A 19-year-old man presents to the clinic with a complaint of increasing shortness of breath for the past 2 years. His shortness of breath is associated with mild chest pain and occasional syncopal attacks during strenuous activity. There is no history of significant illness in the past, however, one of his uncles had similar symptoms when he was his age and died while playing basketball a few years later. He denies alcohol use, tobacco consumption, and the use of recreational drugs. On examination, pulse rate is 76/min and is regular and bounding; blood pressure is 130/70 mm Hg. A triple apical impulse is observed on the precordium and a systolic ejection crescendo-decrescendo murmur is audible between the apex and the left sternal border along with a prominent fourth heart sound. The physician then asks the patient to take a deep breath, close his mouth, and pinch his nose and try to breathe out without allowing his cheeks to bulge out. In doing so, the intensity of the murmur increases. Which of the following hemodynamic changes would be observed first during this maneuver?

↑ Mean Arterial Pressure, ↓ Heart rate, ↑ Baroreceptor activity, ↑ Parasympathetic Outflow

↓ Mean Arterial Pressure, ↑ Heart rate, ↑ Baroreceptor activity, ↓ Parasympathetic Outflow

↑ Mean Arterial Pressure, ↓ Heart rate, ↓ Baroreceptor activity, ↑ Parasympathetic Outflow

↑ Mean Arterial Pressure, ↑ Heart rate, ↓ Baroreceptor activity, ↓ Parasympathetic Outflow

↑ Mean Arterial Pressure, ↑ Heart rate, ↑ Baroreceptor activity, ↑ Parasympathetic Outflow

A 37-year-old male presents to your clinic with shortness of breath and lower extremity edema. He was born in Southeast Asia and emigrated to America ten years prior. Examination demonstrates 2+ pitting edema to the level of his knees, ascites, and bibasilar crackles, as well as an opening snap followed by a mid-to-late diastolic murmur. The patient undergoes a right heart catheterization that demonstrates a pulmonary capillary wedge pressure (PCWP) of 24 mmHg. The patient is most likely to have which of the following?

Normal or decreased left ventricular end diastolic pressure (LVEDP)

Decreased pulmonary artery systolic pressure (PASP)

Increased left ventricular end diastolic pressure (LVEDP)

Increased pulmonary vascular compliance

A 53-year-old man with a past medical history significant for hyperlipidemia, hypertension, and hyperhomocysteinemia presents to the emergency department complaining of 10/10 crushing, left-sided chest pain radiating down his left arm and up his neck into the left side of his jaw. His ECG shows ST-segment elevation in leads V2-V4. He is taken to the cardiac catheterization laboratory for successful balloon angioplasty and stenting of a complete blockage in his left anterior descending coronary artery. Echocardiogram the following day shows decreased left ventricular function and regional wall motion abnormalities. A follow-up echocardiogram 14 days later shows a normal ejection fraction and no regional wall motion abnormalities. This post-infarct course illustrates which of the following concepts?

Coronary collateral circulation

A 36-year-old woman is admitted to the hospital for the evaluation of progressive breathlessness. She has no history of major medical illness. Her temperature is 37°C (98.6°F), pulse is 110/min, and respirations are 22/min. Pulse oximetry on room air shows an oxygen saturation of 99%. Cardiac examination shows a loud S1 and S2. There is a grade 2/6 early systolic murmur best heard in the 2nd right intercostal space. Cardiac catheterization shows a mixed venous oxygen saturation of 55% (N= 65–70%). Which of the following is the most likely cause of this patient's breathlessness?

Decreased left ventricular ejection fraction

Decreased hemoglobin concentration

Increased carbon dioxide retention

Increased pulmonary vascular resistance

Ventricular ejection physiology for USMLE Step 3: High-Yield Physiology Lessons

Ventricular Ejection - The Big Squeeze

Begins when ventricular pressure surpasses aortic and pulmonary artery pressures, pushing the semilunar valves open.
Blood is forcefully expelled, marking the primary work phase of the heart.
Phases:
- Rapid Ejection: Initial, powerful surge of blood.
- Reduced Ejection: Slower flow as ventricular and arterial pressures start to equalize.
Key Formulas:
- Stroke Volume (SV): $SV = EDV - ESV$
- Ejection Fraction (EF): $EF = (SV / EDV) * 100%$. A critical index of contractility; normal is >55%.

Wiggers Diagram: Cardiac Cycle & Ventricular Ejection

⭐ Afterload is the primary determinant of end-systolic volume (ESV). High afterload (e.g., aortic stenosis, hypertension) increases the pressure the ventricle must overcome, reducing stroke volume and leaving more blood behind (↑ ESV).

Ejection Fraction - The Heart's Report Card

Definition: The percentage of blood ejected from the ventricle with each beat; a key index of systolic function.
Formula: $EF = (SV / EDV) * 100%$
- SV: Stroke Volume
- EDV: End-Diastolic Volume
Normal Range: 55-70%.
Clinical Ranges:
- Heart Failure with reduced EF (HFrEF): $≤ \textbf{40}%$
- Heart Failure with preserved EF (HFpEF): $≥ \textbf{50}%$
Primary Indicator Of: Ventricular contractility. Changes in preload, afterload, or contractility will alter EF.

LVEF calculation and heart failure classifications

⭐ High-Yield Fact: EF can be normal in diastolic heart failure (HFpEF). Patients present with dyspnea and exercise intolerance, but the ventricle's pumping percentage is preserved; the issue is with filling (diastolic dysfunction).

Stroke Volume Determinants - The Three Bosses

Stroke Volume ($SV$) is governed by three factors: Preload, Afterload, and Contractility. $SV = EDV - ESV$.

Preload: Ventricular stretch at end-diastole (EDV).
- ↑ Venous return → ↑ Preload → ↑ SV (Frank-Starling Law).
Afterload: Resistance the ventricle ejects against (approximated by SVR).
- ↑ Afterload → ↓ SV.
Contractility (Inotropy): Intrinsic pump strength.
- ↑ Sympathetic tone (Ca²⁺) → ↑ Contractility → ↑ SV.

Cardiac preload, afterload, contractility, and stroke volume

⭐ Afterload is clinically critical; reducing it with vasodilators is a key strategy in treating systolic heart failure to improve forward flow.

📌 Mnemonic: SV depends on CAP: Contractility, Afterload, Preload.

Clinical Correlations - When Ejection Fails

Heart Failure with Reduced Ejection Fraction (HFrEF): The ventricle fails to eject an adequate stroke volume (SV) due to impaired contractility.
Key Metric: Ejection Fraction (EF) = $(SV / EDV) \times 100$.
- Normal EF: 55-70%.
- HFrEF is diagnosed when EF < 40%.
Consequences:
- ↓ Cardiac Output → fatigue, weakness (hypoperfusion).
- ↑ End-Diastolic Volume (EDV) → pulmonary & systemic congestion (e.g., dyspnea, edema).
Common Causes: Ischemic heart disease, chronic hypertension, dilated cardiomyopathy, valvular disease.

⭐ An S3 heart sound is a hallmark of HFrEF, representing tensing of the chordae tendineae during rapid ventricular filling into a distended ventricle.

High‑Yield Points - ⚡ Biggest Takeaways

Ventricular pressure must exceed aortic and pulmonary artery pressures to open the semilunar valves.

The majority of stroke volume is ejected during the initial rapid ejection phase.

Aortic pressure rises and peaks during this phase due to the rapid influx of blood.

This phase corresponds to the ST segment and T wave on the ECG.

Ejection ends when ventricular pressure falls below aortic/pulmonic pressure, causing semilunar valve closure.

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