Stroke Volume Calculator
Use our free Stroke volume Calculator to get personalized health results. Based on validated medical formulas and clinical guidelines.
Formula
SV = EDV - ESV | EF = (SV/EDV) x 100 | CO = SV x HR | CI = CO/BSA
Where SV = Stroke Volume (mL), EDV = End-Diastolic Volume (mL), ESV = End-Systolic Volume (mL), EF = Ejection Fraction (%), CO = Cardiac Output (L/min), HR = Heart Rate (bpm), CI = Cardiac Index (L/min/m2), BSA = Body Surface Area (m2).
Worked Examples
Example 1: Normal Heart Function Assessment
Problem: A patient has an end-diastolic volume of 120 mL, end-systolic volume of 45 mL, heart rate of 70 bpm, and BSA of 1.85 m2. Calculate stroke volume, ejection fraction, cardiac output, and cardiac index.
Solution: Stroke Volume = EDV - ESV = 120 - 45 = 75 mL\nEjection Fraction = (75 / 120) x 100 = 62.5%\nCardiac Output = (75 x 70) / 1000 = 5.25 L/min\nCardiac Index = 5.25 / 1.85 = 2.84 L/min/m2\nStroke Volume Index = 75 / 1.85 = 40.5 mL/m2
Result: SV: 75 mL | EF: 62.5% (Normal) | CO: 5.25 L/min | CI: 2.84 L/min/m2 (Normal)
Example 2: Heart Failure Assessment
Problem: A patient with dilated cardiomyopathy has EDV of 200 mL, ESV of 140 mL, heart rate of 95 bpm, and BSA of 2.0 m2. Calculate hemodynamic parameters.
Solution: Stroke Volume = EDV - ESV = 200 - 140 = 60 mL\nEjection Fraction = (60 / 200) x 100 = 30.0%\nCardiac Output = (60 x 95) / 1000 = 5.70 L/min\nCardiac Index = 5.70 / 2.0 = 2.85 L/min/m2\nStroke Volume Index = 60 / 2.0 = 30.0 mL/m2\nNote: Despite compensatory tachycardia maintaining near-normal CO, the EF of 30% indicates severely reduced systolic function.
Result: SV: 60 mL | EF: 30% (Severely Reduced) | CO: 5.70 L/min | CI: 2.85 L/min/m2
Frequently Asked Questions
What is stroke volume and why is it important in cardiovascular assessment?
Stroke volume is the amount of blood ejected by the left ventricle during each cardiac contraction, measured in milliliters per beat. It is calculated as the difference between end-diastolic volume (the amount of blood in the ventricle at the end of filling) and end-systolic volume (the amount remaining after contraction). Normal stroke volume ranges from 60 to 100 milliliters per beat in healthy adults. This measurement is fundamentally important because it directly reflects the pumping efficiency of the heart. A decreased stroke volume indicates that the heart is not pumping effectively, which can occur in conditions such as heart failure, cardiomyopathy, and severe valve disease. Clinicians use stroke volume alongside heart rate to calculate cardiac output, the total volume of blood pumped per minute.
What is cardiac output and how does it relate to stroke volume?
Cardiac output is the total volume of blood the heart pumps per minute, calculated by multiplying stroke volume by heart rate. The formula is CO = SV x HR. Normal cardiac output ranges from 4 to 8 liters per minute in resting adults. This relationship means that cardiac output can be maintained through compensatory mechanisms even when one component is abnormal. For example, if stroke volume decreases due to heart failure, the body compensates by increasing heart rate to maintain adequate cardiac output. Conversely, athletes often have larger stroke volumes due to cardiac remodeling, allowing them to maintain higher cardiac output at lower heart rates. Understanding this relationship is essential for managing patients in critical care settings, where optimizing cardiac output is a primary goal of hemodynamic management.
What factors affect stroke volume in healthy and diseased hearts?
Stroke volume is determined by three primary physiological factors: preload, afterload, and contractility. Preload refers to the degree of ventricular stretching at end-diastole, governed by the Frank-Starling mechanism where greater stretch produces stronger contraction up to a physiological limit. Afterload is the resistance the ventricle must overcome to eject blood, primarily determined by systemic vascular resistance and aortic pressure. Contractility is the intrinsic strength of cardiac muscle contraction independent of loading conditions. In disease states, each factor can be adversely affected. Heart failure reduces contractility, hypertension increases afterload, and dehydration reduces preload. Medications target these factors specifically: diuretics reduce preload, vasodilators reduce afterload, and inotropes enhance contractility. Understanding which factor predominates in a given clinical scenario guides appropriate therapeutic intervention.
How is stroke volume measured clinically using echocardiography?
Echocardiography is the primary noninvasive method for measuring stroke volume in clinical practice. The most common approach uses the left ventricular outflow tract (LVOT) method, which applies the principle that flow through a tube equals the cross-sectional area multiplied by the velocity-time integral (VTI). The LVOT diameter is measured in the parasternal long-axis view, and the area is calculated using the formula for a circle. The VTI is obtained using pulsed-wave Doppler in the apical five-chamber view. Stroke volume equals LVOT area multiplied by LVOT VTI. Alternative methods include the biplane Simpson method, which traces endocardial borders at end-diastole and end-systole to calculate volumes directly. Three-dimensional echocardiography provides even more accurate volume measurements by avoiding geometric assumptions inherent in two-dimensional techniques.
What is the significance of stroke volume variation in critical care monitoring?
Stroke volume variation (SVV) is a dynamic hemodynamic parameter that measures the percentage change in stroke volume during the respiratory cycle in mechanically ventilated patients. It is calculated as SVV = (SVmax - SVmin) / SVmean x 100. During positive pressure ventilation, inspiration increases intrathoracic pressure, which reduces venous return and right ventricular preload, causing a transient decrease in stroke volume. An SVV greater than 12 to 13 percent generally indicates that the patient is fluid-responsive, meaning that additional intravenous fluid administration will increase cardiac output. This concept has revolutionized fluid management in critical care by allowing goal-directed therapy rather than arbitrary fluid administration. SVV monitoring helps avoid both under-resuscitation and fluid overload, both of which worsen patient outcomes in surgical and septic patients.
How do valvular heart diseases affect stroke volume measurements?
Valvular heart diseases significantly impact stroke volume in different ways depending on the valve affected and the type of lesion. Aortic stenosis reduces effective stroke volume by creating an obstruction to outflow, though the ventricle may compensate through hypertrophy to maintain stroke volume initially. Aortic regurgitation causes volume overload as blood leaks back into the ventricle during diastole, increasing EDV and total stroke volume but reducing effective forward stroke volume. Mitral regurgitation allows blood to flow backward into the left atrium during systole, reducing effective forward cardiac output while the total stroke volume may appear normal or elevated. Mitral stenosis restricts filling of the left ventricle, reducing EDV and consequently stroke volume. Understanding these hemodynamic effects is essential for accurate interpretation of echocardiographic measurements and for determining the severity of valve disease.