceptable adverse effects. For most drugs, this range is wide enough, and the maximum plasma concentration of the drug achieved when the recommended doses of a drug are prescribed lie sufficiently above the minimum therapeutic concentration and sufficiently below the toxic concentration.

However, some drugs have a narrow therapeutic index, which means that even small changes in dose of blood concentration can lead to serious adverse effects. The US Food and Drug Administration (FDA) defines a drug product as having an NTI when there is less than a twofold difference in the minimum toxic concentrations and minimum effective concentrations in the blood and safe and effective use of the drug requires careful titration and patient monitoring.

Examples of drugs with a narrow therapeutic index include carbamazepine, lithium, phenytoin, warfarin, digoxin, and gentamicin. These drugs require close monitoring to ensure that the blood concentration remains within the therapeutic range and does not reach toxic levels.

The half-life of a drug is the time taken for its concentration to fall to one half of its value. Drugs with long half-lives may require a loading dose to achieve therapeutic plasma concentrations rapidly. It takes about 4.5 half-lives to reach steady state plasma levels. Most drugs follow first order kinetics, where a constant fraction of the drug in the body is eliminated per unit time. However, some drugs may follow zero order kinetics, where the plasma concentration of the drug decreases at a constant rate, despite the concentration of the drug. For drugs with nonlinear kinetics of dose-dependent kinetics, the relationship between the AUC of CSS and dose is not linear, and the kinetic parameters may vary depending on the administered dose.

Porphyria: The Little Imitator

Porphyria is a medical condition that is often referred to as the little imitator because it can mimic various common psychiatric presentations. This condition can be triggered by the use of certain psychotropic drugs, including barbiturates, benzodiazepines, sulpiride, and some mood stabilizers.

Porphyria can manifest in different ways, and it is important to be aware of the symptoms. These may include abdominal pain, mental state changes, constipation, vomiting, and muscle weakness.

The MHRA categorizes adverse drug reactions into five types. Type A reactions occur when a drug’s normal pharmacological actions are exaggerated at the usual therapeutic dose, and are typically dose-dependent. Type B reactions are unexpected responses that do not align with the drug’s known pharmacological actions. Type C reactions persist for an extended period of time, while Type D reactions become apparent after some time has passed since the medication was used. Finally, Type E reactions are linked to the discontinuation of a medication.

Elevated plasma levels of clozapine have been observed in individuals of Asian ethnicity. Conversely, younger patients, males, and smokers tend to have lower plasma levels. The use of carbamazepine can accelerate the metabolism of clozapine, resulting in decreased serum assay levels. However, it is not recommended to use carbamazepine and clozapine together due to the increased risk of bone marrow suppression.

Pharmacokinetics in Pregnancy

During pregnancy, there are significant changes in maternal physiology that can affect the pharmacokinetics of drugs. These changes are most pronounced in the third trimester. One of the most notable changes is an increase in plasma volume, which can lead to haemodilution and a decrease in the concentration of plasma albumin. As a result, the total plasma concentrations of albumin-bound drugs may decrease during pregnancy. Additionally, lipophilic drugs may have an increased volume of distribution due to the increase in plasma volume.

Progesterone levels are also elevated during pregnancy, which can lead to delayed gastric emptying and reduced small intestine motility. This may affect the absorption of drugs, but the overall impact on bioavailability is likely to be relatively small.

The activity of hepatic drug-metabolizing enzymes can also change during pregnancy. Estrogens and progesterone can induce some CYP enzymes and inhibit others, leading to altered drug metabolism.

Finally, renal blood flow and the glomerular filtration rate increase during pregnancy, which can enhance the elimination of some drugs. The GFR can increase by up to 50% during pregnancy. These changes in pharmacokinetics during pregnancy must be taken into account when prescribing drugs to pregnant women.

Antipsychotic drugs are known to cause weight gain, but some more than others. The reason for this is not due to a direct metabolic effect, but rather an increase in appetite and a decrease in activity levels. The risk of weight gain appears to be linked to clinical response. There are several suggested mechanisms for this, including antagonism of certain receptors and hormones that stimulate appetite. The risk of weight gain varies among different antipsychotics, with clozapine and olanzapine having the highest risk. Management strategies for antipsychotic-induced weight gain include calorie restriction, low glycemic index diet, exercise, and switching to an alternative antipsychotic. Aripiprazole, ziprasidone, and lurasidone are recommended as alternative options. Other options include aripiprazole augmentation, metformin, orlistat, liraglutide, and topiramate.

Loop diuretics and potassium sparing diuretics have been found to have no significant impact on lithium levels, unlike other diuretics. While acetazolamide can decrease lithium levels by increasing excretion, loop diuretics may initially increase excretion followed by a rebound phase of enhanced reabsorption, resulting in no significant effect on lithium levels over a 24-hour period.

Lithium – Pharmacology

Pharmacokinetics:
Lithium salts are rapidly absorbed following oral administration and are almost exclusively excreted by the kidneys unchanged. Blood samples for lithium should be taken 12 hours post-dose.

Ebstein’s:
Ebstein’s anomaly is a congenital malformation consisting of a prolapse of the tricuspid valve into the right ventricle. It occurs in 1:20,000 of the general population. Initial data suggested it was more common in those using lithium but this had not held to be true.

Contraindications:
Addison’s disease, Brugada syndrome, cardiac disease associated with rhythm disorders, clinically significant renal impairment, untreated of untreatable hypothyroidism, low sodium levels.

Side-effects:
Common side effects include nausea, tremor, polyuria/polydipsia, rash/dermatitis, blurred vision, dizziness, decreased appetite, drowsiness, metallic taste, and diarrhea. Side-effects are often dose-related.

Long-term use is associated with hypothyroidism, hyperthyroidism, hypercalcemia/hyperparathyroidism, irreversible nephrogenic diabetes insipidus, and reduced GFR.

Lithium-induced diabetes insipidus:
Treatment options include stopping lithium (if feasible), keeping levels within 0.4-0.8 mmol/L, once-daily dose of the drug taken at bedtime, amiloride, thiazide diuretics, indomethacin, and desmopressin.

Toxicity:
Lithium salts have a narrow therapeutic/toxic ratio. Risk factors for lithium toxicity include drugs altering renal function, decreased circulating volume, infections, fever, decreased oral intake of water, renal insufficiency, and nephrogenic diabetes insipidus. Features of lithium toxicity include GI symptoms and neuro symptoms.

Pre-prescribing:
Before prescribing lithium, renal function, cardiac function, thyroid function, FBC, and BMI should be checked. Women of childbearing age should be advised regarding contraception, and information about toxicity should be provided.

Monitoring:
Lithium blood levels should be checked weekly until stable, and then every 3-6 months once stable. Thyroid and renal function should be checked every 6 months. Patients should be issued with an information booklet, alert card, and record book.

Extrapyramidal side-effects (EPSE’s) are a group of side effects that affect voluntary motor control, commonly seen in patients taking antipsychotic drugs. EPSE’s include dystonias, parkinsonism, akathisia, and tardive dyskinesia. They can be frightening and uncomfortable, leading to problems with non-compliance and can even be life-threatening in the case of laryngeal dystonia. EPSE’s are thought to be due to antagonism of dopaminergic D2 receptors in the basal ganglia. Symptoms generally occur within the first few days of treatment, with dystonias appearing quickly, within a few hours of administration of the first dose. Newer antipsychotics tend to produce less EPSE’s, with clozapine carrying the lowest risk and haloperidol carrying the highest risk. Akathisia is the most resistant EPSE to treat. EPSE’s can also occur when antipsychotics are discontinued (withdrawal dystonia).

The previously assumed higher risk is now uncertain and may not actually exist. We include this question to ensure that you are aware of the past association, as it may still be present in exam materials that have not been revised.

Lithium – Pharmacology

Pharmacokinetics:
Lithium salts are rapidly absorbed following oral administration and are almost exclusively excreted by the kidneys unchanged. Blood samples for lithium should be taken 12 hours post-dose.

Ebstein’s:
Ebstein’s anomaly is a congenital malformation consisting of a prolapse of the tricuspid valve into the right ventricle. It occurs in 1:20,000 of the general population. Initial data suggested it was more common in those using lithium but this had not held to be true.

Contraindications:
Addison’s disease, Brugada syndrome, cardiac disease associated with rhythm disorders, clinically significant renal impairment, untreated of untreatable hypothyroidism, low sodium levels.

Side-effects:
Common side effects include nausea, tremor, polyuria/polydipsia, rash/dermatitis, blurred vision, dizziness, decreased appetite, drowsiness, metallic taste, and diarrhea. Side-effects are often dose-related.

Long-term use is associated with hypothyroidism, hyperthyroidism, hypercalcemia/hyperparathyroidism, irreversible nephrogenic diabetes insipidus, and reduced GFR.

Lithium-induced diabetes insipidus:
Treatment options include stopping lithium (if feasible), keeping levels within 0.4-0.8 mmol/L, once-daily dose of the drug taken at bedtime, amiloride, thiazide diuretics, indomethacin, and desmopressin.

Toxicity:
Lithium salts have a narrow therapeutic/toxic ratio. Risk factors for lithium toxicity include drugs altering renal function, decreased circulating volume, infections, fever, decreased oral intake of water, renal insufficiency, and nephrogenic diabetes insipidus. Features of lithium toxicity include GI symptoms and neuro symptoms.

Pre-prescribing:
Before prescribing lithium, renal function, cardiac function, thyroid function, FBC, and BMI should be checked. Women of childbearing age should be advised regarding contraception, and information about toxicity should be provided.

Monitoring:
Lithium blood levels should be checked weekly until stable, and then every 3-6 months once stable. Thyroid and renal function should be checked every 6 months. Patients should be issued with an information booklet, alert card, and record book.

Torsades de pointes may not be present on an ECG even if the patient experiences recurring episodes, as it has a tendency to appear and disappear.

QTc Prolongation: Risks and Identification

The QT interval is a measure of the time it takes for the ventricles to repolarize and is calculated from the beginning of the QRS complex to the end of the T wave. However, the QT interval varies with the heart rate, making it difficult to use a single number as a cut-off for a prolonged QT. Instead, a corrected QT interval (QTc) is calculated for each heart rate using various formulas. A QTc over the 99th percentile is considered abnormally prolonged, with approximate values of 470 ms for males and 480 ms for females.

Prolonged QT intervals can lead to torsade de pointes (TdP), a polymorphic ventricular tachycardia that can be fatal if it degenerates into ventricular fibrillation. TdP is characterized by a twisting of the QRS complexes around an isoelectric line and is often asymptomatic but can also be associated with syncope and death. An accurate diagnosis requires an ECG to be recorded during the event. It is important to note that an increase in the QT interval due to a new conduction block should not be considered indicative of acquired LQTS and risk for TdP.