NEET-PG 2015

1414 Questions — Page 21 of 142

Biochemistry

1 questions

Q201

Chymotrypsinogen is activated into chymotrypsin by:

Physiology

9 questions

Q201

Cerebral blood flow is regulated by all, EXCEPT:

Q202

Isocapnic buffering is?

Q203

What is the typical resting membrane potential (RMP) of smooth muscle cells?

Q204

What does the ST Segment of an ECG correspond to?

Q205

Cerebral blood flow is most directly increased by?

Q206

What is the partial pressure for oxygen in the inspired air?

Q207

What is the primary function of the myenteric plexus?

Q208

Aortic valve closure corresponds to the beginning of which phase of the cardiac cycle?

Q209

What is the normal transpulmonary pressure during quiet breathing?

NEET-PG 2015 - Physiology NEET-PG Practice Questions and MCQs

Question 201: Cerebral blood flow is regulated by all, EXCEPT:

A. Intracranial pressure
B. Cerebral metabolic rate
C. Potassium ions (Correct Answer)
D. Arterial PCO2

Explanation: ***Potassium ions*** - While potassium ions play a crucial role in neuronal excitability and membrane potential, they are **not a primary direct regulator** of cerebral blood flow (CBF) in the same way as other factors listed. - Changes in extracellular potassium can affect vascular smooth muscle, but their direct impact on CBF auto-regulation is less pronounced compared to metabolic or pressure-related factors. *Intracranial pressure* - **Increased intracranial pressure (ICP)** can significantly decrease cerebral blood flow due to the **Monro-Kellie doctrine**, which states that an increase in ICP reduces the cerebral perfusion pressure (CPP). - A sustained and significant elevation in ICP can lead to **cerebral ischemia** as it opposes the arterial pressure driving blood into the brain. *Arterial PCO2* - **Arterial PCO2** is a potent regulator of cerebral blood flow, with **hypercapnia (high PCO2)** causing **vasodilation** and increased CBF. - Conversely, **hypocapnia (low PCO2)** leads to **vasoconstriction** and decreased CBF, which is a key mechanism in the management of cerebral edema. *Cerebral metabolic rate* - **Cerebral metabolic rate (CMR)** is directly coupled to cerebral blood flow, meaning that regions of the brain with higher metabolic activity receive increased blood flow. - This **neurovascular coupling** ensures adequate supply of oxygen and nutrients to meet the brain's metabolic demands.

Question 202: Isocapnic buffering is?

A. None of the options
B. Increased pCO2 with increased CO2
C. Increased pCO2 with decreased CO2
D. Normal pCO2 with increased CO2 (Correct Answer)

Explanation: ***Normal pCO2 with increased CO2*** - Isocapnic buffering refers to the process where the body buffers an **increase in lactic acid** or other metabolic acids without a significant change (maintaining it within a normal range) in **arterial partial pressure of carbon dioxide (pCO2)**. - This is achieved by an increase in **ventilation** stimulated by the acid, which expels more CO2 to compensate for the additional CO2 produced from the buffering reaction, thereby keeping pCO2 stable. *Increased pCO2 with increased CO2* - This scenario would indicate **hypoventilation** or a failure of the respiratory compensation mechanism to maintain pCO2 within normal limits during an increased metabolic CO2 load. - **Increased pCO2** would signify a state of **respiratory acidosis** or inadequate respiratory compensation, not isocapnic buffering. *Increased pCO2 with decreased CO2* - This statement is inherently contradictory; it is not possible to have an **increased pCO2** simultaneously with **decreased CO2** in the context of buffering. - **pCO2** is a measure of the partial pressure of carbon dioxide, directly related to the amount of CO2 present and dissolved in the blood. *None of the options* - This option is incorrect because "Normal pCO2 with increased CO2" accurately describes the physiological phenomenon of **isocapnic buffering**.

Question 203: 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 204: What does the ST Segment of an ECG correspond to?

A. Ventricular depolarization
B. Plateau phase between ventricular depolarization and repolarization (Correct Answer)
C. Atrial depolarization
D. AV Conduction

Explanation: ***Plateau phase between ventricular depolarization and repolarization*** - The **ST segment** represents the electrically neutral period between ventricular depolarization and repolarization, corresponding to the **plateau phase (phase 2)** of the ventricular action potential. - During this phase, the entire ventricular myocardium is depolarized, and there is minimal electrical activity, typically causing the ST segment to be **isoelectric**. *Ventricular depolarization* - This electrical event is represented by the **QRS complex** on the ECG, not the ST segment. - The QRS complex signifies the rapid spread of electrical impulses through the ventricles, leading to their contraction. *Atrial depolarization* - **Atrial depolarization** is represented by the **P wave** on the ECG. - This wave indicates the electrical activation of the atria, which precedes atrial contraction. *AV Conduction* - **AV conduction** time is primarily represented by the **PR interval** on the ECG. - The PR interval measures the time from the beginning of atrial depolarization to the beginning of ventricular depolarization, encompassing the delay at the AV node.

Question 205: Cerebral blood flow is most directly increased by?

A. Increase in PO2
B. Increase in PCO2 (Correct Answer)
C. Decrease metabolic rate
D. Increase in metabolic rate

Explanation: ***Increase in PCO2*** - An increase in **arterial PCO2** (partial pressure of carbon dioxide) causes **cerebral vasodilation**, leading to a direct increase in cerebral blood flow. - This is a potent regulatory mechanism to ensure adequate **carbon dioxide removal** and **oxygen supply** to the brain. *Increase in PO2* - An increase in **arterial PO2** (partial pressure of oxygen) causes **mild cerebral vasoconstriction**, which would tend to decrease cerebral blood flow, not increase it. - Cerebral blood flow is generally **less sensitive** to changes in PO2 within the normal range compared to PCO2. *Decrease metabolic rate* - A decrease in the brain's **metabolic rate** would typically lead to a **decrease in local demand** for oxygen and nutrients, resulting in **decreased cerebral blood flow**. - Cerebral blood flow is intrinsically linked to the metabolic needs of brain tissue. *Increase in metabolic rate* - An increase in the brain's **metabolic rate** would lead to an **increase in demand** for oxygen and glucose, which in turn causes **vasodilation** and an increase in cerebral blood flow. - However, this is an indirect effect, whereas an increase in PCO2 directly causes vasodilation.

Question 206: What is the partial pressure for oxygen in the inspired air?

A. 158 mm Hg (Correct Answer)
B. 116 mm Hg
C. 0.3 mm Hg
D. 100 mm Hg

Explanation: ***158 mm Hg*** - The partial pressure of oxygen in inspired air (PIO2) is calculated by multiplying the **fraction of inspired oxygen (FiO2)** by the total atmospheric pressure. - At sea level, atmospheric pressure is approximately **760 mm Hg** and FiO2 is 21% (0.21), so 0.21 × 760 mm Hg = **159.6 mm Hg**, which rounds to 158 mm Hg. - This represents **dry atmospheric air** before it enters the respiratory tract. *116 mm Hg* - This value does not correspond to a standard physiological measurement in respiratory physiology. - It is lower than inspired air PO2 but higher than alveolar PO2, making it an intermediate value used as a distractor. - **Humidified tracheal air** has PO2 of approximately 150 mm Hg: (760-47) × 0.21 = 149.7 mm Hg, where 47 mm Hg is water vapor pressure. *0.3 mm Hg* - This value is extremely low and represents the approximate **partial pressure of oxygen in mixed venous blood**, not inspired air. - Such a low value in inspired air would indicate **severe hypoxia** incompatible with life. - This is used as an unrealistic distractor. *100 mm Hg* - This value represents the approximate **partial pressure of oxygen in alveolar air (PAO2) and arterial blood (PaO2)**. - It is lower than inspired air due to humidification, mixing with residual air, and continuous oxygen uptake by blood. - It does not represent the partial pressure of oxygen in the inspired atmospheric air.

Question 207: What is the primary function of the myenteric plexus?

A. Regulating GI secretion
B. Regulating local blood flow
C. Regulating motility (Correct Answer)
D. Regulating absorption

Explanation: ***Regulating motility*** - The myenteric plexus, also known as **Auerbach's plexus**, is primarily responsible for coordinating the **rhythmic contractions** and **relaxation of the gastrointestinal (GI) smooth muscle**. - Its strategic location between the **longitudinal and circular muscle layers** allows it to directly influence the strength and frequency of peristalsis, thus regulating the movement of food through the digestive tract. *Regulating GI secretion* - While it has some indirect influence, the **submucosal plexus** (Meissner's plexus) is the primary neural network regulating **secretory functions** of the GI tract. - The myenteric plexus's main role is more directly related to muscle contraction and relaxation rather than glandular secretion. *Regulating local blood flow* - Local blood flow in the GI tract is primarily regulated by the **sympathetic and parasympathetic nervous systems**, along with local metabolic factors and hormones. - The myenteric plexus has a minimal direct role in the control of **GI blood vessel smooth muscle**. *Regulating absorption* - Absorption is primarily a function of the **intestinal epithelial cells** and is regulated by various transport mechanisms, hormones, and local factors. - While the enteric nervous system influences mucosal function indirectly, the myenteric plexus's primary role is **motor control** rather than directly regulating nutrient absorption processes.

Question 208: Aortic valve closure corresponds to the beginning of which phase of the cardiac cycle?

A. Systole
B. Parasystole
C. Isovolumetric contraction
D. Isovolumetric relaxation (Correct Answer)

Explanation: ***Isovolumetric relaxation*** - **Aortic valve closure** marks the end of **ventricular ejection** and the beginning of **isovolumetric relaxation** as both the aortic and mitral valves are closed, and ventricular pressure drops without a change in volume. - This phase is vital for the heart to relax and prepare for filling, corresponding to the **second heart sound (S2)**. *Systole* - **Systole** refers to the **contraction phase** of the heart, encompassing both isovolumetric contraction and ventricular ejection. - Aortic valve closure signifies the end of the **ejection phase** of systole, not its beginning. *Parasystole* - **Parasystole** is an **arrhythmia** where an ectopic pacemaker competes with the normal sinus rhythm, leading to independent atrial or ventricular contractions. - It is a **pathological condition** and not a normal phase of the cardiac cycle. *Isovolumetric contraction* - **Isovolumetric contraction** occurs after the **mitral valve closes** and before the aortic valve opens, causing pressure to build in the ventricle. - This phase precedes **ventricular ejection** and is initiated by mitral valve closure, not aortic valve closure.

Question 209: What is the normal transpulmonary pressure during quiet breathing?

A. 0 to + 1 cm H2O
B. 0 to -1 cm H2O
C. +5 to +8 cm H2O (Correct Answer)
D. - 8 to - 5 cm H2O

Explanation: ***+5 to +8 cm H2O*** - Transpulmonary pressure (P_tp) is the **difference between alveolar pressure and pleural pressure** (P_alv - P_pl). - During quiet breathing at **functional residual capacity (FRC)**, alveolar pressure is **0 cm H2O** (atmospheric) while pleural pressure is approximately **-5 cm H2O**, giving P_tp = **+5 cm H2O**. - At end-inspiration during quiet breathing, pleural pressure becomes more negative (**-8 cm H2O**) while alveolar pressure remains near atmospheric, resulting in P_tp ≈ **+8 cm H2O**. - This positive transpulmonary pressure gradient is essential to **keep the lungs inflated** against elastic recoil and prevent **atelectasis**. *0 to +1 cm H2O* - This pressure is far too low to maintain lung inflation against elastic recoil forces. - Normal transpulmonary pressure must be several cm H2O positive to counterbalance the lung's tendency to collapse. - This value would result in **near-complete lung collapse**. *0 to -1 cm H2O* - A negative or zero transpulmonary pressure would mean pleural pressure equals or exceeds alveolar pressure. - This condition would cause **immediate lung collapse (pneumothorax)** as there would be no pressure gradient to keep the lungs expanded. *-8 to -5 cm H2O* - This range represents **pleural pressure**, not transpulmonary pressure. - Pleural pressure is indeed -5 to -8 cm H2O during quiet breathing, but transpulmonary pressure is calculated as the difference between alveolar and pleural pressures. - Confusing pleural pressure with transpulmonary pressure is a common error.