When two different chemicals act on two different receptors and their responses are opposite to each other on the same cell, this phenomenon is called?
Which of the following is classified as a Type E adverse reaction?
Muscarinic cholinergic receptors are seen at all sites, except?
Which of the following statements about clonidine is incorrect?
Which dopamine receptor is known for its inhibitory action in the central nervous system?
Which of the following medications is most likely to cause reflex tachycardia?
In which of the following conditions is Verapamil not typically used?
What is the drug of choice for a classical angina attack?
Nesiritide causes vasodilation through?
Which of the following is NOT a side effect of digitalis?
NEET-PG 2013 - Pharmacology NEET-PG Practice Questions and MCQs
Question 21: When two different chemicals act on two different receptors and their responses are opposite to each other on the same cell, this phenomenon is called?
- A. Physiological antagonism (Correct Answer)
- B. Chemical antagonism
- C. Reversible antagonism
- D. Competitive antagonism
Explanation: ***Physiological antagonism*** - This occurs when two drugs act on **different receptors** to produce **opposite physiological effects** within the same system or cell, effectively canceling each other out [1]. - A classic example is the opposing actions of **histamine** (causing bronchoconstriction) and **adrenaline** (causing bronchodilation) on the bronchi [1]. *Chemical antagonism* - This involves a direct **chemical interaction** between two drugs that results in the **inactivation of one or both** of them. - An example is the binding of **chelating agents** to heavy metals, forming an inert complex. *Reversible antagonism* - This describes antagonism where the antagonist binds to the receptor and can be **displaced by a higher concentration of the agonist**. - It does not specifically describe antagonists acting on different receptors or producing opposing physiological effects. *Competitive antagonism* - This occurs when an antagonist directly **competes with an agonist for the same binding site** on a receptor [1]. - The antagonist, while not producing a response itself, prevents the agonist from binding and activating the receptor.
Question 22: Which of the following is classified as a Type E adverse reaction?
- A. Toxicity
- B. Augmented effect
- C. Teratogenesis
- D. Rebound effect due to drug withdrawal (Correct Answer)
Explanation: ***Rebound effect due to drug withdrawal*** - Type E adverse reactions are related to **end-of-treatment effects**, specifically withdrawal phenomena. - The **rebound effect** after drug cessation, such as worsened angina after stopping beta-blockers, is a classic example of a Type E reaction. *Toxicity* - This is a general term for adverse effects from excessive drug doses and is **not a specific type** in the ABCDEF classification. - Dose-dependent toxic effects typically align with **Type A** (augmented) reactions, which are predictable and related to the drug's pharmacology. *Augmented effect* - An **augmented effect** is classified as a Type A adverse drug reaction, meaning it is **dose-dependent**, predictable from the drug's known pharmacology, and common. - Examples include bleeding with anticoagulants or hypotension with antihypertensives. *Teratogenesis* - **Teratogenesis** refers to drug-induced fetal malformations and is categorized as a **Type D** (delayed) adverse drug reaction. - These effects are often severe, occur after prolonged exposure, and are rare.
Question 23: Muscarinic cholinergic receptors are seen at all sites, except?
- A. Stomach
- B. CNS
- C. Glands
- D. Neuromuscular junction (Correct Answer)
Explanation: ***Neuromuscular junction*** - The **neuromuscular junction** primarily contains **nicotinic cholinergic receptors**, not muscarinic receptors. - Activation of these nicotinic receptors by acetylcholine causes muscle contraction. *Stomach* - The stomach contains **muscarinic M3 receptors** which mediate gastric acid secretion and smooth muscle contraction. - Activation by acetylcholine via the vagus nerve promotes digestion. *CNS* - The **central nervous system** has various subtypes of **muscarinic receptors (M1-M5)** distributed throughout, playing roles in learning, memory, and motor control. - These receptors modulate neuronal excitability and neurotransmitter release. *Glands* - Most exocrine glands (e.g., salivary, lacrimal, sweat glands) are richly supplied with **muscarinic receptors**, primarily **M3**. - Activation leads to increased glandular secretion.
Question 24: Which of the following statements about clonidine is incorrect?
- A. Alpha 2 receptor agonist
- B. Sudden withdrawal causes rebound hypertension
- C. Controls loose motions due to diabetic neuropathy
- D. First line for AMI (Correct Answer)
Explanation: ***First line for AMI*** - Clonidine is **not first-line** for **Acute Myocardial Infarction (AMI)** as it can cause **bradycardia** and **hypotension**, potentially worsening cardiac output. - First-line AMI treatments include **thrombolytics**, **antiplatelet agents** (aspirin), **beta-blockers**, and **ACE inhibitors** for optimal cardiac protection. *Alpha 2 receptor agonist* - Clonidine is indeed an **alpha-2 adrenergic receptor agonist** that acts centrally in the **medulla oblongata**. - It reduces **sympathetic outflow** from the CNS, leading to decreased **heart rate**, **blood pressure**, and **peripheral vascular resistance**. *Sudden withdrawal causes rebound hypertension* - Abrupt clonidine discontinuation causes dangerous **rebound hypertension** due to sudden loss of **sympathetic inhibition**. - **Gradual tapering** over 1-2 weeks is essential to prevent this potentially life-threatening complication. *Controls loose motions due to diabetic neuropathy* - Clonidine effectively treats **diabetic diarrhea** by stimulating **alpha-2 receptors** in the enteric nervous system. - It **slows intestinal transit** and **enhances fluid absorption**, making it useful for **autonomic neuropathy-related** gastrointestinal symptoms.
Question 25: Which dopamine receptor is known for its inhibitory action in the central nervous system?
- A. Dopamine Receptor D5
- B. No inhibitory dopamine receptor present
- C. Dopamine Receptor D2 (Correct Answer)
- D. Dopamine Receptor D1
Explanation: ***Dopamine Receptor D2*** - The **D2 receptor** is a member of the D2-like family (D2, D3, D4), which are **G-protein coupled receptors** that inhibit adenylyl cyclase activity. - Its activation typically leads to a **decrease in neuronal excitability** and neurotransmitter release, providing an inhibitory effect in the CNS. *Dopamine Receptor D5* - The **D5 receptor** belongs to the D1-like family (D1, D5), which are **G-protein coupled receptors** that stimulate adenylyl cyclase activity. - Activation of D5 receptors typically leads to **excitatory effects** rather than inhibitory ones in the CNS. *No inhibitory dopamine receptor present* - This statement is incorrect as specific dopamine receptor subtypes, particularly the **D2-like family**, are well-established to exert inhibitory actions in the CNS. - These inhibitory effects are crucial for various physiological processes, including motor control and reward pathways. *Dopamine Receptor D1* - The **D1 receptor** is part of the D1-like family (D1, D5) and is known for its **excitatory effects** in the CNS. - Activation of D1 receptors leads to an **increase in intracellular cAMP** and generally enhances neuronal activity.
Question 26: Which of the following medications is most likely to cause reflex tachycardia?
- A. Nifedipine (Correct Answer)
- B. Verapamil
- C. Propranolol
- D. Amlodipine
Explanation: ***Nifedipine*** - Nifedipine is a **dihydropyridine calcium channel blocker** that causes significant peripheral vasodilation, leading to a rapid drop in blood pressure. - This sudden drop in blood pressure triggers a **baroreflex response**, compensatory increase in heart rate. *Verapamil* - Verapamil is a **non-dihydropyridine calcium channel blocker** that primarily acts on the cardiac pacemaker cells and slows AV nodal conduction. - While it can cause vasodilation, its direct negative chronotropic effect on the heart often **blunts or prevents reflex tachycardia**. *Propranolol* - Propranolol is a **non-selective beta-blocker** that blocks beta-1 and beta-2 adrenergic receptors. - It directly **decreases heart rate and myocardial contractility**, thereby preventing reflex tachycardia. *Amlodipine* - Amlodipine is a **dihydropyridine calcium channel blocker**, similar to nifedipine, but it has a **slower onset of action and a longer half-life**. - Its more gradual onset of vasodilation often results in a significantly **less pronounced or absent reflex tachycardia** compared to nifedipine.
Question 27: In which of the following conditions is Verapamil not typically used?
- A. Angina pectoris
- B. Atrial fibrillation
- C. Ventricular tachycardia (Correct Answer)
- D. Hypertension
Explanation: ***Ventricular tachycardia*** - Verapamil, a **non-dihydropyridine calcium channel blocker**, can worsen hemodynamics in patients with **ventricular tachycardia (VT)** by causing profound hypotension or precipitating cardiac arrest. - VT often requires prompt treatment with **antiarrhythmics like amiodarone** or **electrical cardioversion**, as it can be life-threatening. - Verapamil is **contraindicated in VT** due to its negative inotropic effects and risk of hemodynamic collapse. *Angina pectoris* - Verapamil is effectively used to treat angina pectoris by **decreasing myocardial oxygen demand** through negative chronotropic and inotropic effects, and by causing **coronary vasodilation**, improving blood flow. - Its effects help to reduce the frequency and severity of anginal episodes, particularly in **stable angina**. *Atrial fibrillation* - Verapamil is commonly used for **rate control in atrial fibrillation** by **slowing conduction through the AV node**, which decreases the ventricular response rate. - It helps to manage symptoms and prevent complications related to rapid heart rates in this arrhythmia. *Hypertension* - Verapamil is used in the treatment of **hypertension** through its vasodilatory effects and reduction in peripheral vascular resistance. - It is particularly useful in patients who cannot tolerate other antihypertensive agents or as part of combination therapy.
Question 28: What is the drug of choice for a classical angina attack?
- A. CCBs
- B. β-blocker
- C. GTN (Correct Answer)
- D. Prazosin
Explanation: ***GTN*** - **Glyceryl trinitrate (GTN)** is the drug of choice for immediate relief of a classical angina attack because it rapidly dilates coronary arteries and peripheral blood vessels, reducing **myocardial oxygen demand** and improving blood flow [2]. - Its **nitric oxide** mediated vasodilatory effects quickly alleviate chest pain by decreasing **preload** and afterload [2], [3]. *CCBs* - **Calcium channel blockers (CCBs)** are used for long-term prevention of angina by reducing myocardial oxygen demand, but they are not the first-line treatment for acute relief due to their slower onset of action [1]. - While they can dilate coronary arteries and reduce heart rate/contractility, their role is more in **prophylaxis** rather than acute symptom management [1]. *β-blocker* - **Beta-blockers** are primarily used for chronic management and prevention of angina by reducing heart rate, contractility, and blood pressure, thereby decreasing myocardial oxygen demand. - They are generally avoided for acute angina attacks as they do not provide rapid symptomatic relief and can potentially worsen symptoms in some acute ischemic conditions. *Prazocin* - **Prazosin** is an **alpha-1 adrenergic blocker** primarily used to treat hypertension and benign prostatic hyperplasia. - It causes vasodilation but is not indicated for the treatment of acute angina, as its mechanism of action and onset of effect are not suitable for rapid relief of myocardial ischemia.
Question 29: Nesiritide causes vasodilation through?
- A. ATP
- B. Cyclic adenosine monophosphate (cAMP)
- C. K+ ions
- D. Guanosine 3',5'-cyclic monophosphate (cGMP) (Correct Answer)
Explanation: ***Guanosine 3',5'-cyclic monophosphate (cGMP)*** - **Nesiritide** is a synthetic **B-type natriuretic peptide (BNP)** that acts as a potent vasodilator [2]. - It works by binding to **guanylyl cyclase receptors**, leading to an increase in intracellular **cGMP**, which promotes smooth muscle relaxation [1], [2]. *Cyclic adenosine monophosphate (cAMP)* - While **cAMP** is a crucial second messenger in various cellular processes and can mediate some forms of vasodilation, it is primarily associated with **beta-adrenergic receptor activation**, not the mechanism of action of nesiritide. - Nesiritide's pathway is distinct from those involving **cAMP-mediated** relaxation, which often involves different kinases and protein phosphorylation. *ATP* - **ATP** (adenosine triphosphate) is the primary **energy currency** of the cell and is involved in numerous cellular functions, including muscle contraction and relaxation, but it is not a direct mediator of nesiritide's vasodilatory effects. - Though ATP can be broken down to produce **adenosine**, which has vasodilatory properties, this is not the specific mechanism through which nesiritide causes vasodilation. *K+ ions* - Changes in **potassium ion (K+)** flux across cell membranes are essential for regulating vascular tone, as K+ channel activation can lead to hyperpolarization and relaxation of smooth muscle. - However, **nesiritide's primary mechanism** of action does not involve direct modulation of K+ channels; its vasodilatory effects are mediated by the **cGMP pathway** [2].
Question 30: Which of the following is NOT a side effect of digitalis?
- A. Nausea and vomiting
- B. Ventricular Bigeminy
- C. Vasodilatation (Correct Answer)
- D. Ventricular tachycardia
Explanation: **Vasodilatation** - **Digitalis**, primarily digoxin, is known for its **positive inotropic effect**, increasing myocardial contractility, and for its **vasoconstrictive properties** at higher doses due to sympathetic activation and direct smooth muscle effects, not vasodilatation. - While it can indirectly improve cardiac output and thus tissue perfusion, its direct vascular effects do not typically include widespread vasodilatation. *Ventricular tachycardia* - **Digitalis toxicity** can lead to various arrhythmias, including **ventricular tachycardia**, which is a potentially life-threatening side effect. - This occurs due to increased automaticity and delayed afterdepolarizations in ventricular myocytes. *Nausea and vomiting* - **Gastrointestinal symptoms** such as **nausea and vomiting** are common early signs of digitalis toxicity. - These effects are thought to be mediated by the drug's action on the chemoreceptor trigger zone in the brainstem. *Ventricular Bigeminy* - **Ventricular bigeminy**, characterized by alternating normal and premature ventricular beats, is another classic manifestation of **digitalis toxicity**. - This arrhythmia results from enhanced automaticity and altered conduction properties in the ventricles.