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CARDIOVASCULAR CONTROL DURING EXERCISE

CARDIOVASCULAR CONTROL DURING EXERCISE. CARDIOVASCULAR CONTROL DURING EXERCISE. Major Cardiovascular Functions. w Delivery (e.g., oxygen and nutrients). w Removal (e.g., carbon dioxide and waste products). w Transportation (e.g., hormones). w Maintenance (e.g., body temperature, pH).

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CARDIOVASCULAR CONTROL DURING EXERCISE

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  1. CARDIOVASCULAR CONTROL DURING EXERCISE CARDIOVASCULAR CONTROL DURING EXERCISE

  2. Major Cardiovascular Functions w Delivery (e.g., oxygen and nutrients) w Removal (e.g., carbon dioxide and waste products) w Transportation (e.g., hormones) w Maintenance (e.g., body temperature, pH) w Prevention (e.g., infection—immune function)

  3. The Cardiovascular System w A pump (the heart) w A system of channels (the blood vessels) w A fluid medium (blood)

  4. THE HEART

  5. Did You Know…? Arteries always carry blood away from the heart; veins always carry blood back to the heart with the help of breathing, the muscle pump, and valves. Pulmonary “veins” carry oxygenated blood from the lungs to the heart and pulmonary “arteries” carry blood with lower oxygen levels to the lungs for oxygenation.

  6. Myocardium—The Cardiac Muscle w Thickness varies directly with stress placed on chamber walls. w Left ventricle is the most powerful of chambers and thus, the largest. w With vigorous exercise, the left ventricle size increases. w Due to intercalated disks—impulses travel quickly in cardiac muscle and allow it to act as one large muscle fiber; all fibers contract together.

  7. Resting Heart Rate w Averages 60 to 80 beats per minute (bpm); can range from 28 bpm to above 100 bpm w Tends to decrease with age and with increased cardiovascular fitness w Is affected by environmental conditions such as altitude and temperature

  8. Maximum Heart Rate w The highest heart rate value one can achieve in an all-out effort to the point of exhaustion w Remains constant day to day and changes slightly from year to year w Can be estimated: HRmax = 220 – age in years

  9. THE INTRINSIC CONDUCTION SYSTEM

  10. The Cardiac Conduction System w Sinoatrial (SA) node—pacemaker (60-80 beats/min intrinsic heart rate) w Atrioventricular (AV) node—built-in delay of 0.13 sec. w AV bundle (bundle of His) wPurkinje fibers—6 times faster transmission

  11. Did You Know…? Resting heart rates in adults tend to be between 60 and 85 beats per min. However, extended endurance training can lower resting heart rate to 35 beats per minute or less.

  12. Electrocardiogram (ECG) • Records the heart's electrical activity and monitors cardiac changes • Cardiac conduction system

  13. PHASES OF THE RESTING ECG

  14. Cardiac Cycle w Events that occur between two consecutive heartbeats (systole to systole) w Diastole—relaxation phase during which the chambers fill with blood (T wave to QRS)—62% of cycle duration w Systole—contraction phase during which the chambers expel blood (QRS to T wave)—38% of cycle duration

  15. Stroke Volume (SV) w Volume of blood pumped per contraction w End-diastolic volume (EDV)—volume of blood in ventricle before contraction w End-systolic volume (ESV)—volume of blood in ventricle after contraction w SV = EDV – ESV . Cardiac Output (Q) w Total volume of blood pumped by the ventricle per minute . w Q = HR ´ SV Stroke Volume and Cardiac Output

  16. BLOOD DISTRIBUTION AT REST

  17. Functions of the Blood w Transports gas, nutrients, and wastes w Regulates temperature w Buffers and balances acid base

  18. THE COMPOSITION OF TOTAL BLOOD VOLUME

  19. Blood Plasma Volume w Reduced with onset of exercise (goes to interstitial fluid space) w More is lost if exercise results in sweating w Excessive loss can result in impaired performance w Reduction in blood plasma volume results in hemoconcentration

  20. Hematocrit and Blood Formed Elements Ratio of formed elements to the total blood volume w White blood cells—protect body from disease organisms w Blood platelets—cell fragments that help blood coagulation w Red blood cells—carry oxygen to tissues with the help of hemoglobin

  21. Blood Viscosity w Thickness of the blood w The more viscous, the more resistant to flow w Higher hematocrits result in higher blood viscosity

  22. Steady-State Heart Rate w Heart rate plateau reached during constant rate of submaximal work w Optimal heart rate for meeting circulatory demands at that rate of work w The lower the steady-state heart rate, the more efficient the heart

  23. w Heart rate (HR), stroke volume (SV), and cardiac output (Q) increase. . Cardiovascular Response to Acute Exercise w Blood flow and blood pressure change. w All result in allowing the body to meet the increased demands placed on it efficiently.

  24. Stroke Volume w Determinant of cardiorespiratory endurance capacity at maximal rates of work w May increase with increasing rates of work up to intensities of 40% to 60% of max w May continue to increase up through maximal exercise intensity, generally in highly trained athletes • Depends on position of body during exercise • stroke volume video

  25. STROKE VOLUME

  26. STROKE VOLUME INCREASES IN CYCLISTS

  27. w When exercise intensity exceeds 40% to 60%, further increases in Q are more a result of increases in HR than SV since SV tends to plateau at higher work rates. . Cardiac Output w Resting value is approximately 5.0 L/min. w Increases directly with increasing exercise intensity to between 20 to 40 L/min. wThe magnitude of increase varies with body size and endurance conditioning.

  28. CARDIAC OUTPUT DURING EXERCISE

  29. Heart rate Stroke volume Cardiac outputActivity (beats/min) (ml/beat) (L/min) Resting (supine) 55 95 5.2 Resting (standing 60 70 4.2 and sitting) Running 190 130 24.7 Cycling 185 120 22.2 Swimming 170 135 22.9 Changes in Heart Rate, Stroke Volume, and Cardiac Output

  30. Cardiovascular Endurance Exercise w Systolic BP increases in direct proportion to increased exercise intensity w Diastolic BP changes little if any during endurance exercise, regardless of intensity Resistance Exercise w Exaggerates BP responses to as high as 480/350 mmHg w Some BP increases are attributed to the Valsalva maneuver Blood Pressure

  31. w Blood flow distribution changes from rest to exercise as blood is redirected to the muscles and systems that need it. (continued) Key Points Cardiovascular Response to Exercise w As exercise intensity increases, heart rate, stroke volume, and cardiac output increase to get more blood to the tissues. w More blood pumped from the heart per minute during exercise allows for more oxygen and nutrients to get to the muscles and for waste to be removed more quickly.

  32. Key Points Cardiovascular Response to Exercise w Cardiovascular drift is the result of decreased stroke volume, increased heart rate, and decreased systemic and pulmonary arterial pressure due to prolonged steady-state exercise or exercise in the heat. w Systolic blood pressure increases directly with increased exercise intensity while diastolic blood pressure remains constant. w Blood pressure tends to increase during high-intensity resistance training, due in part to the Valsalva maneuver.

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