Compliance of blood vessels US Medical PG Practice Questions and MCQs
Practice US Medical PG questions for Compliance of blood vessels. These multiple choice questions (MCQs) cover important concepts and help you prepare for your exams.
Compliance of blood vessels US Medical PG Question 1: A woman with coronary artery disease is starting to go for a walk. As she begins, her heart rate accelerates from a resting pulse of 60 bpm until it reaches a rate of 120 bpm, at which point she begins to feel a tightening in her chest. She stops walking to rest and the tightening resolves. This has been happening to her consistently for the last 6 months. Which of the following is a true statement?
- A. This patient's chest pain is indicative of transmural ischemia
- B. Perfusion of the myocardium takes place equally throughout the cardiac cycle
- C. Increasing the heart rate increases the amount of time spent during each cardiac cycle
- D. Increasing the heart rate decreases the relative amount of time spent during diastole (Correct Answer)
- E. Perfusion of the myocardium takes place primarily during systole
Compliance of blood vessels Explanation: ***Increasing the heart rate decreases the relative amount of time spent during diastole***
- With increasing heart rate, the **duration of the cardiac cycle decreases**, but this reduction is disproportionately greater in **diastole (filling phase)** compared to systole (ejection phase), which becomes critical in patients with coronary artery disease as myocardial perfusion occurs during diastole.
- Reduced diastolic time means less time for **coronary artery filling** and **myocardial perfusion**, exacerbating ischemia in the presence of fixed coronary stenosis.
*This patient's chest pain is indicative of transmural ischemia*
- The patient's symptoms are consistent with **stable angina**, characterized by chest pain with exertion that resolves with rest, suggesting **subendocardial ischemia** rather than transmural.
- **Transmural ischemia** typically indicates a more severe, often prolonged, and extensive reduction in blood flow, such as in a **ST-elevation myocardial infarction (STEMI)**.
*Perfusion of the myocardium takes place equally throughout the cardiac cycle*
- Myocardial perfusion is **not equal throughout the cardiac cycle**; it primarily occurs during **diastole** when the heart muscle is relaxed and coronary arteries are less compressed.
- During **systole**, the contracting myocardium compresses the coronary arteries, restricting blood flow, especially to the **subendocardial layers**.
*Increasing the heart rate increases the amount of time spent during each cardiac cycle*
- **Increasing heart rate** by definition **decreases the total duration of each cardiac cycle** (e.g., if heart rate is 60 bpm, cycle duration is 1 second; if 120 bpm, cycle duration is 0.5 seconds).
- While both systole and diastole shorten, the **diastolic phase shortens more significantly**, which is problematic for myocardial perfusion.
*Perfusion of the myocardium takes place primarily during systole*
- **Myocardial perfusion primarily occurs during diastole**, not systole, because the **intramyocardial pressure is lower** and the coronary arteries are less compressed, allowing for better blood flow.
- During **systole**, the high intramyocardial pressure, especially in the left ventricular wall, compresses the coronary vessels, significantly reducing blood flow to the myocardium.
Compliance of blood vessels US Medical PG Question 2: Which of the following physiologic changes decreases pulmonary vascular resistance (PVR)?
- A. Inhaling the inspiratory reserve volume (IRV)
- B. Exhaling the entire vital capacity (VC)
- C. Exhaling the expiratory reserve volume (ERV)
- D. Breath holding maneuver at functional residual capacity (FRC)
- E. Inhaling the entire vital capacity (VC) (Correct Answer)
Compliance of blood vessels Explanation: ***Inhaling the entire vital capacity (VC)***
- As lung volume increases from FRC to TLC (which includes inhaling the entire VC), alveolar vessels are **stretched open**, and extra-alveolar vessels are **pulled open** by the increased radial traction, leading to a decrease in PVR.
- This **maximizes the cross-sectional area** of the pulmonary vascular bed, lowering resistance.
*Inhaling the inspiratory reserve volume (IRV)*
- While inhaling IRV increases lung volume, it's not the maximal inspiration of the entire VC where **PVR is typically at its lowest**.
- PVR continues to decrease as lung volume approaches total lung capacity (TLC).
*Exhaling the entire vital capacity (VC)*
- Exhaling the entire vital capacity leads to very low lung volumes, where PVR significantly **increases**.
- At low lung volumes, **alveolar vessels become compressed** and extra-alveolar vessels **narrow**, increasing resistance.
*Exhaling the expiratory reserve volume (ERV)*
- Exhaling the ERV results in a lung volume below FRC, which causes a **marked increase in PVR**.
- This is due to the **compression of alveolar vessels** and decreased radial traction on extra-alveolar vessels.
*Breath holding maneuver at functional residual capacity (FRC)*
- At FRC, the PVR is at an **intermediate level**, not its lowest.
- This is the point where the opposing forces affecting alveolar and extra-alveolar vessels are somewhat balanced, but not optimized for minimal resistance.
Compliance of blood vessels US Medical PG Question 3: A 27-year-old man is brought to the emergency department 30 minutes after being shot in the abdomen during a violent altercation. His temperature is 36.5°C (97.7°F), pulse is 118/min and regular, and blood pressure is 88/65 mm Hg. Examination shows cool extremities. Abdominal examination shows a 2.5-cm entrance wound in the left upper quadrant at the midclavicular line, below the left costal margin. Focused ultrasound shows free fluid in the left upper quadrant. Which of the following sets of hemodynamic changes is most likely in this patient?
Cardiac output (CO) | Pulmonary capillary wedge pressure (PCWP) | Systemic vascular resistance (SVR) | Central venous pressure (CVP)
- A. ↑ ↓ ↓ ↓
- B. ↓ ↓ ↑ ↑
- C. ↓ ↓ ↓ ↓
- D. ↓ ↓ ↑ ↓ (Correct Answer)
- E. ↓ ↑ ↑ ↑
Compliance of blood vessels Explanation: ***↓ ↓ ↑ ↓***
- This patient is in **hypovolemic shock** due to hemorrhage, leading to decreased **cardiac output (CO)** and **pulmonary capillary wedge pressure (PCWP)** due to reduced preload.
- The body compensates for hypovolemia by increasing **systemic vascular resistance (SVR)** to maintain perfusion to vital organs, while **central venous pressure (CVP)** decreases due to the depleted blood volume.
*↑ ↓ ↓ ↓*
- An increased **cardiac output** is inconsistent with hypovolemic shock, where the heart's ability to pump blood is compromised by a lack of circulating volume.
- While **PCWP**, **SVR**, and **CVP** decreasing could be seen in some forms of shock, the elevated CO rules out hypovolemic shock.
*↓ ↓ ↑ ↑*
- An elevated **central venous pressure (CVP)** is inconsistent with hypovolemic shock, as CVP reflects right atrial pressure and would be low due to decreased blood volume.
- While other parameters such as **CO** and **PCWP** decreasing and **SVR** increasing can be seen in hypovolemic shock, the increased CVP suggests a different hemodynamic state, like cardiogenic shock.
*↓ ↓ ↓ ↓*
- A decrease in **systemic vascular resistance (SVR)** is characteristic of **distributive shock** (e.g., septic or neurogenic shock), not hypovolemic shock, where compensatory vasoconstriction would lead to increased SVR.
- While **CO**, **PCWP**, and **CVP** would decrease due to overall poor perfusion, the SVR response differentiates it from hypovolemic shock.
*↓ ↑ ↑ ↑*
- An elevated **pulmonary capillary wedge pressure (PCWP)** and **central venous pressure (CVP)** indicate increased fluid volume or cardiac dysfunction, which is contrary to the reduced preload seen in hypovolemic shock.
- While **cardiac output (CO)** may decrease in cardiogenic shock, the other elevated pressures point away from a primary hypovolemic cause.
Compliance of blood vessels US Medical PG Question 4: A 60-year-old male engineer who complains of shortness of breath when walking a few blocks undergoes a cardiac stress test because of concern for coronary artery disease. During the test he asks his cardiologist about what variables are usually used to quantify the functioning of the heart. He learns that one of these variables is stroke volume. Which of the following scenarios would be most likely to lead to a decrease in stroke volume?
- A. Anxiety
- B. Heart failure (Correct Answer)
- C. Exercise
- D. Pregnancy
- E. Digitalis
Compliance of blood vessels Explanation: ***Heart failure***
- In **heart failure**, the heart's pumping ability is impaired, leading to a reduced **ejection fraction** and thus a decreased **stroke volume**.
- The weakened myocardium cannot effectively contract to expel the normal volume of blood, resulting in lower blood output per beat.
*Anxiety*
- **Anxiety** typically causes an increase in **sympathetic nervous system** activity, leading to increased heart rate and myocardial contractility.
- This often results in a temporary **increase in stroke volume** due to enhanced cardiac performance, not a decrease.
*Exercise*
- During **exercise**, there is a significant **increase in venous return** and sympathetic stimulation, leading to increased **end-diastolic volume** and contractility.
- This physiological response causes a substantial **increase in stroke volume** to meet the body's higher oxygen demands.
*Pregnancy*
- **Pregnancy** leads to significant **physiological adaptations** to accommodate the growing fetus, including a substantial increase in **blood volume**.
- This increased blood volume and cardiac output result in an **increase in stroke volume** to maintain adequate perfusion for both mother and fetus.
*Digitalis*
- **Digitalis** is a cardiac glycoside that **increases intracellular calcium** in myocardial cells, enhancing the **force of contraction**.
- This positive inotropic effect leads to an **increased stroke volume** by improving the heart's pumping efficiency.
Compliance of blood vessels US Medical PG Question 5: An investigator is studying the effect of antihypertensive drugs on cardiac output and renal blood flow. For comparison, a healthy volunteer is given a placebo and a continuous infusion of para-aminohippuric acid (PAH) to achieve a plasma concentration of 0.02 mg/ml. His urinary flow rate is 1.5 ml/min and the urinary concentration of PAH is measured to be 8 mg/ml. His hematocrit is 50%. Which of the following values best estimates cardiac output in this volunteer?
- A. 8 L/min
- B. 3 L/min
- C. 4 L/min
- D. 1.2 L/min
- E. 6 L/min (Correct Answer)
Compliance of blood vessels Explanation: ***6 L/min***
- This value represents the estimated **cardiac output** based on the calculated renal blood flow.
- Step 1: Calculate renal plasma flow (RPF) using PAH clearance: RPF = (Urinary PAH × Urine flow rate) / Plasma PAH = (8 mg/ml × 1.5 ml/min) / 0.02 mg/ml = 600 ml/min = 0.6 L/min
- Step 2: Calculate renal blood flow (RBF): Since hematocrit is 50%, RBF = RPF / (1 - Hematocrit) = 0.6 / 0.5 = 1.2 L/min
- Step 3: Estimate cardiac output: The kidneys normally receive approximately **20-25% of cardiac output**. Using 20%: Cardiac Output = RBF / 0.20 = 1.2 / 0.20 = **6 L/min**
- This is consistent with normal resting cardiac output in a healthy adult.
*8 L/min*
- This value overestimates cardiac output based on the renal blood flow calculation.
- While some individuals may have higher cardiac output during exercise, the calculated RBF of 1.2 L/min suggests a resting cardiac output closer to 6 L/min.
*3 L/min*
- This value significantly underestimates cardiac output.
- If cardiac output were 3 L/min, the kidneys would be receiving 40% of cardiac output (1.2/3), which is physiologically implausible at rest.
*4 L/min*
- This value underestimates cardiac output based on the renal data.
- This would mean kidneys receive 30% of cardiac output (1.2/4), which is higher than the typical 20-25%.
*1.2 L/min*
- This is the calculated **renal blood flow**, not cardiac output.
- While this calculation is correct for RBF, the question specifically asks for cardiac output estimation, which requires accounting for the fact that kidneys receive only about 20-25% of total cardiac output.
Compliance of blood vessels US Medical PG Question 6: A 70-year-old man comes to the physician for a follow-up examination of diffuse exertional chest pain which he has successfully been treating with sublingual nitroglycerin for the past year. The patient has been taking lisinopril daily for essential hypertension. His pulse is 75/min and regular, and blood pressure is 155/90 mm Hg. Cardiac and pulmonary examination show no abnormalities; there is no peripheral edema. A decrease of which of the following is the most likely explanation for the improvement of this patient's chest pain?
- A. Ventricular compliance
- B. Venous pooling
- C. End-diastolic pressure (Correct Answer)
- D. Peripheral arterial resistance
- E. Electrical conduction speed
Compliance of blood vessels Explanation: ***End-diastolic pressure***
- Sublingual nitroglycerin primarily works by causing **venodilation**, which leads to a decrease in **venous return** to the heart.
- Reduced venous return results in a lower **end-diastolic volume** and consequently, a lower **end-diastolic pressure**, thereby decreasing **preload** and myocardial oxygen demand.
*Ventricular compliance*
- **Ventricular compliance** refers to the ventricle's ability to stretch and fill, and while nitroglycerin can slightly affect it through reduced pressure, it's not the primary mechanism for improving anginal symptoms.
- A decrease in compliance would generally worsen performance, not improve chest pain, as it would make it harder for the ventricle to fill.
*Venous pooling*
- Nitroglycerin causes **vasodilation**, trapping blood in the peripheral veins, which is a mechanism leading to **decreased venous return**, not a descriptor of the improvement.
- **Increased venous pooling** is the action of nitroglycerin, but the *decrease* in venous pooling would imply less blood trapped in veins, increasing cardiac preload.
*Peripheral arterial resistance*
- While nitroglycerin can cause some **arterial dilation**, leading to a decrease in **afterload**, its predominant effect in relieving angina is through venodilation and preload reduction.
- **Lisinopril**, an ACE inhibitor, primarily reduces afterload by decreasing systemic vascular resistance, which is already being taken by the patient.
*Electrical conduction speed*
- Nitroglycerin has no significant direct effect on the **electrical conduction system** of the heart.
- Changes in electrical conduction speed are related to conditions like **arrhythmias** or medications such as **beta-blockers** or **calcium channel blockers**, not a direct effect of nitrates for angina relief.
Compliance of blood vessels US Medical PG Question 7: A 65-year-old man comes to the physician for a routine examination. He feels well. His pulse is 80/min and blood pressure is 140/85 mm Hg. Cardiac examination shows a holosystolic murmur in the 4th intercostal space along the left sternal border that gets louder during inspiration. The increase of this patient's murmur is best explained by which of the following hemodynamic changes?
- A. Increased systemic venous compliance
- B. Decreased pulmonary vessel capacity
- C. Decreased left ventricular preload
- D. Increased peripheral vascular resistance
- E. Increased right ventricular stroke volume (Correct Answer)
Compliance of blood vessels Explanation: ***Increased right ventricular stroke volume***
- The murmur's location at the **left sternal border** in the 4th intercostal space, combined with its **holosystolic** nature and **inspiratory increase**, points to **tricuspid regurgitation**.
- During **inspiration**, intrathoracic pressure decreases, leading to **increased venous return** to the right side of the heart, thereby increasing the **right ventricular stroke volume** and the intensity of a right-sided murmur.
*Increased systemic venous compliance*
- An increase in systemic venous compliance would cause a **decrease in venous return** to the right heart due to venous pooling, which would **decrease** the intensity of right-sided murmurs.
- This condition would lead to a reduction in preload, not an increase needed to augment the murmur.
*Decreased pulmonary vessel capacity*
- A decrease in pulmonary vessel capacity would primarily affect **pulmonary hypertension** and right ventricular afterload, rather than directly increasing right ventricular stroke volume or the intensity of a tricuspid regurgitation murmur during inspiration.
- It would hinder blood flow from the right ventricle to the pulmonary artery, not enhance it.
*Decreased left ventricular preload*
- While deep inspiration can mildly decrease left ventricular preload due to pooling of blood in the pulmonary circulation, this effect is relevant for **left-sided murmurs** and would cause their intensity to **decrease**.
- This change would not explain the observed increase in a right-sided murmur.
*Increased peripheral vascular resistance*
- Increased peripheral vascular resistance would primarily affect the **left side of the heart** as the left ventricle would have to pump against a higher afterload.
- This would typically **increase** the intensity of **left-sided murmurs** like aortic stenosis or mitral regurgitation but would not directly explain the inspiratory increase of a right-sided murmur.
Compliance of blood vessels US Medical PG Question 8: An otherwise healthy 65-year-old man comes to the physician for a follow-up visit for elevated blood pressure. Three weeks ago, his blood pressure was 160/80 mmHg. Subsequent home blood pressure measurements at days 5, 10, and 15 found: 165/75 mm Hg, 162/82 mm Hg, and 170/80 mmHg, respectively. He had a cold that was treated with over-the-counter medication 4 weeks ago. Pulse is 72/min and blood pressure is 165/79 mm Hg. Physical examination shows no abnormalities. Laboratory studies, including thyroid function studies, serum electrolytes, and serum creatinine, are within normal limits. Which of the following is the most likely underlying cause of this patient's elevated blood pressure?
- A. Decrease in arterial compliance (Correct Answer)
- B. Increase in left ventricular end-diastolic volume
- C. Increase in aldosterone production
- D. Decrease in baroreceptor sensitivity
- E. Medication-induced vasoconstriction
Compliance of blood vessels Explanation: ***Decrease in arterial compliance***
- In elderly patients, **systolic hypertension** (isolated or combined) is commonly caused by **stiffening of the large arteries** (aorta and its major branches), which is a decrease in **arterial compliance**. This leads to a higher systolic pressure needed to eject blood into the stiffened vessels.
- The patient's age (65), persistent elevated systolic blood pressure readings with relatively normal diastolic pressure (though slightly elevated), and the absence of other obvious causes point towards **age-related arterial stiffness**.
*Increase in left ventricular end-diastolic volume*
- An increase in **left ventricular end-diastolic volume (LVEDV)** typically increases **preload** and **cardiac output**, which can contribute to hypertension.
- However, primary hypertension in older adults is more directly linked to **arterial stiffness**, which impacts systolic pressure more profoundly than changes in LVEDV alone.
*Increase in aldosterone production*
- Increased **aldosterone production** (primary hyperaldosteronism) causes hypertension primarily by increasing **sodium and water retention**, leading to **volume expansion** and often accompanied by **hypokalemia**.
- This patient has **normal serum electrolytes**, making primary hyperaldosteronism less likely as the primary cause of his hypertension.
*Decrease in baroreceptor sensitivity*
- A decrease in **baroreceptor sensitivity** can contribute to **blood pressure lability** and impaired compensatory responses to postural changes, but it is not the primary underlying mechanism for sustained, consistently elevated systolic blood pressure in essential hypertension in the elderly.
- While age can affect baroreceptor function, **arterial stiffness** is a more direct cause of the observed systolic hypertension.
*Medication-induced vasoconstriction*
- Some over-the-counter medications, particularly **decongestants** (e.g., pseudoephedrine), can cause **vasoconstriction** and elevate blood pressure.
- However, the patient's cold was 4 weeks ago, and his current symptoms and blood pressure elevations are sustained and occurred *after* the cold resolved and with normal examination, suggesting a more chronic rather than acute medication-induced effect.
Compliance of blood vessels US Medical PG Question 9: A 66-year-old man is brought to the emergency department 20 minutes after being involved in a high-speed motor vehicle collision in which he was the unrestrained passenger. His wife confirms that he has hypertension, atrial fibrillation, and chronic lower back pain. Current medications include metoprolol, warfarin, hydrochlorothiazide, and oxycodone. On arrival, he is lethargic and confused. His pulse is 112/min, respirations are 10/min, and blood pressure is 172/78 mm Hg. The eyes open spontaneously. The pupils are equal and sluggish. He moves his extremities in response to commands. There is a 3-cm scalp laceration. There are multiple bruises over the right upper extremity. Cardiopulmonary examination shows no abnormalities. The abdomen is soft and nontender. Neurologic examination shows no focal findings. Two large-bore peripheral intravenous catheters are inserted. A 0.9% saline infusion is begun. A focused assessment with sonography in trauma is negative. Plain CT of the brain shows a 5-mm right subdural hematoma with no mass effect. Fresh frozen plasma is administered. Which of the following is most likely to reduce this patient's cerebral blood flow?
- A. Hyperventilation (Correct Answer)
- B. Lumbar puncture
- C. Decompressive craniectomy
- D. Intravenous hypertonic saline
- E. Intravenous mannitol
Compliance of blood vessels Explanation: ***Hyperventilation***
- **Hyperventilation** reduces arterial partial pressure of carbon dioxide (**PaCO2**), causing **cerebral vasoconstriction** and thereby decreasing cerebral blood flow (CBF).
- This effect is used therapeutically to transiently lower **intracranial pressure (ICP)** in cases of acute cerebral edema or herniation by reducing cerebral blood volume.
*Lumbar puncture*
- A **lumbar puncture** drains cerebrospinal fluid (CSF) from the subarachnoid space, which would reduce ICP.
- However, it does not directly impact cerebral blood flow regulations, and in some situations with elevated ICP, it can be hazardous due to the risk of **herniation**.
*Decompressive craniectomy*
- **Decompressive craniectomy** involves removing a portion of the skull to allow the brain to swell, directly reducing ICP by increasing intracranial volume.
- While it lowers ICP, it doesn't directly reduce cerebral blood flow; in fact, by relieving compression, it may help maintain or improve CBF.
*Intravenous hypertonic saline*
- **Intravenous hypertonic saline** increases serum osmolarity, drawing fluid out of brain cells and into the intravascular space, thereby reducing **cerebral edema** and ICP.
- This reduction in edema and ICP can improve rather than reduce cerebral blood flow by reducing extrinsic compression of cerebral vessels.
*Intravenous mannitol*
- **Intravenous mannitol** is an osmotic diuretic that creates an osmotic gradient, drawing fluid from the brain parenchyma into the intravascular compartment, reducing **cerebral edema** and ICP.
- Similar to hypertonic saline, its primary effect is to decrease brain volume and ICP, which tends to improve CBF by reducing vascular compression, not reduce it.
Compliance of blood vessels US Medical PG Question 10: A 55-year-old woman is brought to the emergency department because of worsening upper abdominal pain for 8 hours. She reports that the pain radiates to the back and is associated with nausea. She has hypertension and hyperlipidemia, for which she takes enalapril, furosemide, and simvastatin. Her temperature is 37.5°C (99.5 °F), blood pressure is 84/58 mm Hg, and pulse is 115/min. The lungs are clear to auscultation. Examination shows abdominal distention with epigastric tenderness and guarding. Bowel sounds are decreased. Extremities are warm. Laboratory studies show:
Hematocrit 48%
Leukocyte count 13,800/mm3
Platelet count 175,000/mm3
Serum:
Calcium 8.0 mg/dL
Urea nitrogen 32 mg/dL
Amylase 250 U/L
An ECG shows sinus tachycardia. Which of the following is the most likely underlying cause of this patient's vital sign abnormalities?
- A. Hemorrhagic fluid loss
- B. Capillary leakage (Correct Answer)
- C. Decreased cardiac output
- D. Decreased albumin concentration
- E. Increased excretion of water
Compliance of blood vessels Explanation: ***Capillary leakage***
- The patient's presentation with **pancreatitis** (epigastric pain radiating to the back, nausea, elevated amylase, epigastric tenderness, guarding) can lead to widespread **capillary leakage** and **third-space fluid sequestration**.
- This leakage results in **intravascular volume depletion**, manifesting as **hypotension** (84/58 mm Hg) and **tachycardia** (115/min), despite seemingly normal extremities.
*Hemorrhagic fluid loss*
- While bleeding can cause similar vital sign changes, a **hematocrit of 48%** makes significant acute hemorrhage unlikely.
- There are no other clinical signs of bleeding, such as **ecchymosis** or **melena**.
*Decreased cardiac output*
- While ultimately leading to hypotension and tachycardia, **decreased cardiac output** in this context is a *consequence* of **intravascular hypovolemia due to capillary leakage**, not the primary underlying cause.
- The underlying issue is the loss of effective circulating volume, not pump failure.
*Decreased albumin concentration*
- **Hypoalbuminemia** contributes to reduced plasma oncotic pressure and can worsen capillary leakage and edema, but it is typically a more chronic condition and not the immediate primary cause of acute, rapid intravascular volume depletion leading to shock in this setting.
- The presented vital signs suggest a more immediate and acute fluid shift.
*Increased excretion of water*
- **Increased water excretion**, such as from **diuretic use** (furosemide), could contribute to hypovolemia, but the acute and severe nature of the patient's symptoms along with signs of peritonitis and elevated amylase point more strongly to pancreatitis-induced fluid shifts as the primary cause.
- Furthermore, pancreatitis itself is a significant driver of fluid loss into the retroperitoneum and peritoneal cavity.
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