Inotropic effect of thyroid hormone is by ?
What is the nature of the relationship between insulin and glucose concentration in the human body?
Which of the following statements about insulin-mediated transport of glucose is correct?
Which of the following neurons in the cerebellar cortex is primarily excitatory?
What is one of the specific functions of the primary motor cortex located on the anterior edge of the pre-central gyrus?
Which part of the sympathetic nervous system is responsible for secreting catecholamines?
What is the typical resting membrane potential (RMP) of smooth muscle cells?
Which of the following statements is TRUE regarding the Bohr effect?
What is the Haldane Effect?
What is the total surface area of the respiratory membrane in a healthy adult human?
NEET-PG 2015 - Physiology NEET-PG Practice Questions and MCQs
Question 51: Inotropic effect of thyroid hormone is by ?
- A. Membrane receptors
- B. cAMP
- C. cGMP
- D. Enhancement of Catecholamines (Correct Answer)
Explanation: ***Enhancement of Catecholamines*** - Thyroid hormones **potentiate the effects of catecholamines** (like adrenaline and noradrenaline) on the heart, leading to increased heart rate and contractility, which is an **inotropic effect**. - This occurs by increasing the number and sensitivity of **beta-adrenergic receptors** on cardiac muscle cells. *Membrane receptors* - While thyroid hormones do have some rapid, non-genomic effects that may involve **membrane receptors**, their primary and well-established inotropic effect is mediated indirectly through catecholamine sensitivity. - The classic action of thyroid hormones is via intracellular receptors that modulate gene expression, not direct membrane receptor signaling for inotropic effects. *cAMP* - **cAMP** is a common second messenger for many hormones, particularly those acting via G protein-coupled receptors. - While catecholamines themselves act through cAMP to exert their cardiac effects, thyroid hormones *enhance the action* of catecholamines rather than directly using cAMP as their primary inotropic mechanism. *cGMP* - **cGMP** is a second messenger often associated with nitric oxide signaling and vasodilation, contributing to cGMP-dependent protein kinases. - It is not the primary mediator for the *positive inotropic effect* of thyroid hormones on the heart.
Question 52: What is the nature of the relationship between insulin and glucose concentration in the human body?
- A. Linear
- B. Hyperbola
- C. Sigmoidal (Correct Answer)
- D. Bell Shaped
Explanation: ***Sigmoidal*** - The relationship between insulin and glucose concentration is best described as **sigmoidal**, characterized by a slow initial rise in insulin secretion at low glucose levels, followed by a steep increase at physiological glucose concentrations, and then a plateau at very high glucose levels. - This shape reflects the **beta cell's sensitivity to glucose**, where a minimal threshold of glucose is required to trigger insulin release, and then a maximal release capacity is reached. *Linear* - A **linear relationship** would imply that for every unit increase in glucose, there is a constant, proportional increase in insulin secretion, which is not physiologically accurate. - While insulin secretion does increase with glucose, the rate of increase varies significantly across different glucose concentrations. *Hyperbola* - A **hyperbolic relationship** typically suggests a rapid initial response that then gradually plateaus, often seen in enzyme kinetics. - While there is a plateau in insulin secretion at high glucose levels, the initial phase is not as rapid or proportionally inverse as a hyperbolic function would suggest. *Bell Shaped* - A **bell-shaped curve** describes a relationship where there is an optimal point, and deviations in either direction lead to a decrease in the response (e.g., enzyme activity vs. pH). - This is not characteristic of insulin secretion, as insulin levels generally continue to rise or plateau at higher glucose concentrations and do not decrease beyond an optimal point.
Question 53: Which of the following statements about insulin-mediated transport of glucose is correct?
- A. Via GLUT-2
- B. Main mechanism in RBCs
- C. Seen in adipose tissue (Correct Answer)
- D. Occurs primarily in the brain
Explanation: ***Seen in adipose tissue*** - **Adipose tissue** and **skeletal muscle** are the primary sites where glucose uptake from the bloodstream is significantly enhanced by insulin. - Insulin stimulates the translocation of **GLUT4 transporters** to the cell membrane in these tissues, increasing glucose entry. *Occurs primarily in the brain* - Glucose uptake into the **brain** is largely **insulin-independent**, primarily mediated by **GLUT1** and **GLUT3 transporters**. - The brain requires a constant supply of glucose and does not rely on insulin to facilitate its entry. *Via GLUT-2* - **GLUT2** is a **low-affinity, high-capacity** glucose transporter primarily found in the **liver**, **pancreatic beta cells**, kidneys, and small intestine. - It allows for rapid equilibration of glucose across membranes but is not directly involved in the **insulin-mediated uptake** seen in peripheral tissues. *Main mechanism in RBCs* - **Red blood cells (RBCs)** primarily use **GLUT1** for glucose transport, which is an **insulin-independent** process. - RBCs do not contain mitochondria and rely on glycolysis for energy, so they require a continuous, insulin-independent supply of glucose.
Question 54: Which of the following neurons in the cerebellar cortex is primarily excitatory?
- A. Purkinje
- B. Basket
- C. Golgi
- D. Granule cells (Correct Answer)
Explanation: ***Granule cells*** - **Granule cells** are the only neurons in the cerebellar cortex that are **excitatory**, utilizing glutamate as their neurotransmitter. - They receive input from **mossy fibers** and project their parallel fibers to Purkinje cells and other interneurons. *Purkinje* - **Purkinje cells** are the primary output neurons of the cerebellar cortex and are **inhibitory**, releasing GABA. - They integrate vast amounts of information and project to the **deep cerebellar nuclei**. *Basket* - **Basket cells** are **inhibitory interneurons** located in the molecular layer of the cerebellum. - They synapse on the somata of **Purkinje cells**, providing potent inhibition. *Golgi* - **Golgi cells** are **inhibitory interneurons** found in the granular layer of the cerebellum. - They receive excitatory input from **parallel fibers** and inhibit granule cells, forming an important feedback loop.
Question 55: What is one of the specific functions of the primary motor cortex located on the anterior edge of the pre-central gyrus?
- A. Control of voluntary movement (Correct Answer)
- B. Increase extensor muscle tone
- C. Perception of pain
- D. Inhibition of stretch reflex
Explanation: ***Control of voluntary movement*** - The **primary motor cortex (M1)**, located in the **precentral gyrus**, is critically involved in generating neural impulses that control the execution of **voluntary movements**. - It plays a key role in **planning and executing complex, skilled movements**, especially of the distal musculature. *Increase extensor muscle tone* - While motor pathways influence muscle tone, the primary motor cortex's most specific role is not simply increasing extensor tone; rather, it coordinates a wide range of movements involving both flexors and extensors. - **Spasticity** or increased muscle tone (often extensor) is more commonly associated with damage to the **corticospinal tracts (upper motor neuron lesions)**, which *prevents* the fine-tuning inhibitory control from the cortex. *Perception of pain* - **Pain perception** is primarily processed in the **somatosensory cortex** (postcentral gyrus), limbic system, and insula, not the primary motor cortex. - The primary motor cortex is responsible for **motor output**, not sensory interpretation. *Inhibition of stretch reflex* - While descending motor pathways can modulate spinal reflexes, the direct and primary function of the primary motor cortex is not the specific inhibition of the stretch reflex. - The **gamma motor system** and other spinal interneurons are more directly involved in modulating the sensitivity of the stretch reflex.
Question 56: Which part of the sympathetic nervous system is responsible for secreting catecholamines?
- A. Cardiac ganglion
- B. Cervical sympathetic chain
- C. Adrenal medulla (Correct Answer)
- D. Thoracic sympathetic chain
Explanation: ***Adrenal medulla*** - The adrenal medulla acts as a modified **sympathetic ganglion**, directly innervated by **preganglionic sympathetic fibers**. - Upon stimulation, it releases a high concentration of **epinephrine** (adrenaline) and a smaller amount of **norepinephrine** (noradrenaline) into the bloodstream, acting as hormones. *Cardiac ganglion* - **Cardiac ganglia** are parasympathetic ganglia located in the heart, involved in regulating heart rate and contractility via acetylcholine release. - They do not secrete **catecholamines** but rather act as relay stations for parasympathetic innervation. *Cervical sympathetic chain* - The **cervical sympathetic chain** primarily innervates structures in the head, neck, and upper limbs, influencing functions like pupils, salivary glands, and sweat glands. - While it contains sympathetic neurons, its primary role is not the systemic release of **catecholamines** into the bloodstream. *Thoracic sympathetic chain* - The **thoracic sympathetic chain** provides sympathetic innervation to organs in the thoracic and abdominal cavities, influencing heart rate, bronchodilation, and visceral blood flow. - Like other sympathetic ganglia, it releases norepinephrine at target organ synapses, but it does not serve as a major endocrine gland for systemic catecholamine release.
Question 57: What is the typical resting membrane potential (RMP) of smooth muscle cells?
- A. -90 mV
- B. -70 mV
- C. -60 mV (Correct Answer)
- D. -40 mV
Explanation: ***-60 mV*** - Smooth muscle cells typically have a **resting membrane potential of -55 to -60 mV**, which is **less negative** compared to skeletal muscle (-90 mV) or neurons (-70 mV). - This relatively depolarized RMP allows them to be **more easily excited** and enables **spontaneous slow wave depolarizations** and pacemaker activity in some smooth muscle types. - The less negative potential is due to higher resting permeability to Na+ and Ca2+ compared to skeletal muscle. *-90 mV* - This is the typical resting membrane potential for **skeletal muscle cells** and **large myelinated nerve fibers**. - Such a highly negative RMP provides a **larger buffer against accidental excitation** and ensures precise voluntary control. - This value is maintained by high K+ permeability and active Na+/K+ ATPase activity. *-70 mV* - This is the characteristic resting membrane potential of **most neurons**, allowing for efficient generation and propagation of action potentials. - It represents a balance between depolarizing and hyperpolarizing influences, optimal for neuronal signaling. - This is more negative than smooth muscle but less negative than skeletal muscle. *-40 mV* - This value is **too depolarized** to be a stable resting potential for smooth muscle and would be **near threshold potential**. - At -40 mV, voltage-gated calcium channels would be significantly activated, causing sustained contraction rather than a resting state. - This might represent a **partially depolarized state** or the RMP of specialized pacemaker cells like cardiac SA node cells, but **not typical smooth muscle**.
Question 58: Which of the following statements is TRUE regarding the Bohr effect?
- A. Decreased affinity of Hb to O2 is associated with increased pH & decreased CO2
- B. Decreased affinity of Hb to O2 is associated with increased pH & CO2
- C. Decreased affinity of Hb to O2 is associated with decreased pH & increased CO2 (Correct Answer)
- D. Decreased affinity of Hb to O2 is associated with decreased pH & decreased CO2
Explanation: ***Decreased affinity of Hb to O2 is associated with decreased pH & increased CO2*** - The **Bohr effect** describes how **hemoglobin's (Hb) affinity for oxygen (O2) decreases** in the presence of increased **acidity (decreased pH)** and higher **carbon dioxide (CO2)** concentrations. - This physiological adaptation ensures that O2 is **released more readily** to tissues that are actively metabolizing (e.g., muscle during exercise), as these tissues produce more CO2 and lactic acid, leading to a drop in pH. *Decreased affinity of Hb to O2 is associated with increased pH & decreased CO2* - An **increased pH** (more alkaline) and **decreased CO2** actually **increase Hb's affinity for O2**, shifting the oxygen dissociation curve to the left. - This scenario promotes **oxygen loading** onto hemoglobin, typically occurring in the lungs rather than O2 release in the tissues. *Decreased affinity of Hb to O2 is associated with increased pH & CO2* - This statement combines an **increased pH** (which increases Hb-O2 affinity) with **increased CO2** (which decreases Hb-O2 affinity), leading to a contradictory and incorrect physiological effect based on the Bohr principle. - The net effect of an increased pH would typically dominate in terms of O2 binding. *Decreased affinity of Hb to O2 is associated with decreased pH & decreased CO2* - While **decreased pH** does reduce Hb's affinity for O2, **decreased CO2** would tend to increase it. - Therefore, this combination does not accurately represent the primary conditions that lead to a significant decrease in Hb-O2 affinity as described by the Bohr effect in active tissues.
Question 59: What is the Haldane Effect?
- A. O2 delivery by increased CO2
- B. CO2 delivery by increased CO2
- C. CO2 delivery by increased O2 (Correct Answer)
- D. O2 delivery by increased CO
Explanation: ***CO2 delivery by increased O2*** - The **Haldane effect** describes how **oxygenation of hemoglobin** decreases its affinity for **carbon dioxide (CO2)**, leading to the release of CO2 from the blood. - This is crucial in the lungs, where high oxygen levels promote CO2 unloading for exhalation. *O2 delivery by increased CO2* - This describes the **Bohr effect**, where an increase in **carbon dioxide (CO2)** or acidity in the tissues causes hemoglobin to release **oxygen (O2)**. - The Haldane effect is the converse, relating oxygen binding to CO2 release, not the other way around. *CO2 delivery by increased CO2* - This statement is inherently circular and does not describe a physiological effect. - It confuses the mechanism with the substance being transported. *O2 delivery by increased CO* - **Carbon monoxide (CO)** has a much higher affinity for hemoglobin than oxygen, forming **carboxyhemoglobin** and impairing oxygen delivery. - This is related to **carbon monoxide poisoning**, not a physiological regulatory effect like the Haldane or Bohr effects.
Question 60: What is the total surface area of the respiratory membrane in a healthy adult human?
- A. 30 m2
- B. 50 m2
- C. 75 m2 (Correct Answer)
- D. 100 m2
Explanation: ***75 m²*** - The **total surface area** of the respiratory membrane in a healthy adult human is approximately **70-80 m²**, with 75 m² being the most accurate estimate among the given options. - This large surface area is primarily attributed to the presence of approximately **300-500 million alveoli**, which are crucial for efficient gas exchange. - Modern measurements using **stereological techniques** have refined earlier estimates and established this range as the current standard. *100 m²* - This value represents an **older estimate** that has been revised downward with more accurate measurement techniques. - While historically cited in older textbooks, current physiological data supports a **smaller surface area** of approximately 70-80 m². *30 m²* - This value is significantly **underestimated** for the total respiratory membrane surface area. - Such a small surface area would result in highly **inefficient gas exchange**, leading to severe respiratory compromise and inability to meet metabolic demands. *50 m²* - While larger than 30 m², this is still an **underestimation** of the full respiratory membrane surface area. - It does not adequately account for the extensive and intricate branching of the **respiratory bronchioles** and the vast number of alveolar sacs.