The biological response to a drug can only be triggered by the portion of the drug that is not bound.

Drug Distribution in the Body

After being absorbed, drugs can distribute to different parts of the body, such as fat, plasma, muscle, brain tissue, and glands like the thyroid. However, for a drug to have an effect, it must be present in the plasma in an unbound state. This means that the drug molecules are not attached to any other molecules and are free to interact with their target receptors. The concentration of unbound drug in the plasma is what determines the drug’s effectiveness and potential side effects. Therefore, understanding a drug’s distribution in the body is crucial for determining the appropriate dosage and monitoring its effects.

Benzodiazepines have been found to suppress REM sleep and can lead to intense dreams and severe nightmares when discontinued due to a rebound effect. Additionally, they can cause anterograde amnesia, which is the inability to create new memories. While benzodiazepines do not directly induce of inhibit liver enzymes, they are metabolized by CYP3A4, which can be inhibited by certain medications such as SSRIs, erythromycin, and ketoconazole. Flumazenil, a medication used to manage benzodiazepine overdose, has a short half-life and may require repeated doses. However, benzodiazepines are not recommended for the treatment of depression of panic disorder.

Benzodiazepines: Effective but Addictive

Benzodiazepines are a class of drugs that are commonly used to treat anxiety. They are divided into two categories: hypnotics, which have a short half-life, and anxiolytics, which have a long half-life. While they can be effective in reducing anxiety symptoms, they are also highly addictive and should not be prescribed for more than one month at a time.

Benzodiazepines are particularly effective as hypnotics, but they do have some negative effects on sleep. They suppress REM sleep, and when they are discontinued, a rebound effect is often seen. This means that people may experience more vivid dreams and nightmares when they stop taking the medication. It is important for doctors to carefully monitor patients who are taking benzodiazepines to ensure that they are not becoming addicted and that they are not experiencing any negative side effects.

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.

Flumazenil: A Selective GABAA Receptor Antagonist

Flumazenil is a medication that selectively blocks the effects of benzodiazepines on the GABAA receptor. It is used to reverse the sedative effects caused by benzodiazepines, either partially or completely. Flumazenil works by competitively interacting with benzodiazepine receptors, which can reverse the binding of benzodiazepines to these receptors. It is administered intravenously and has a short half-life of about 60 minutes. The effects of flumazenil are usually shorter than those of benzodiazepines, and sedation may recur. Flumazenil also blocks non-benzodiazepine-agonists like zopiclone. However, it has no effect on other drugs such as barbiturates, ethanol, of other GABA-mimetic agents unless they act on the benzodiazepine receptor site. The hypnosedative effects of benzodiazepines are rapidly blocked within 1-2 minutes after intravenous administration, and the duration of action ranges from 20 to 50 minutes.

Clozapine is an atypical antipsychotic drug that acts as an antagonist at various receptors, including dopamine, histamine, serotonin, adrenergic, and cholinergic receptors. It is mainly metabolized by CYP1A2, and its plasma levels can be affected by inducers and inhibitors of this enzyme. Clozapine is associated with several side effects, including drowsiness, constipation, weight gain, and hypersalivation. Hypersalivation is a paradoxical side effect, and its mechanism is not fully understood, but it may involve clozapine agonist activity at the muscarinic M4 receptor and antagonist activity at the alpha-2 adrenoceptor. Clozapine is also associated with several potentially dangerous adverse events, including agranulocytosis, myocarditis, seizures, severe orthostatic hypotension, increased mortality in elderly patients with dementia-related psychosis, colitis, pancreatitis, thrombocytopenia, thromboembolism, and insulin resistance and diabetes mellitus. The BNF advises caution in using clozapine in patients with prostatic hypertrophy, susceptibility to angle-closure glaucoma, and adults over 60 years. Valproate should be considered when using high doses of clozapine, plasma levels > 0.5 mg/l, of when the patient experiences seizures. Myocarditis is a rare but potentially fatal adverse event associated with clozapine use, and its diagnosis is based on biomarkers and clinical features. The mortality rate of clozapine-induced myocarditis is high, and subsequent use of clozapine in such cases leads to recurrence of myocarditis in most cases.

Olanzapine was found to have the highest duration of treatment before discontinuation due to inadequate efficacy, the longest period of successful treatment, and the lowest number of hospitalizations caused by worsening of schizophrenia among the patients.

CATIE Study: Comparing Antipsychotic Medications for Schizophrenia Treatment

The Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE) Study, funded by the National Institute of Mental Health (NIMH), was a nationwide clinical trial that aimed to compare the effectiveness of older and newer antipsychotic medications used to treat schizophrenia. It is the largest, longest, and most comprehensive independent trial ever conducted to examine existing therapies for schizophrenia. The study consisted of two phases.

Phase I of CATIE compared four newer antipsychotic medications to one another and an older medication. Participants were followed for 18 months to evaluate longer-term patient outcomes. The study involved over 1400 participants and was conducted at various treatment sites, representative of real-life settings where patients receive care. The results from CATIE are applicable to a wide range of people with schizophrenia in the United States.

The medications were comparably effective, but high rates of discontinuation were observed due to intolerable side-effects of failure to adequately control symptoms. Olanzapine was slightly better than the other drugs but was associated with significant weight gain as a side-effect. Surprisingly, the older, less expensive medication (perphenazine) used in the study generally performed as well as the four newer medications. Movement side effects primarily associated with the older medications were not seen more frequently with perphenazine than with the newer drugs.

Phase II of CATIE sought to provide guidance on which antipsychotic to try next if the first failed due to ineffectiveness of intolerability. Participants who discontinued their first antipsychotic medication because of inadequate management of symptoms were encouraged to enter the efficacy (clozapine) pathway, while those who discontinued their first treatment because of intolerable side effects were encouraged to enter the tolerability (ziprasidone) pathway. Clozapine was remarkably effective and was substantially better than all the other atypical medications.

The CATIE study also looked at the risk of metabolic syndrome (MS) using the US National Cholesterol Education Program Adult Treatment Panel criteria. The prevalence of MS at baseline in the CATIE group was 40.9%, with female patients being three times as likely to have MS compared to matched controls and male patients being twice as likely.

Due to their increased vulnerability to anticholinergic side effects, elderly individuals are at a higher risk of experiencing delirium. The first generation of H1 antihistamines, which have a greater tendency for anticholinergic side effects, are more likely to trigger delirium in the elderly. Benadryl, an over-the-counter medication in the UK used to treat hay fever, contains diphenhydramine as its active ingredient.

Antihistamines: Types and Uses

Antihistamines are drugs that block the effects of histamine, a neurotransmitter that regulates physiological function in the gut and potentiates the inflammatory and immune responses of the body. There are two types of antihistamines: H1 receptor blockers and H2 receptor blockers. H1 blockers are mainly used for allergic conditions and sedation, while H2 blockers are used for excess stomach acid.

There are also first and second generation antihistamines. First generation antihistamines, such as diphenhydramine and promethazine, have uses in psychiatry due to their ability to cross the blood brain barrier and their anticholinergic properties. They tend to be sedating and are useful for managing extrapyramidal side effects. Second generation antihistamines, such as loratadine and cetirizine, show limited penetration of the blood brain barrier and are less sedating.

It is important to note that there are contraindications to first-generation antihistamines, including benign prostatic hyperplasia, angle-closure glaucoma, and pyloric stenosis in infants. These do not apply to second-generation antihistamines.

Drug Clearance: Understanding the Rate of Drug Removal from the Body

Drug clearance refers to the efficiency of drug removal from the plasma, and is measured as the volume of plasma cleared of a drug over a specific time period. The unit of measurement for drug clearance is volume per time. Clearance of a drug involves both metabolism and excretion. When drug intake equals clearance, it is referred to as a steady state, which is usually achieved by 4.5 half-lives. The time taken to reach steady state depends on the half-life of the drug.

There are two main types of clearance: hepatic and renal. Hepatic clearance involves the conversion of the parent drug into a different chemical entity by the liver enzymes, while renal clearance involves the removal of the drug from the plasma into the urine. The clearance of a drug can take one of two forms: zero and first-order kinetics. In zero-order reactions, the clearance of a drug is constant and not related to the concentration of the drug in the plasma. This type of reaction is typically found when the material needed for the reaction to proceed (e.g. enzyme) is saturated. Ethanol and Phenytoin are good examples of this.

Most drugs tend to follow first-order reactions, where the clearance is related to the concentration of the drug in the plasma. The half-life of a drug is the time taken for its concentration to fall by half. In first-order reactions, this is constant. In zero-order reactions, it gets progressively shorter.

It is important to note that elimination and clearance are not the same. Elimination is the irreversible removal of the drug from the body, while clearance is a theoretical volume of blood that is cleared of the drug per unit of time, which is independent of the drug dose of concentration. Understanding drug clearance is crucial in determining the appropriate dosing regimen for a drug.

CYP1A2 is responsible for metabolizing caffeine, and it competes with other drugs that are also metabolized by this enzyme. When caffeine is consumed excessively, it can deplete the CYP1A2, leaving none available to metabolize clozapine, resulting in increased levels of clozapine. However, this is not a common issue in clinical settings.

The Cytochrome P450 system is a group of enzymes that metabolize drugs by altering their functional groups. The system is located in the liver and small intestine and is involved in drug interactions through enzyme induction of inhibition. Notable inducers include smoking, alcohol, and St John’s Wort, while notable inhibitors include grapefruit juice and some SSRIs. CYP2D6 is important due to genetic polymorphism, and CYP3A4 is the most abundant subfamily and is commonly involved in interactions. Grapefruit juice inhibits both CYP1A2 and CYP3A4, while tobacco smoking induces CYP1A2. The table summarizes the main substrates, inhibitors, and inducers for each CYP enzyme.

Hyponatremia in Psychiatric Patients

Hyponatremia, of low serum sodium, can occur in psychiatric patients due to the disorder itself, its treatment, of other medical conditions. Symptoms include nausea, confusion, seizures, and muscular cramps. Drug-induced hyponatremia is known as the syndrome of inappropriate antidiuretic hormone hypersecretion (SIADH), which results from excessive secretion of ADH and fluid overload. Diagnosis is based on clinically euvolaemic state with low serum sodium and osmolality, raised urine sodium and osmolality. SSRIs, SNRIs, and tricyclics are the most common drugs that can cause SIADH. Risk factors for SIADH include starting a new drug, and treatment usually involves fluid restriction and sometimes demeclocycline.

Pregabalin: Pharmacokinetics and Mechanism of Action

Pregabalin is a medication that acts on the alpha-2-delta subunit of voltage-gated calcium channels in the central nervous system. It is known for its anticonvulsant, analgesic, and anxiolytic properties. By decreasing presynaptic calcium currents, it reduces the release of excitatory neurotransmitters that contribute to anxiety. Despite being a GABA analogue, it does not affect GABA receptors of metabolism.

Pregabalin has predictable and linear pharmacokinetics, making it easy to use in clinical practice. It is rapidly absorbed and proportional to dose, with a time to maximal plasma concentration of approximately 1 hour. Steady state is achieved within 24-48 hours, and efficacy can be observed as early as day two in clinical trials. It has a high bioavailability and a mean elimination half-life of 6.3 hours.

Unlike many medications, pregabalin is not subject to hepatic metabolism and does not induce of inhibit liver enzymes such as the cytochrome P450 system. It is excreted unchanged by the kidneys and does not bind to plasma proteins. This means that it is unlikely to cause of be affected by pharmacokinetic drug-drug interactions.

While there is some potential for abuse of pregabalin, the euphoric effects disappear with prolonged use. Overall, pregabalin is a safe and effective medication for the treatment of various conditions, including anxiety and neuropathic pain.

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.

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.

A drug’s half-life is an estimation of the time it takes for the drug’s initial concentration in the body to decrease by half. For example, if a drug’s half-life is 4 hours and the initial concentration is 160 mg, it’s estimated that 80 mg will remain after 4 hours.

Other important pharmacokinetic values include the volume of distribution, which is the apparent volume that contains the drug, concentration, which is the amount of drug per unit volume, elimination rate constant, which is the rate at which the drug is removed from the body, and clearance, which is the volume of blood cleared of the drug per unit time. When the overall intake of a drug is equal to the rate of elimination, this is known as steady state, which is typically achieved after approximately 4-5 half life times.

Macrocytic anaemia is the type that is commonly associated with valproate.

Valproate: Forms, Doses, and Adverse Effects

Valproate comes in three forms: semi-sodium valproate, valproic acid, and sodium valproate. Semi-sodium valproate is a mix of sodium valproate and valproic acid and is licensed for acute mania associated with bipolar disorder. Valproic acid is also licensed for acute mania, but this is not consistent with the Maudsley Guidelines. Sodium valproate is licensed for epilepsy. It is important to note that doses of sodium valproate and semi-sodium valproate are not the same, with a slightly higher dose required for sodium valproate.

Valproate is associated with many adverse effects, including nausea, tremor, liver injury, vomiting/diarrhea, gingival hyperplasia, memory impairment/confusional state, somnolence, weight gain, anaemia/thrombocytopenia, alopecia (with curly regrowth), severe liver damage, and pancreatitis. Increased liver enzymes are common, particularly at the beginning of therapy, and tend to be transient. Vomiting and diarrhea tend to occur at the start of treatment and remit after a few days. Severe liver damage is most likely to occur in the first six months of therapy, with the maximum risk being between two and twelve weeks. The risk also declines with advancing age.

Valproate is a teratogen and should not be initiated in women of childbearing potential. Approximately 10% of children exposed to valproate monotherapy during pregnancy suffer from congenital malformations, with the risk being dose-dependent. The most common malformations are neural tube defects, facial dysmorphism, cleft lip and palate, craniostenosis, cardiac, renal and urogenital defects, and limb defects. There is also a dose-dependent relationship between valproate and developmental delay, with approximately 30-40% of children exposed in utero experiencing delay in their early development, such as talking and walking later, lower intellectual abilities, poor language skills, and memory problems. There is also a thought to be a 3-fold increase of autism in children exposed in utero.

Hyponatremia in Psychiatric Patients

Hyponatremia, of low serum sodium, can occur in psychiatric patients due to the disorder itself, its treatment, of other medical conditions. Symptoms include nausea, confusion, seizures, and muscular cramps. Drug-induced hyponatremia is known as the syndrome of inappropriate antidiuretic hormone hypersecretion (SIADH), which results from excessive secretion of ADH and fluid overload. Diagnosis is based on clinically euvolaemic state with low serum sodium and osmolality, raised urine sodium and osmolality. SSRIs, SNRIs, and tricyclics are the most common drugs that can cause SIADH. Risk factors for SIADH include starting a new drug, and treatment usually involves fluid restriction and sometimes demeclocycline.

Clozapine is an atypical antipsychotic drug that acts as an antagonist at various receptors, including dopamine, histamine, serotonin, adrenergic, and cholinergic receptors. It is mainly metabolized by CYP1A2, and its plasma levels can be affected by inducers and inhibitors of this enzyme. Clozapine is associated with several side effects, including drowsiness, constipation, weight gain, and hypersalivation. Hypersalivation is a paradoxical side effect, and its mechanism is not fully understood, but it may involve clozapine agonist activity at the muscarinic M4 receptor and antagonist activity at the alpha-2 adrenoceptor. Clozapine is also associated with several potentially dangerous adverse events, including agranulocytosis, myocarditis, seizures, severe orthostatic hypotension, increased mortality in elderly patients with dementia-related psychosis, colitis, pancreatitis, thrombocytopenia, thromboembolism, and insulin resistance and diabetes mellitus. The BNF advises caution in using clozapine in patients with prostatic hypertrophy, susceptibility to angle-closure glaucoma, and adults over 60 years. Valproate should be considered when using high doses of clozapine, plasma levels > 0.5 mg/l, of when the patient experiences seizures. Myocarditis is a rare but potentially fatal adverse event associated with clozapine use, and its diagnosis is based on biomarkers and clinical features. The mortality rate of clozapine-induced myocarditis is high, and subsequent use of clozapine in such cases leads to recurrence of myocarditis in most cases.

Blurred vision occurs as a result of muscarinic blockade, which causes the pupils to dilate (mydriasis).

Receptors and Side-Effects

Histamine H1 Blockade:
– Weight gain
– Sedation

Alpha 1 Blockade:
– Orthostatic hypotension
– Sedation
– Sexual dysfunction
– Priapism

Muscarinic Central M1 Blockade:
– Agitation
– Delirium
– Memory impairment
– Confusion
– Seizures

Muscarinic Peripheral M1 Blockade:
– Dry mouth
– Ataxia
– Blurred vision
– Narrow angle glaucoma
– Constipation
– Urinary retention
– Tachycardia

Each receptor has specific effects on the body, but they can also have side-effects. Histamine H1 blockade can cause weight gain and sedation. Alpha 1 blockade can lead to orthostatic hypotension, sedation, sexual dysfunction, and priapism. Muscarinic central M1 blockade can cause agitation, delirium, memory impairment, confusion, and seizures. Muscarinic peripheral M1 blockade can result in dry mouth, ataxia, blurred vision, narrow angle glaucoma, constipation, urinary retention, and tachycardia. It is important to be aware of these potential side-effects when using medications that affect these receptors.

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).

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.

The time course of drug concentration in various body parts is described and predicted by pharmacokinetics, while pharmacodynamics is used to describe the intensity and time course of a drug’s effects. Pharmacological actions encompass genetic and environmental factors that affect an individual’s response to and tolerance of psychotropic agents. The mechanism of drugs’ therapeutic effects is described as how they are produced.

The UK market no longer offers thioridazine and droperidol due to their impact on the QTc interval.

Amantadine and QTc Prolongation

Amantadine is a medication used to treat Parkinson’s disease and influenza. It has been associated with QTc prolongation, which can increase the risk of Torsades de points. Therefore, caution should be exercised when prescribing amantadine to patients with risk factors for QT prolongation. If a patient is already taking amantadine and develops a prolonged QTc interval, the medication should be discontinued and an alternative treatment considered. It is important to monitor the QTc interval in patients taking amantadine, especially those with risk factors for QT prolongation.

The Bazett formula adjusts the QT interval for heart rate by taking the square root of the R-R interval and dividing the QT interval by it.

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.

Antipsychotics can be classified in different ways, with the most common being typical (first generation) and atypical (second generation) types. Typical antipsychotics block dopamine (D2) receptors and have varying degrees of M1, Alpha-1, and H1 receptor blockade. Atypical antipsychotics have a lower propensity for extrapyramidal side-effects and are attributed to the combination of relatively lower D2 antagonism with 5HT2A antagonism. They are also classified by structure, with examples including phenothiazines, butyrophenones, thioxanthenes, diphenylbutylpiperidine, dibenzodiazepines, benzoxazoles, thienobenzodiazepine, substituted benzamides, and arylpiperidylindole (quinolone). Studies have found little evidence to support the superiority of atypicals over typicals in terms of efficacy, discontinuation rates, of adherence, with the main difference being the side-effect profile. The Royal College also favors classification by structure.

Antiemetic Properties of Antipsychotics

Antipsychotics are commonly used in palliative care to prevent nausea and vomiting. Chlorpromazine and haloperidol are two antipsychotics that have been found to be effective antiemetics. Chlorpromazine works by blocking histamine receptors, while haloperidol blocks dopamine receptors in the chemoreceptor trigger zone (CTZ), which influences the vomiting center. Promazine is also a potent histamine antagonist but is not commonly used as an antiemetic. However, both chlorpromazine and promazine have sedative effects.

Pimozide, on the other hand, has low affinity for histamine receptors, and pericyazine demonstrates moderate affinity. Flupenthixol is not used as an antiemetic. Overall, antipsychotics have proven to be effective in preventing nausea and vomiting in palliative care, with different mechanisms of action depending on the specific drug.

The First Pass Effect in Psychiatric Drugs

The first-pass effect is a process in drug metabolism that significantly reduces the concentration of a drug before it reaches the systemic circulation. This phenomenon is related to the liver and gut wall, which absorb and metabolize the drug before it can enter the bloodstream. Psychiatric drugs are not exempt from this effect, and some undergo a significant reduction in concentration before reaching their target site. Examples of psychiatric drugs that undergo a significant first-pass effect include imipramine, fluphenazine, morphine, diazepam, and buprenorphine. On the other hand, some drugs undergo little to no first-pass effect, such as lithium and pregabalin.

Orally administered drugs are the most affected by the first-pass effect. However, there are other routes of administration that can avoid of partly avoid this effect. These include sublingual, rectal (partly avoids first pass), intravenous, intramuscular, transdermal, and inhalation. Understanding the first-pass effect is crucial in drug development and administration, especially in psychiatric drugs, where the concentration of the drug can significantly affect its efficacy and safety.

Agomelatine: A New Drug for Depression Treatment

Agomelatine is a recently developed medication that is used to treat depression. Its mechanism of action involves acting as an agonist at melatonin M1 and M2 receptors, while also acting as an antagonist at 5HT2C receptors. The effects of melatonin appear to promote sleep, while the 5HT2C antagonism leads to the release of dopamine and norepinephrine in the frontal cortex. Interestingly, serotonin levels do not appear to be affected by this medication.

Antidepressants and Their Cardiac Effects

SSRIs are generally recommended for patients with cardiac disease as they may protect against myocardial infarction (MI). Untreated depression worsens prognosis in cardiovascular disease. Post MI, SSRIs and mirtazapine have either a neutral of beneficial effect on mortality. Sertraline is recommended post MI, but other SSRIs and mirtazapine are also likely to be safe. However, citalopram is associated with Torsades de pointes (mainly in overdose). Bupropion, citalopram, escitalopram, moclobemide, lofepramine, and venlafaxine should be used with caution of avoided in those at risk of serious arrhythmia (those with heart failure, left ventricular hypertrophy, previous arrhythmia, of MI).

Tricyclic antidepressants (TCAs) have established arrhythmogenic activity which arises as a result of potent blockade of cardiac sodium channels and variable activity at potassium channels. ECG changes produced include PR, QRS, and QT prolongation and the Brugada syndrome. Lofepramine is less cardiotoxic than other TCAs and seems to lack the overdose arrhythmogenicity of other TCAs. QT changes are not usually seen at normal clinical doses of antidepressants (but can occur, particularly with citalopram/escitalopram). The arrhythmogenic potential of TCAs and other antidepressants is dose-related.

Overall, SSRIs are recommended for patients with cardiac disease, while caution should be exercised when prescribing TCAs and other antidepressants, especially in those at risk of serious arrhythmia. It is important to monitor patients closely for any cardiac effects when prescribing antidepressants.

Hyperprolactinemia is a potential side effect of antipsychotic medication, but it is rare with antidepressants. Dopamine inhibits prolactin, so dopamine antagonists, such as antipsychotics, can increase prolactin levels. The degree of prolactin elevation is dose-related, and some antipsychotics cause more significant increases than others. Hyperprolactinemia can cause symptoms such as galactorrhea, menstrual difficulties, gynecomastia, hypogonadism, and sexual dysfunction. Long-standing hyperprolactinemia in psychiatric patients can increase the risk of osteoporosis and breast cancer, although there is no conclusive evidence that antipsychotic medication increases the risk of breast malignancy and mortality. Some antipsychotics, such as clozapine and aripiprazole, have a low risk of causing hyperprolactinemia, while typical antipsychotics and risperidone have a high risk. Monitoring of prolactin levels is recommended before starting antipsychotic therapy and at three months and annually thereafter. Antidepressants rarely cause hyperprolactinemia, and routine monitoring is not recommended. Symptomatic hyperprolactinemia has been reported with most antidepressants, except for a few, such as mirtazapine, agomelatine, bupropion, and vortioxetine.

Prescribing in the Elderly: Iatrogenic Consequences

Many medications, both prescribed and over-the-counter, can have significant adverse effects in the elderly population. It is important to note that the lists provided below are not exhaustive, and only the most common and important examples are given.

Medications Linked to Delirium and Other Cognitive Disorders

Medications are the most common reversible cause of delirium and dementia in the elderly. Many medications can cause cognitive impairment, but the classes of drugs most strongly associated with the development of drug-induced dementia are opioids, benzodiazepines, and anticholinergics.

According to a systematic review done in 2011 (Clegg, 2011), long-acting benzodiazepines (e.g., diazepam) are more troublesome than those that are shorter-acting. Opioids are associated with an approximately 2-fold increased risk of delirium in medical and surgical patients (Clegg, 2011). Pethidine appears to have a higher risk of delirium compared with other members of the opioid class. This may be because pethidine can accumulate when renal function is impaired and is converted to a metabolite with anticholinergic properties.

Some antipsychotic drugs have considerable antimuscarinic (anticholinergic) activity (e.g., chlorpromazine and clozapine), which may cause of worsen delirium. Delirium is uncommon in newer antipsychotics (but has been reported).

Medications Linked to Mood Changes

The following medications are well known to precipitate mood changes:

– Centrally-acting antihypertensives (e.g., methyldopa, reserpine, and clonidine) can cause depressive symptoms.
– Interferon-a is capable of inducing depressive symptoms.
– Digoxin is capable of inducing depressive symptoms.
– Corticosteroids can cause depressive, manic, and mixed symptoms with of without psychosis.
– Antidepressants can precipitate mania.

Medications Linked to Psychosis

The following medications are well known to precipitate psychosis:

– Anti-Parkinson’s Medications (e.g., bromocriptine, amantadine, selegiline, anticholinergics (e.g., trihexyphenidyl, benztropine, benzhexol), and levodopa).
– Corticosteroids

Medications Linked to Anxiety

The following medications are well known to precipitate anxiety:

– Stimulants
– β adrenergic inhalers

Opioid Pharmacology and Treatment Medications

Opioids work by binding to opioid receptors in the brain, specifically the µ, k, and δ receptors. The µ receptor is the main target for opioids and mediates euphoria, respiratory depression, and dependence. Dopaminergic cells in the ventral tegmental area produce dopamine, which is released into the nucleus accumbens upon stimulation of µ receptors, leading to the reward and euphoria that drives repeated use. However, with repeated exposure, µ receptors become less responsive, leading to dysphoria and drug craving.

There are several medications used in opioid treatment. Methadone is a full agonist targeting µ receptors, with some action against k and δ receptors, and has a half-life of 15-22 hours. However, it carries a risk of respiratory depression, especially when used with hypnotics and alcohol. Buprenorphine is a partial agonist targeting µ receptors, as well as a partial k agonist of functional antagonist and a weak δ antagonist. It has a high affinity for µ receptors and a longer half-life of 24-42 hours, making it safer than methadone. Naloxone is an antagonist targeting all opioid receptors and is used to reverse opioid overdose, with a half-life of 30-120 minutes. However, it can cause noncardiogenic pulmonary edema in some cases. Naltrexone is a reversible competitive antagonist at µ and ĸ receptors, with a half-life of 4-6 hours, and is used as an adjunctive prophylactic treatment for detoxified formerly opioid-dependent people.

Alpha2 adrenergic agonists, such as clonidine and lofexidine, can ameliorate opioid withdrawal symptoms associated with the noradrenaline system, including sweating, shivering, and runny nose and eyes. The locus coeruleus, a nucleus in the pons with a high density of noradrenergic neurons possessing µ-opioid receptors, is involved in wakefulness, blood pressure, breathing, and overall alertness. Exposure to opioids results in heightened neuronal activity of the nucleus cells, and if opioids are not present to suppress this activity, increased amounts of norepinephrine are released, leading to withdrawal symptoms. Clonidine was originally developed as an antihypertensive, but its antihypertensive effects are problematic in detox, so lofexidine was developed as an alternative with less hypotensive effects.

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).

In certain cases, the addition of 5-10 mg of aripiprazole has demonstrated the ability to restore hyperprolactinaemia to normal levels.

Antipsychotics and Sexual Dysfunction: Causes, Risks, and Management

Sexual dysfunction is a common side effect of antipsychotic medication, with the highest risk associated with risperidone and haloperidol due to their effect on prolactin levels. Clozapine, olanzapine, quetiapine, aripiprazole, asenapine, and lurasidone are associated with lower rates of sexual dysfunction. The Arizona Sexual Experiences Scale (ASEX) can be used to measure sexual dysfunction before and during treatment. Management options include excluding other causes, watchful waiting, dose reduction, switching to a lower risk agent, adding aripiprazole, considering an antidote medication, of using sildenafil for erectile dysfunction. It is important to address sexual dysfunction to improve quality of life and medication adherence.

Amphetamine engages in competition with the DAT instead of obstructing it.

Mechanisms of action for illicit drugs can be classified based on their effects on ionotropic receptors of ion channels, G coupled receptors, of monoamine transporters. Cocaine and amphetamine both increase dopamine levels in the synaptic cleft, but through different mechanisms. Cocaine directly blocks the dopamine transporter, while amphetamine binds to the transporter and increases dopamine efflux through various mechanisms, including inhibition of vesicular monoamine transporter 2 and monoamine oxidase, and stimulation of the intracellular receptor TAAR1. These mechanisms result in increased dopamine levels in the synaptic cleft and reuptake inhibition.

Sertraline is the preferred medication for treating post-MI depression as it has minimal impact on heart rate, blood pressure, and the QTc interval. Tricyclics are not recommended due to their potential to cause postural hypotension, increased heart rate, and QTc interval prolongation. Fluoxetine may be used with caution as it has a slight effect on heart rate but does not significantly affect blood pressure of the QTc interval. Trazodone should be used with care as it can cause significant postural hypotension and QTc interval prolongation in post-MI patients. Venlafaxine should be avoided in these patients as it can increase blood pressure, particularly at higher doses.

While the majority of SSRIs are believed to have minimal impact on the QTc interval, studies have demonstrated that citalopram and escitalopram can lead to QTc prolongation.

Antidepressants and Their Cardiac Effects

SSRIs are generally recommended for patients with cardiac disease as they may protect against myocardial infarction (MI). Untreated depression worsens prognosis in cardiovascular disease. Post MI, SSRIs and mirtazapine have either a neutral of beneficial effect on mortality. Sertraline is recommended post MI, but other SSRIs and mirtazapine are also likely to be safe. However, citalopram is associated with Torsades de pointes (mainly in overdose). Bupropion, citalopram, escitalopram, moclobemide, lofepramine, and venlafaxine should be used with caution of avoided in those at risk of serious arrhythmia (those with heart failure, left ventricular hypertrophy, previous arrhythmia, of MI).

Tricyclic antidepressants (TCAs) have established arrhythmogenic activity which arises as a result of potent blockade of cardiac sodium channels and variable activity at potassium channels. ECG changes produced include PR, QRS, and QT prolongation and the Brugada syndrome. Lofepramine is less cardiotoxic than other TCAs and seems to lack the overdose arrhythmogenicity of other TCAs. QT changes are not usually seen at normal clinical doses of antidepressants (but can occur, particularly with citalopram/escitalopram). The arrhythmogenic potential of TCAs and other antidepressants is dose-related.

Overall, SSRIs are recommended for patients with cardiac disease, while caution should be exercised when prescribing TCAs and other antidepressants, especially in those at risk of serious arrhythmia. It is important to monitor patients closely for any cardiac effects when prescribing antidepressants.

A lack of vitamin C is commonly linked to gum inflammation and bleeding.

Thiamine Deficiency and Alcohol-Related Brain Disease

Thiamine deficiency is a well-known cause of a neurological disorder called Wernicke-Korsakoff syndrome (WKS) in individuals with alcohol use disorder. Thiamine, also known as vitamin B1, is an essential nutrient that cannot be produced by the body and must be obtained through the diet. Thiamine is required for the proper functioning of enzymes involved in the metabolism of carbohydrates, the synthesis of neurotransmitters, nucleic acids, fatty acids, and complex sugar molecules, and the body’s defense against oxidative stress.

Three enzymes that require thiamine as a cofactor are transketolase, pyruvate dehydrogenase (PDH), and alpha ketoglutarate dehydrogenase (KGDH), all of which participate in the breakdown of carbohydrates. Thiamine deficiency leads to suboptimal levels of functional enzymes in the cell, which can cause cell damage in the central nervous system through cell necrosis, cellular apoptosis, and oxidative stress.

Alcoholism can contribute to thiamine deficiency through inadequate nutritional intake, decreased absorption of thiamine from the gastrointestinal tract, and impaired utilization of thiamine in the cells. Giving thiamine to patients with WKS can reverse many of the acute symptoms of the disease, highlighting the importance of this nutrient in the prevention and treatment of alcohol-related brain disease.

The second generation of H1 antihistamines exhibit limited ability to cross the blood-brain barrier, leading to their non-sedating properties. Furthermore, they possess greater receptor specificity and do not produce significant anticholinergic effects. These characteristics make them a more desirable option for managing allergic conditions, as they minimize the risk of adverse effects.

Antihistamines: Types and Uses

Antihistamines are drugs that block the effects of histamine, a neurotransmitter that regulates physiological function in the gut and potentiates the inflammatory and immune responses of the body. There are two types of antihistamines: H1 receptor blockers and H2 receptor blockers. H1 blockers are mainly used for allergic conditions and sedation, while H2 blockers are used for excess stomach acid.

There are also first and second generation antihistamines. First generation antihistamines, such as diphenhydramine and promethazine, have uses in psychiatry due to their ability to cross the blood brain barrier and their anticholinergic properties. They tend to be sedating and are useful for managing extrapyramidal side effects. Second generation antihistamines, such as loratadine and cetirizine, show limited penetration of the blood brain barrier and are less sedating.

It is important to note that there are contraindications to first-generation antihistamines, including benign prostatic hyperplasia, angle-closure glaucoma, and pyloric stenosis in infants. These do not apply to second-generation antihistamines.

Hepatic Impairment: Recommended Drugs

Patients with hepatic impairment may experience reduced ability to metabolize drugs, toxicity, enhanced dose-related side effects, reduced ability to synthesize plasma proteins, and elevated levels of drugs subject to first-pass metabolism due to reduced hepatic blood flow. The Maudsley Guidelines 14th Ed recommends the following drugs for patients with hepatic impairment:

Antipsychotics: Paliperidone (if depot required), Amisulpride, Sulpiride

Antidepressants: Sertraline, Citalopram, Paroxetine, Vortioxetine (avoid TCA and MAOI)

Mood stabilizers: Lithium

Sedatives: Lorazepam, Oxazepam, Temazepam, Zopiclone 3.75mg (with care)

Although many drugs are metabolized by CYP1A2, grapefruit juice does not have a significant effect on the metabolism of lithium, as the majority of lithium is excreted without undergoing significant metabolic changes.

The Cytochrome P450 system is a group of enzymes that metabolize drugs by altering their functional groups. The system is located in the liver and small intestine and is involved in drug interactions through enzyme induction of inhibition. Notable inducers include smoking, alcohol, and St John’s Wort, while notable inhibitors include grapefruit juice and some SSRIs. CYP2D6 is important due to genetic polymorphism, and CYP3A4 is the most abundant subfamily and is commonly involved in interactions. Grapefruit juice inhibits both CYP1A2 and CYP3A4, while tobacco smoking induces CYP1A2. The table summarizes the main substrates, inhibitors, and inducers for each CYP enzyme.

Oxazepam is a significant metabolite found in various benzodiazepines, but it does not produce any significant metabolites of its own. It is occasionally prescribed to individuals with liver impairment because it does not necessitate hepatic oxidation and is instead metabolized through glucuronidation (which is often preserved even in severe liver disease).

The Significance of Active Metabolites in Drug Discovery and Development

Certain drugs are classified as prodrugs, which means that they are inactive when administered and require metabolism to become active. These drugs are converted into an active form, which is referred to as an active metabolite. Some drugs have important active metabolites, such as diazepam, dothiepin, fluoxetine, imipramine, risperidone, amitriptyline, and codeine, which are desmethyldiazepam, dothiepin sulfoxide, norfluoxetine, desipramine, 9-hydroxyrisperidone, nortriptyline, and morphine, respectively.

The role of pharmacologically active metabolites in drug discovery and development is significant. Understanding the active metabolites of a drug can help in the development of more effective and safer drugs. Active metabolites can also provide insights into the pharmacokinetics and pharmacodynamics of a drug, which can aid in the optimization of dosing regimens. Additionally, active metabolites can have different pharmacological properties than the parent drug, which can lead to the discovery of new therapeutic uses for a drug. Therefore, the study of active metabolites is an important aspect of drug discovery and development.

Modafinil shares similarities in its mechanism of action with amphetamine, and its effects are relatively brief with a half-life of approximately 8-12 hours. Additionally, the side effects of modafinil are comparable to those of amphetamine.

Modafinil: A Psychostimulant for Wakefulness and Attention Enhancement

Modafinil is a type of psychostimulant that is known to improve wakefulness, attention, and vigilance. Although it is similar to amphetamines, it does not produce the same euphoric effects and is not associated with dependence of tolerance. Additionally, it does not seem to cause psychosis. Modafinil is approved for the treatment of narcolepsy, obstructive sleep apnea, and chronic shift work. It is also suggested as an adjunctive treatment for depression by the Maudsley. Recently, it has gained popularity as a smart drug due to its potential to enhance cognitive functioning in healthy individuals.

Benzodiazepines and Z-drugs (such as zopiclone and zolpidem) have a common mechanism of action on the GABA receptor. It is noteworthy that alcohol also affects this receptor, which explains the similar effects observed in alcohol and benzodiazepine use. Additionally, benzodiazepines play a role in managing alcohol withdrawal symptoms.

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.

Antipsychotics can be classified in various ways, including by chemical structure and generation. The two main generations are typical (first generation) and atypical (second generation) antipsychotics. Risperidone is an atypical antipsychotic and belongs to the benzisoxazole class. It works as an antagonist for dopamine D2, 5-HT 2a, histamine-1 receptor, and alpha 1-adrenoceptor. Other antipsychotics belong to different structural categories, such as butyrophenones (e.g. haloperidol), dibenzodiazapines (e.g. clozapine), dibenzothiazapines (e.g. quetiapine), Thienobenzodiazepine (e.g. olanzapine), phenothiazines (e.g. chlorpromazine, trifluoperazine, thioridazine), thioxanthenes (e.g. flupentixol), diphenylbutylpiperidine (e.g. pimozide), substituted benzamides (e.g. sulpiride), and arylpiperidylindole (quinolone) (e.g. aripiprazole).

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.

Pregabalin: Pharmacokinetics and Mechanism of Action

Pregabalin is a medication that acts on the alpha-2-delta subunit of voltage-gated calcium channels in the central nervous system. It is known for its anticonvulsant, analgesic, and anxiolytic properties. By decreasing presynaptic calcium currents, it reduces the release of excitatory neurotransmitters that contribute to anxiety. Despite being a GABA analogue, it does not affect GABA receptors of metabolism.

Pregabalin has predictable and linear pharmacokinetics, making it easy to use in clinical practice. It is rapidly absorbed and proportional to dose, with a time to maximal plasma concentration of approximately 1 hour. Steady state is achieved within 24-48 hours, and efficacy can be observed as early as day two in clinical trials. It has a high bioavailability and a mean elimination half-life of 6.3 hours.

Unlike many medications, pregabalin is not subject to hepatic metabolism and does not induce of inhibit liver enzymes such as the cytochrome P450 system. It is excreted unchanged by the kidneys and does not bind to plasma proteins. This means that it is unlikely to cause of be affected by pharmacokinetic drug-drug interactions.

While there is some potential for abuse of pregabalin, the euphoric effects disappear with prolonged use. Overall, pregabalin is a safe and effective medication for the treatment of various conditions, including anxiety and neuropathic pain.

Taste disturbance is known as Dysgeusia in medical terminology and can be caused by various medications. Lithium is a frequently encountered culprit, but other drugs such as certain antidepressants, benzodiazepines, z-drugs, and opiates can also lead to this condition. Additionally, any medication that causes dry mouth may result in taste disturbance. This information is sourced from D Kaufman’s book, Clinical neurology for psychiatrists, published in 2007 on page 38.

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.

Antipsychotics can be classified in different ways, with the most common being typical (first generation) and atypical (second generation) types. Typical antipsychotics block dopamine (D2) receptors and have varying degrees of M1, Alpha-1, and H1 receptor blockade. Atypical antipsychotics have a lower propensity for extrapyramidal side-effects and are attributed to the combination of relatively lower D2 antagonism with 5HT2A antagonism. They are also classified by structure, with examples including phenothiazines, butyrophenones, thioxanthenes, diphenylbutylpiperidine, dibenzodiazepines, benzoxazoles, thienobenzodiazepine, substituted benzamides, and arylpiperidylindole (quinolone). Studies have found little evidence to support the superiority of atypicals over typicals in terms of efficacy, discontinuation rates, of adherence, with the main difference being the side-effect profile. The Royal College also favors classification by structure.

If there are no T wave abnormalities on the ECG, the Maudsley guidelines deem a QTc of 460 ms acceptable for women.

Amantadine and QTc Prolongation

Amantadine is a medication used to treat Parkinson’s disease and influenza. It has been associated with QTc prolongation, which can increase the risk of Torsades de points. Therefore, caution should be exercised when prescribing amantadine to patients with risk factors for QT prolongation. If a patient is already taking amantadine and develops a prolonged QTc interval, the medication should be discontinued and an alternative treatment considered. It is important to monitor the QTc interval in patients taking amantadine, especially those with risk factors for QT prolongation.