NEET-PG 2015 Practice Questions

Q: Which of the following processes primarily utilizes lactate produced anaerobically?

Cori cycle. ***Cori cycle*** - The **Cori cycle** (lactic acid cycle) involves the transport of **lactate** produced during anaerobic metabolism in muscles to the liver. - In the **liver**, this lactate is then converted back to **glucose** via gluconeogenesis, which can be returned to the muscles. *Gluconeogenesis* - **Gluconeogenesis** is the synthesis of glucose from non-carbohydrate precursors, one of which is lactate. - While it uses lactate, it is only one component of the broader **Cori cycle**, which describes the inter-organ cooperation. *Glycolysis* - **Glycolysis** is the metabolic pathway that breaks down glucose into pyruvate, which can then be converted to lactate under anaerobic conditions. - This process *produces* lactate but does not *utilize* it, acting upstream of lactate production. *TCA cycle* - The **TCA cycle** (Krebs cycle) is a central part of aerobic respiration that oxidizes acetyl-CoA to produce ATP, NADH, and FADH2. - It does not directly utilize lactate; instead, lactate is typically converted to pyruvate before potentially entering the TCA cycle under aerobic conditions.

Q: Increase in plasma viscosity is maximally caused by which plasma protein?

Fibrinogen. ***Globulin*** - Increased levels of **globulin** proteins, particularly in inflammatory or proliferative conditions, have a significant impact on plasma viscosity due to their **high molecular weight** [1]. - **Globulins** contribute to **hyperviscosity syndrome**, which can lead to clinical symptoms like fatigue and visual disturbances [1]. *Albumin* - While **albumin** is the most abundant plasma protein, its primary role is in maintaining **oncotic pressure**, not significantly affecting plasma viscosity. - An increase in albumin does not correlate with plasma viscosity increases to the extent seen with globulins. *All have equal effect* - Different plasma proteins do not have **equal effects** on viscosity; **globulins** and **fibrinogen** particularly influence it more than **albumin**. - The impact on viscosity varies significantly with protein concentration and type, making this statement inaccurate. *Fibrinogen* - **Fibrinogen** does contribute to plasma viscosity but is typically less than that caused by globulins, especially when globulin levels are markedly elevated. - Its effect is more pronounced during **coagulation**, rather than in the general increase of plasma viscosity associated with inflammatory states. **References:** [1] Cross SS. Underwood's Pathology: A Clinical Approach. 6th ed. (Basic Pathology) introduces the student to key general principles of pathology, both as a medical science and as a clinical activity with a vital role in patient care. Part 2 (Disease Mechanisms) provides fundamental knowledge about the cellular and molecular processes involved in diseases, providing the rationale for their treatment. Part 3 (Systematic Pathology) deals in detail with specific diseases, with emphasis on the clinically important aspects., pp. 141-142.

Q: Which protein primarily contributes to oncotic pressure in the blood?

Albumin. ***Albumin*** - **Albumin** is the most abundant plasma protein and its small size and high concentration make it the primary determinant of **oncotic pressure** in the blood. - Its presence in the capillaries draws water from the **interstitial space** back into the blood vessels, maintaining **fluid balance** and blood volume. *Fibrinogen* - **Fibrinogen** is a crucial protein involved in **blood clotting**, where it is converted into **fibrin** to form a clot. - While a plasma protein, its contribution to **oncotic pressure** is minor compared to albumin, as it's less abundant and larger in size. *Globulins* - **Globulins** are a diverse group of proteins involved in immune function (**immunoglobulins**), transport (e.g., **alpha** and **beta globulins**), and clotting. - While they contribute to total plasma protein concentration, their collective impact on **oncotic pressure** is secondary to that of albumin due to lower concentrations and varied molecular weights. *Transferrin* - **Transferrin** is a specific **beta-globulin** that plays a vital role in **iron transport** in the blood. - Its primary function is not related to **oncotic pressure**, and its concentration is significantly lower than albumin.

Q: What is Proaccelerin?

Factor V. ***Factor V*** - **Factor V**, also known as **proaccelerin** or **labile factor**, is a **plasma protein** that plays a crucial role in the coagulation cascade. - It is activated by thrombin to **Factor Va**, which then combines with Factor Xa, calcium, and phospholipid to form the **prothrombinase complex**, significantly enhancing thrombin generation. *Factor II* - **Factor II** is **prothrombin**, a precursor to **thrombin**, which is central to coagulation. - It is not referred to as preaccelerin. *Factor VII* - **Factor VII** is primarily involved in the **extrinsic pathway** of coagulation, becoming activated to Factor VIIa upon contact with tissue factor. - It works to activate Factor IX and Factor X, but it is not preaccelerin. *Factor X* - **Factor X**, also known as **Stuart-Prower factor**, is a key enzyme in the **common pathway** of coagulation, converting prothrombin to thrombin. - It is distinct from Factor V, which acts as a cofactor.

Q: What is the typical pH range of intracellular fluid (ICF) compared to extracellular fluid (ECF)?

Typically around 7.0, slightly less than ECF. ***Typically around 7.0, slightly less than ECF*** - The **intracellular fluid (ICF)** tends to be slightly more acidic due to metabolic processes within cells that produce **acidic byproducts**. - This makes its pH typically around **7.0–7.2**, which is subtly lower than the extracellular fluid. *Typically around 7.4, slightly more than ICF* - A pH of approximately **7.4** is characteristic of **extracellular fluid (ECF)**, which includes plasma and interstitial fluid. - The ECF is maintained within a **narrow, slightly alkaline** range to support cellular function and enzyme activity throughout the body. *Approximately equal to ECF* - While both fluid compartments are maintained within a **narrow physiological range**, their pH values are not exactly equal. - This slight difference is essential for various biological processes, including maintaining **membrane potential** and **enzyme efficiency**. *Significantly higher than ECF* - The ICF pH is **not significantly higher** than ECF; in fact, it is slightly lower. - Maintaining too high a pH intracellularly would disrupt **cellular metabolism** and **protein structure**.

Q: Which of the following statements about ENaC is incorrect?

Composed of 2 homologous subunits. ***Composed of 2 homologous subunits*** - ENaC (Epithelial Sodium Channel) is a **heterotrimeric complex** composed of **three distinct subunits**: α, β, and γ. - The functional channel typically has a stoichiometry of 2α:1β:1γ, forming a heterotrimer. - These subunits share sequence homology but are **non-identical proteins**, not just two homologous subunits. - A fourth related subunit (δ) exists and can substitute for α in some tissues, but the classical ENaC is a three-subunit channel. *Epithelial channel* - ENaC is indeed an **epithelial channel** responsible for critical **sodium reabsorption** in various epithelia. - It plays a vital role in regulating **fluid and electrolyte balance** across tight epithelial layers. *Present in kidney and GIT* - ENaC is abundantly expressed in the **distal nephron of the kidney**, specifically in the collecting duct, where it mediates fine-tuning of sodium reabsorption. - It is also present in the **lower gastrointestinal tract (colon)**, contributing to sodium absorption, and in the airways and salivary glands. *Inhibited by amiloride* - **Amiloride** is a well-known **potassium-sparing diuretic** that specifically acts by blocking ENaC. - This inhibition reduces sodium reabsorption and, consequently, water reabsorption, leading to increased diuresis.

Q: What is the average size of platelets in micrometers?

2-3 µm. ***2-3 µm*** - Platelets, also known as **thrombocytes**, are small, anucleated cell fragments crucial for **hemostasis**, and their average diameter generally falls within the range of 2-3 micrometers. - This **small size** allows them to easily navigate through capillaries and aggregate rapidly at sites of vascular injury. *3-4 µm* - While platelets can vary slightly in size, an average of 3-4 µm is generally considered a bit on the larger side and not the typical average diameter. - Larger platelets might be seen in certain conditions like **idiopathic thrombocytopenic purpura (ITP)**, but this is not the average normal size. *4-5 µm* - This range is significantly larger than the typical size of normal circulating platelets. - Platelets this large would be considered **macroplatelets** and could indicate specific pathological conditions or inherited platelet disorders. *1-2 µm* - This size range is generally considered smaller than the average normal platelet size. - Very small platelets might be seen in some specific conditions, but it's not the usual average for healthy individuals.

Q: What is the composition of epithelial sodium channels?

1α, 1β, 1γ. ***1α, 1β, 1γ*** - Epithelial sodium channels (**ENaCs**) are heterotrimeric complexes composed of one **alpha (α)**, one **beta (β)**, and one **gamma (γ) subunit**. - This specific subunit composition is essential for the channel's proper function in **sodium reabsorption** across epithelial tissues. *2α, 1β* - This composition is incomplete as it lacks the **gamma (γ) subunit**, which is a crucial component of the functional ENaC. - While alpha and beta subunits are present, the absence of the gamma subunit would impair the channel's ability to efficiently transport sodium. *2α, 1β, 2γ* - This composition is incorrect because a functional ENaC typically includes only **one gamma (γ) subunit**, not two. - An imbalance in subunit stoichiometry can lead to misfolding or improper assembly, affecting channel function. *2α, 1β, 1γ* - This combination correctly includes all three types of subunits (alpha, beta, gamma) but incorrectly states there are **two alpha (α) subunits**. - A functional ENaC has a single alpha subunit, making this option incorrect.

Q: What is the process of passive transport of molecules through protein pores/channels in the cell membrane?

Diffusion. ***Diffusion*** - **Diffusion** is the net movement of particles from an area of higher concentration to an area of lower concentration without requiring energy. - When diffusion occurs through **protein channels or pores** in the cell membrane, it is specifically termed **facilitated diffusion** or **channel-mediated diffusion**. - This remains a form of **passive transport** as it moves substances down their concentration gradient without ATP expenditure. - Examples include ion channels (Na⁺, K⁺, Ca²⁺) and aquaporins for water transport. *Active transport* - **Active transport** requires energy (typically ATP) to move substances **against** their concentration gradient. - It involves carrier proteins (pumps) like Na⁺-K⁺ ATPase that undergo conformational changes. - This is fundamentally different from passive transport through pores. *Transcytosis* - **Transcytosis** is a vesicular transport mechanism for moving substances across an entire cell. - It combines **endocytosis** on one side and **exocytosis** on the other side. - This is not passive transport through pores but rather bulk transport. *Endocytosis* - **Endocytosis** involves engulfing extracellular substances by forming membrane-bound vesicles. - Types include phagocytosis, pinocytosis, and receptor-mediated endocytosis. - This requires energy and does not involve transport through pores.

Q: Inhibition of heart by vagus is mediated by which receptors?

M2. ***M2*** - The **vagus nerve** primarily mediates its inhibitory effects on the heart through **muscarinic M2 receptors**. - Activation of M2 receptors by **acetylcholine** (released from the vagus nerve) decreases heart rate and contractility. *M1* - **M1 receptors** are primarily found in neuronal tissue and glands, playing a role in **gastric acid secretion** and cognitive functions. - They are not the primary muscarinic subclass responsible for vagal inhibition of the heart. *NN* - **NN receptors** are **nicotinic receptors** found on postganglionic neurons in autonomic ganglia. - They are involved in **ganglionic transmission** and are not directly responsible for efferent vagal effects on the heart. *NM* - **NM receptors** are **nicotinic receptors** found at the **neuromuscular junction** of skeletal muscles. - Their activation leads to **skeletal muscle contraction**, and they have no role in regulating heart function.

Question 1

Which of the following processes primarily utilizes lactate produced anaerobically?

Accepted Answer

Cori cycle

Answer

Gluconeogenesis

Answer

TCA cycle

Answer

Glycolysis

Question 2

Increase in plasma viscosity is maximally caused by which plasma protein?

Accepted Answer

Fibrinogen

Answer

Albumin

Answer

All have equal effect

Answer

Globulin

Question 3

Which protein primarily contributes to oncotic pressure in the blood?

Accepted Answer

Albumin

Answer

Globulins

Answer

Fibrinogen

Answer

Transferrin

Question 4

What is Proaccelerin?

Accepted Answer

Factor V

Answer

Factor VII

Answer

Factor II

Answer

Factor X

Question 5

What is the typical pH range of intracellular fluid (ICF) compared to extracellular fluid (ECF)?

Accepted Answer

Typically around 7.0, slightly less than ECF

Answer

Typically around 7.4, slightly more than ICF

Answer

Approximately equal to ECF

Answer

Significantly higher than ECF

Question 6

Which of the following statements about ENaC is incorrect?

Accepted Answer

Composed of 2 homologous subunits

Answer

Present in kidney and GIT

Answer

Epithelial channel

Answer

Inhibited by amiloride

Question 7

What is the average size of platelets in micrometers?

Accepted Answer

2-3 µm

Answer

4-5 µm

Answer

3-4 µm

Answer

1-2 µm

Question 8

What is the composition of epithelial sodium channels?

Accepted Answer

1α, 1β, 1γ

Answer

2α, 1β, 1γ

Answer

2α, 1β

Answer

2α, 1β, 2γ

Question 9

What is the process of passive transport of molecules through protein pores/channels in the cell membrane?

Accepted Answer

Diffusion

Answer

Transcytosis

Answer

Endocytosis

Answer

Active transport

Question 10

Inhibition of heart by vagus is mediated by which receptors?

Accepted Answer

M2

Answer

M1

Answer

NN

Answer

NM

NEET-PG 2015

Biochemistry

Physiology