Cardiovascular Dynamics During Exercise Chapters 15 16 Introduction
- Slides: 55
Cardiovascular Dynamics During Exercise Chapters 15 & 16
Introduction At rest: O 2 supply = O 2 demand Exercise: O 2 demand increases To the muscles To the heart To the skin Maintain flow to the brain How does the heart increase O 2 supply to meet the O 2 demand?
Cardiac Output Q = heart rate times stroke volume
Cardiac Output Blood flow per minute. At rest Q = 5 -6 liters/min Q increases linearly with the demand for more O 2 Indicator of oxygen supply
How does cardiac output increase? Increase heart rate Increase stroke volume
Heart Rate Resting heart rate Anxiety Dehydration Temperature Digestion Over-training The most important factor for increasing Q during acute exercise.
Heart Rate What causes HR to increase during exercise? Decrease parasympathetic (vagal) stimulation Increase sympathetic stimulation
Heart Rate Steady state exercise Why does heart rate level off during steady state exercise?
Heart Rate Increases with intensity and levels off at maximal effort. – HRmax = 220 – age – (± 12)
Stroke Volume pumped per beat of the heart Influenced by preload and afterload
Stroke Volume Increases until about 25 -50% of maximum After that it may plateau (untrained) or continue to increase (trained) Decrease at maximum effort?
Stroke Volume How does stroke volume increase during exercise? Increase preload (EDV) – Increase venous return • Muscle pump, etc. Decrease afterload – Vasodilation • Metabolic control and sympathetic stimulation Increase contractility (ESV) – Increase sympathetic stimulation
Frank-Starling Mechanism Frank-Starling mechanism: the ability of the heart to alter the force of contraction is dependent on changes in preload. As the myocardial fibers are stretched, the force of contraction is increased. Because the length of the fiber is determined primarily by the volume of blood in the ventricle, EDV is the primary determinant of preload
This graph depicts the Frank-Starling mechanism of compensation in CHF. The black curves represent ventricular function in a normal subject and the colored curve is with left ventricular dysfunction. Line N to A represents the initial reduction in cardiac output due to CHF. Line A to B represents the Frank-Starling mechanism of compensation; an increase in left ventricular end-diastolic pressure needed to maintain cardiac output.
Stroke Volume
Stroke Volume Increased sympathetic stimulation Vasodilation from ‘autoregulation’
Cardiovascular drift Caused by a decrease in venous return Cardiac output is maintained by…. . ?
Cardiovascul ar Drift
Stroke Volume SV greater in trained Most significant effect of training
Result • • An increase in cardiac output… • Increase HR • Increase SV …results in an increase in O 2 supply
Hemodynamics
Blood Vessels Arteries Arterioles Capillaries Venules Veins
Physical Characteristics of • Plasma Blood Liquid portion of blood Contains ions, proteins, hormones • Cells Red blood cells Contain hemoglobin to carry oxygen White blood cells Platelets
The Blood Arterial blood carries 20 ml of oxygen per 100 ml of blood
Hematocrit Percent of blood composed of cells
The Blood • Arterial blood: 97 -98% saturated with O 2 • Venous blood – Rest – 75% – Exercise – 25%
Blood Pressure Expressed as systolic/diastolic Normal is 120/80 mm. Hg High is ≥ 140/90 mm. Hg Systolic pressure (top number) Pressure generated during ventricular contraction (systole) Diastolic pressure Pressure in the arteries during cardiac relaxation
Blood Pressure • Pulse pressure Difference between systolic and diastolic Pulse Pressure = Systolic - Diastolic • Mean arterial pressure (MAP) Average pressure in the arteries MAP = Diastolic + 1/3(pulse pressure)
Mean Arterial Pressure • Blood pressure of 120/80 mm Hg • MAP = 80 mm Hg +. 33(120 -80) • • = 80 mm Hg + 13 = 93 mm Hg
Hemodynamics • Based on interrelationships between: – Pressure – Resistance
Hemodynamics: Pressure Blood flows from high →low pressure Proportional to the difference between MAP and right atrial pressure (ΔP)
Blood Flow Through the Systemic Circuit
Hemodynamics: Resistance depends upon: Length of the vessel Viscosity of the blood Radius of the vessel A small change in vessel diameter can have a dramatic impact on resistance! Length x viscosity Resistance = Radius 4
Hemodynamics: Blood Flow Directly proportional to the pressure difference between the two ends of the system Inversely proportional to resistance Δ Pressure Flow = Resistance
Sources of Vascular Resistance MAP decreases throughout the systemic circulation Largest drop occurs across the arterioles Arterioles are called “resistance vessels”
Pressure Changes Across the Systemic Circulation
Pressure Changes During the Cardiac Cycle
Factors That Influence Arterial Blood Pressure
Cardiovascular Control
How can the blood vessels increase blood flow? Vasodilation to increase blood flow to muscles and skin Waste products (metabolic or local control) Sympathetic stimulation (cholinergic) Vasoconstriction to maintain blood pressure Sympathetic stimulation (adrenergic) Maximum muscle blood flow is limited by the ability to maintain blood pressure
Vasodilation Vasoconstriction
Blood Vessels
Oxygen Extraction Measured as a-v O 2 difference • a = O 2 in arteries (20 ml/100 ml of blood) • v = O 2 in veins (15 ml/100 ml of blood) • (a-v)O 2 = 5 ml/100 ml of blood
a-v O 2 difference No change in O 2 content in the blood Remains at 20 ml/100 ml of blood Decrease in O 2 inside the muscle High pressure to a Low pressure Greater pressure difference between the blood and the muscles Oxygen moves from a HIGH pressure area (blood) to a LOW pressure area (muscle) Therefore, more O 2 is extracted from the blood High pressure to a Lower pressure
RESTING 20 ml or P 02 98 EXERCISE 20 ml or P 02 98 5 ml extracted PO 2 = 40 15 ml extracted PO 2 = 20 Lower PO 2 due to an increase in O 2 consumption (VO 2) during exercise
Oxygen Consumption VO 2 liters per minute milliliters per kilogram per minute VO 2 = oxygen supply x oxygen extraction VO 2 = Q x a-v O 2 difference VO 2 = HR x SV x a-v O 2 difference
Oxygen Consumption An increase in oxygen supply leads to an increase in oxygen consumption Increase in cardiac output With help from HR and SV Increase in (a-v)O 2 More O 2 is supplied and extracted Therefore, more O 2 can be used by the muscle fibers (mito)
Oxygen Consumption Q and a-v O 2 difference each account for 50% of the increase in VO 2 during exercise Near maximal exercise, Q accounts for 75% of the increase in VO 2
Oxygen Consumption VO 2 increases with intensity VO 2 = rate of blood flow times the O 2 extracted from a given amount of blood VO 2 = cardiac output x a-v. O 2 difference VO 2 can increase by A greater blood flow Taking more oxygen out of every 100 ml of blood
What limits aerobic exercise? Lack of oxygen supply? If so, wouldn’t the muscles be more anaerobic? And, wouldn’t the heart also be more anaerobic? But an anaerobic heart produces angina Maybe the central nervous system protects the heart from ischemia by causing muscle fatigue before the heart becomes
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