Download Cardiorespiratory Adaptations to Training

Cardiorespiratory Adaptations to
Training
Cardiovascular Adaptations
From Aerobic Training
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Increased cardiorespiratory endurance
Increased muscular endurance
Decreased VO2 at rest and submaximal exercise
IncreasedVO2 Max
Increased heart weight, volume, and chamber size
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Increased left ventricle wall thickness “athletes heart”
Increased left ventricle EDV
Increased blood plasma
Increased Stroke Volume (fig. 10.3)
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from increased EDV and decreased ESV = increased EF
Frank-Starling law: elastic recoil of the ventricle
Cardiovascular Adaptations
From Aerobic Training
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Decreased resting heart rate
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Decreased submaximal heart rate
Decreased maximum heart rate of elite athletes
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from increased parasympathetic activity and decreased
sympathetic activity.
if your heart rate is too fast the period of ventricular filling is
reduced and your stroke volume might be compromised.
the heart expends less energy by contracting less often but
more forcibly than it would by contracting more often.
Decreased Heart Rate Recovery (fig. 10.5)
Cardiovascular Adaptations
From Aerobic Training
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Maintained cardiac output at rest and submaximal
exercise
Increased cardiac output during maximal exercise
Increased blood flow to the muscles
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increased capillarization of trained muscles
greater opening of existing capillaries in trained muscles
more effective blood redistribution
increased blood volume
decreased blood viscosity & increased oxygen delivery
Decreased resting blood pressure, but is unchanged
during exercise
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from increased blood flow
Cardiovascular Adaptations
From Aerobic Training
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Increased blood volume (blood plasma) and is greater
with more intense levels of training
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increased release of antidiuretic hormone
increased plasma proteins which help retain blood fluid
increased red blood cell volume
decreased blood viscosity
Respiratory Adaptations From
Aerobic Training
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Respiratory system functioning usually does not
limit performance because ventilation can be
increased to a greater extent than cardiovascular
function.
Slight increase in Total lung Capacity
Slight decrease in Residual Lung Volume
Increased Tidal Volume at maximal exercise levels
Decreased respiratory rate and pulmonary
ventilation at rest and at submaximal exercise
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(RR) decreases because of greater pulmonary efficiency
Increased respiratory rate and pulmonary ventilation
at maximal exercise levels
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from increased tidal volume
Respiratory Adaptations From
Aerobic Training
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Unchanged pulmonary diffusion
at rest and submaximal exercise.
Increased pulmonary diffusion
during maximal exercise.
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from increased circulation and
increased ventilation
from more alveoli involved during
maximal exercise
Increased A-VO2 difference
especially at maximal exercise.
Metabolic Adaptations From
Aerobic Training
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Lactate threshold occurs at a higher percentage of
VO2 Max.
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Decreased Respiratory Exchange Ratio (ratio of
carbon dioxide released to oxygen consumed)
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from a greater ability to clear lactate from the muscles
from an increase in skeletal muscle enzymes
from a higher utilization of fatty acids instead of carbo’s
however, the RER increases from the ability to perform at
maximum levels of exercise for longer periods of time
because of high lactate tolerance.
Increased resting metabolic rate
Decreased VO2 during submaximal exercise
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from a metabolic efficiency and mechanical efficiency
Metabolic Adaptations From
Aerobic Training
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Large increases in VO2 Max
 in mature athletes, the highest attainable VO2 Max is
reached within 8 to 18 months of heavy endurance
training.
 VO2 Max is influenced by “training” in early
childhood.
 from increased oxidative enzymes
 from increased size and number of mitochondria
 from increased blood volume, cardiac output & O2
diffusion
 from increased capillary density
Cardiorespiratory Adaptations
From Anaerobic Training
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Small increase in cardiorespiratory endurance
Small increase in VO2 Max
Small increases in Stroke Volume
Cardiorespiratory Adaptations
From Resistance Training
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Small increase in left ventricle size
Decreased resting heart rate
Decreased submaximal heart rate
Decreased resting blood pressure is greater than from
endurance training
Resistance training has a positive effect on aerobic
endurance but aerobic endurance has a negative
effect on strength, speed and power.
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muscular strength is decreased
reaction and movement times are decreased
agility and neuromuscular coordination are decreased
concentration and alterness are decreased
Factors Affecting the
Adaptation to Aerobic
Training
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Heredity accounts for between 25% and 50% of the
variance in VO2 Max values.
Age-Related decreases in VO2 Max might partly
result from an age-related decrease in activity levels.
Gender plays a small role (10% difference) in the VO2
Max values of male and female endurance athletes.
There will be RESPONDERS (large improvement)
and NONRESPONDERS (little improvement) among
groups of people who experience identical training.
The greater the Specificity of Training for a given
sport or activity, the greater the improvement in
performance.
Applications to Exercise
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Breathe Right nasal strips
“head up” during recovery
O2 on the sidelines
active recovery
stretching before and after
intense exercise
smokers beware
stitch in the side
second wind
resist the valsalva
exercise increases the quality
of life more than the
quantity of life