A factor that is likely to increase the duration of action of a drug that is partially metabolized by CYP3A4 in the liver is:

Chronic administration of cimetidine with the drug

Chronic administration of phenobarbital with the drug

Displacement from tissue binding sites by another drug

Chronic administration of rifampicin

All of the following statements regarding the bioavailability of a drug are true except which one?

Low oral availability always and necessarily means poor absorption

It is a fraction of administered drug that reaches the systemic circulation in unchanged form

Bioavailability can be determined from plasma concentration or urinary excretion data.

Bioavailability of an orally administered drug can be calculated by comparing the Area Under Curve after oral and intravenous administration

Pharmacokinetics and Pharmacodynamics for FMGE: High-Yield Psychiatry Lessons

PK vs PD Fundamentals - Drug's Journey & Impact

Pharmacokinetics (PK): Body's action on drug. "What the body does to the drug."
- 📌 ADME: Absorption, Distribution, Metabolism, Excretion.
- Key parameters: Bioavailability (F), Volume of distribution ($V_d$), Clearance (CL), Half-life ($t_{1/2}$).
Pharmacodynamics (PD): Drug's action on body. "What the drug does to the body."
- Receptor interactions: Agonists, antagonists.
- Dose-Response: Efficacy ($E_{max}$), Potency ($ED_{50}$).

⭐ First-pass metabolism significantly reduces the bioavailability of orally administered drugs like lignocaine or propranolol.

Pharmacokinetics (ADME) - Body's Drug Maze

📌 ADME: Absorption, Distribution, Metabolism, Excretion.

Absorption: Drug movement from administration site to bloodstream.
- Bioavailability (F): Fraction reaching circulation. $F = \text{AUC}\text{oral} / \text{AUC}\text{IV}$. IV $F = \mathbf{100}%$.
- First-pass metabolism (liver) ↓ F for oral drugs.
Distribution: Reversible transfer of drug from blood to tissues/organs.
- Volume of Distribution ($V_d$): $V_d = \text{Dose} / C_0$.
- Influenced by lipid solubility, protein binding.
Metabolism: Chemical alteration of drug, primarily by liver enzymes (CYP450).
- Phase I (oxidation, etc.), Phase II (conjugation).
- Enzyme induction/inhibition → drug interactions.
Excretion: Elimination of drug/metabolites, mainly via kidneys.
- Clearance (CL): $CL = k \cdot V_d$.
- Half-life ($t_{1/2}$): $t_{1/2} = 0.693 / k$. Steady state in 4-5 $t_{1/2}$.

⭐ Most psychotropic drugs are lipid-soluble, leading to a large volume of distribution ($V_d$) and ability to cross the blood-brain barrier.

Pharmacodynamics (Mechanisms) - Drug's Power Play

What drug does to body; mechanism of action (MoA).
Receptor Interactions:
- Agonist: Activates receptor.
  - Full: Max response.
  - Partial: Submaximal; can act as antagonist with full agonist.
  - Inverse: Opposite effect to agonist (e.g., some antihistamines on H1 receptors).
- Antagonist: Blocks receptor action; no intrinsic activity.
  - Competitive: Reversible; shifts Dose-Response (DR) curve right (↓Potency, $E_{max}$ same). Overcome by ↑agonist.
  - Non-competitive: Irreversible or allosteric; ↓$E_{max}$. Cannot be overcome.
Dose-Response Relationship:
- Potency: Drug amount for a given effect ($ED_{50}$ or $EC_{50}$); ↓$ED_{50}$ = ↑Potency.
- Efficacy: Max effect a drug can produce ($E_{max}$).
- Therapeutic Index (TI): Measure of drug safety. $TI = TD_{50}/ED_{50}$. Higher TI = safer drug.
  - 📌 Lithium, Warfarin, Digoxin, Theophylline (Low TI Drugs - "Low Warning Dose Threshold").
- Receptor Regulation:
  - Downregulation (Desensitization/Tachyphylaxis): ↓Receptor number/sensitivity with chronic agonist use.
  - Upregulation (Supersensitivity): ↑Receptor number/sensitivity with chronic antagonist use.

⭐ Most antipsychotics exert their primary therapeutic effect by blocking Dopamine D2 receptors.

GPCR Ligand Binding and Response Curves

Clinical Applications & TDM - Minds & Meds

Therapeutic Drug Monitoring (TDM): Optimizes dosing, ↑ efficacy, ↓ toxicity.
- Indications: Narrow therapeutic index (NTI), non-response, toxicity, interactions.
- Key Drugs (Trough Levels):
  - Lithium: 0.6-1.2 mEq/L (Acute: up to 1.5). Toxic >1.5 mEq/L.
  - Clozapine: >350 ng/mL (efficacy).
  - Nortriptyline: 50-150 ng/mL.
  - Valproate: 50-100 µg/mL.
  - Carbamazepine: 4-12 µg/mL.
Drug Interactions (CYP450):
- Inducers: Carbamazepine, Phenytoin, Rifampicin, Smoking, St. John's Wort → ↓ drug levels.
- Inhibitors: Valproate, Fluoxetine, Paroxetine, Cimetidine, Erythromycin → ↑ drug levels.
Special Populations:
- Elderly: ↓ clearance. "Start low, go slow."
- Pregnancy: Risk-benefit (e.g., Valproate - NTDs).

⭐ Carbamazepine is a potent auto-inducer, accelerating its own metabolism, often requiring upward dose titration.

High‑Yield Points - ⚡ Biggest Takeaways

CYP450 enzymes (e.g., 2D6, 3A4) critically mediate psychotropic metabolism; inducers ↓ levels, inhibitors ↑ levels.

TDM is essential for drugs like lithium and TCAs due to narrow therapeutic windows.

Drug half-life (t½) determines dosing interval and time to steady state (approx. 4-5 half-lives).

Antipsychotic D2 receptor occupancy target: >65% for efficacy, >80% increases EPS risk.

Pharmacodynamic mechanisms: agonism, antagonism, partial agonism define drug actions.

First-pass metabolism significantly impacts oral drug bioavailability.

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