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Cardiorespiratory Adaptations to Training. Chapter 13. Cardiorespiratory endurance. refers to your body’s ability to sustain prolonged, rhythmical exercise. Cardiorespiratory Endurance. Highly related to aerobic development. Cardiorespiratory Endurance.
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Cardiorespiratory Adaptations to Training Chapter 13
Cardiorespiratory endurance • refers to your body’s ability to sustain prolonged, rhythmical exercise.
Cardiorespiratory Endurance • Highly related to aerobic development.
Cardiorespiratory Endurance • VO2MAX is the best indicator of cardiorespiratory endurance.
VO2MAX • Absolute and relative measures. • absolute =l . min-1 • relative = ml . kg-1 . min-1 • VO2 = SV x HR x a-vO2diff
Cardiovascular Response • Left ventricle undergoes the most change in response to endurance training. • internal dimensions of the left ventricle increase. • (mostly in response to an increase in ventricular filling)
Cardiovascular Response • left ventricle wall thickness also increases, increasing the strength potential of that chamber’s contractions. Left Ventricle
Cardiovascular Response • Following endurance training, stroke volume increases during rest, submaximal levels of exercise, and maximal exertion.
Cardiovascular Response • A major factor leading to the stroke volume increase is an increased end-diastolic volume, probably caused by an increase in blood plasma.
Cardiovascular Response • Another major factor is increased left ventricular contractility. • This is caused by hypertrophy of the cardiac muscle and increased elastic recoil, which results from increased stretching of the chamber with more diastolic filling.
Heart Rate Adaptations: • A person’s submaximal HR decreases proportionally with the amount of training completed.
Heart Rate Adaptations: • Maximal HR either remains unchanged or decreases slightly with training.
Heart Rate Adaptations: • When a decrease occurs, it is probably to allow for optimum stroke volume to maximize cardiac output.
Heart Rate Adaptations: • The HR recovery period decreases with increased endurance, making this value well suited to tracking an individual’s progress with training.
Heart Rate Adaptations: • However, this is not useful for comparing fitness levels of different people.
Heart Rate Adaptations: • Resistance training can also lead to reduced heart rates; however, these decreases are not as reliable or as large as those seen with endurance training.
Cardiac Output Adaptations: • Cardiac output at rest or during submaximal levels of exercise remains unchanged or decreases slightly after training.
Cardiac Output Adaptations: • Cardiac output at maximal levels of exercise increases considerably. • This is largely the result of the submaximal increase in maximal stroke volume.
Blood Distribution Adaptations • Blood flow to muscles is increased by endurance training.
Blood Distribution Adaptations • Increased blood flow results from four factors: • Increased capillarization. • Greater opening of existing capillaries. • More effective blood redistribution. • Increased blood volume.
Blood Pressure Adaptations: • Resting blood pressure is generally reduced by endurance training in those with borderline or moderate hypertension.
Blood Pressure Adaptations: • Endurance training has little or no effect on blood pressure during standardized submaximal or maximal exercise.
Blood Volume Adaptations: • Blood volume increases as a result of endurance training. • The increase is primarily caused by an increase in blood plasma.
Blood Volume Adaptations: • RBC count can increase, but the gain in plasma is typically much higher, resulting in a relatively greater fluid portion of the blood.
Blood Volume Adaptations: • Increased plasma volume causes decreased blood viscosity, which can improve circulation and oxygen availability.
Blood Volume Adaptations: • The training-induced increase in plasma volume, and its impact on stroke volume and VO2MAX, make it one of the most significant training effects.
Pulmonary Adaptations: • Most static lung volumes remain essentially unchanged after training.
Pulmonary Adaptations: • Tidal volume, though unchanged at rest and during submaximal exercise, increases with maximal exertion.
Pulmonary Adaptations: • Respiratory rate remains steady at rest, can decrease slightly with submaximal exercise, but increases considerably with maximal exercise after training.
Pulmonary Adaptations: • The combined effect of increased tidal volume and respiration rate is an increase in pulmonary ventilation at maximal effort following training.
Pulmonary Adaptations: • Pulmonary diffusion at maximal work rates increases, probably because of increased ventilation and increased lung perfusion.
Pulmonary Adaptations: • a-vO2diff increases with training, reflecting an increased oxygen extraction by the tissues and more effective blood distribution.
Acid-Base Balance Adaptations: • Lactate threshold increases with endurance training, which allows you to perform at higher rates of work and levels of oxygen consumption without increasing your blood lactate above resting levels.
Acid-Base Balance Adaptations: • Maximal blood lactate levels can be increased slightly.
Oxygen Consumption Adaptations: • The respiratory exchange ratio decreases at submaximal work rates, indicating a greater utilization of free fatty acids. • It increases at maximal effort.
Oxygen Consumption Adaptations: • Oxygen consumption can be increased slightly at rest. • It can be decreased slightly or remain unaltered during submaximal exercise.
Oxygen Consumption Adaptations: • VO2MAX increases substantially following training, but the amount of increase possible is limited in each individual.
Oxygen Consumption Adaptations: • The major limiting factor appears to be oxygen delivery to the active muscles.
Oxygen Consumption Adaptations: • Although VO2MAX has an upper limit, endurance performance can continue to improve for years with continued training.
Oxygen Consumption Adaptations: • An individual’s genetic makeup predetermines a range for his/her VO2MAX, accounting for 25% to 50% of the variance in VO2MAX values.
Oxygen Consumption Adaptations: • Heredity also largely explains individual variations in response to identical training programs.
Oxygen Consumption Adaptations: • Age-related decreases in aerobic capacity might partly result from decreased activity.
Oxygen Consumption Adaptations: • Highly conditioned female endurance athletes have VO2MAX values only about 10% lower than those of highly conditioned male endurance athletes. • Body size • Hemoglobin content • Percent lean mass
Oxygen Consumption Adaptations: • To maximize cardiorespiratory gains, training should be specific to the type of activity the exerciser usually performs.
Oxygen Consumption Adaptations: • Resistance training in combination with endurance training does not appear to restrict improvement in aerobic capacity and may increase short-term endurance.
Oxygen Consumption Adaptations: • All exercisers can benefit from maximizing their endurance.
Determining Exercise Intensity For basic health and fitness: • 40-45% of heart rate or VO2 reserve, or 50-64% of heart rate max
Determining Exercise Intensity For optimal health and fitness: • 50-85% of heart rate or VO2 reserve, or 65-90% of heart rate max
Determining Exercise Intensity • Heart rate max Calculated by 208 – 0.7(age)
Determining Exercise Intensity • Heart Rate Reserve Heart rate max – resting heart rate • VO2 Reserve VO2max – resting VO2