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CARDIORESPIRATORY ADAPTATIONS TO TRAINING

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CARDIORESPIRATORY ADAPTATIONS TO TRAINING ... for several fitness components (endurance strength) at one time ... most important component of physical fitness. ... – PowerPoint PPT presentation

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Title: CARDIORESPIRATORY ADAPTATIONS TO TRAINING


1
CARDIORESPIRATORY ADAPTATIONS TO TRAINING
  • Endurance - two different concepts - muscular e.,
    cardiorespiratory e.
  • Muscular E - ability of muscle to sustain
    high-intensity, repetitive or static exercise
    (important for sprinters, weight lifter, boxer,
    wrestler) - related to muscular strength and
    anaerobic development.
  • Cardiorespiratory E. - ability of the body to
    sustain prolonged exercise. (cyclist, distance
    runners, swimmers) related to development of
    cardiovascular and respiratory systems, thus
    aerobic development.

2
Evaluation E. Capacity
  • Aerobic Power - Vo2 max
  • with endurance training - more oxygen delivered
    - 6 months training - increase
    in VO2 max of 20 percent - perform e.
  • activities at higher work rate, faster.
  • Oxygen Transport System
  • shared by CR systems - VO2
    ? SV x HR x a - VO2 diff.

3
A - CV Adaptations To Training
  • 1) Heart Size - hearts weight, volume, LV wall
    thickness, chamber size increase - Athletes
    Heart
    LV internal
    dimension increases - increase in ventricular
    filling (rise in plasma volume),
    LV wall thickness, increase (hypertrophy)
    - increase in strength potential of its
    contractions.
  • 2) Stroke Volume - higher after endurance tr.
    at rest, during exercise,
    stronger
    heart, availability of greater blood volume
    increase in EDV, increase in EF.

4

5
  • 3) Heart Rate (HR) - decrease of HR after
    endurance tr. (elite athletes 30 - 40 beats
    (min.) - increase in parasympathetic
    tone. At submaximal exercise tr. - decrease of HR
    by about 20 - 40 beats/min. after 6 months.
    Maximal HR - unchanged or
    slightly decreased (allowing for optimum SV
    to maximize CO). HR recovery time -
    decrease - well suited to tracking an
    indviduals progress with tr.
  • 4) Cardiac Output (CO) - at rest, during
    submaximal levels of ex. - unchanged , at maximal
    levels - considerable increase (mainly by ?of
    SV). CO in untrained 14 - 16
    l/min., 40 l intrained athletes.

6
  • 5) Blood Flow (BF)
  • enhanced muscle blood supply following
  • training
  • a) increased capillarization of trained muscles
  • - new capillaries develop - ? capillary to
    fiber ratio
  • b) greater opening of existing capillaries
  • c) more effective blood redistribution (shunting
  • away from areas that dont need high
    flow)
  • 6) Blood Pressure (BP) - resting blood pressure
  • reduced, no changes during submaximal
  • or maximal work rates.

7
  • 7) Blood Volume (BV) - E. tr. - ? BV, mainly by
    increase in blood plasma volume
    (? ADH, aldosterone, ? amount of plasma
    proteins). Red blood cells count increases,
    (pseudoanemia). Blood viscosity ?
    - improvement of circulation).
  • Plasma volume - high correlation with
    VO2 max ? increase in plasma volume
    - most significant training effect

8
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9
B - Respiratory Adaptations To Training
  • Lung Volumes - no change in VC, RV, TLC, slight
    increase in TV
  • Respiratory Rate increase in maximal exercise
    levels of pulmonary ventilation - slightly
    reduced at rest, maximal pulmonary ventilation
    substantially increased. Untrained - 120 l/min,
    trained - 240 l/min.
  • Pulmonary Diffusion - no change at rest, increase
    in maximal exercise
  • A-v O2 diff. - increase after training (?mixed
    venous O2 content)

10
Metabolic Adaptations
  • Lactate Threshold - E. tr. -? lactate thr.
    n - higher rate of work at higher
    rate of O2 consumption without raising blood
    lactate. Maximal blood lactate levels increase
    slightly.
  • Respiratory Exchange Ratio (RER) - at rest -
    ?? RER (greater utilization of
    FFA), at maximal levels of work - ? RER in
    trained individuals. (sustained hyperventilation
    ? excessive CO2 release)

11
  • Maximal O2 Consumption - substantial increase
    following training - individual limitation, major
    limiting factor
    - oxygen delivery to the
    active muscles (lack of
    oxidative enzymes in mitochondria, central and
    peripheral circulatory factor limit endurance
    capacity)

12
  • Long-term Improvement in Endurance
  • Highest attainable VO2 max usually reached
    within 18 months of intense e. conditioning,
    further improvement with continued tr. for many
    additional years - bodys ability
    perform at increasing percentage of VO2 max for
    extended periods - result of increase in lactate
    threshold

13
  • Factors Affecting the Response to Aerobic
    Training
  • Heredity Genetic factors establish boundaries for
    an individual endurance training can push Vo2 max
    to the upper limits of these boundaries.
  • Age
    Age related decrease - decrease in
    activity levels.
  • Decline in VO2 max
    - attenuated by
    continuing training

14
  • Gender
  • Highly conditioned female e. athletes
    - 10 percent lower VO2 max values
  • Responders x Nonresponders
  • Large improvements - responders, little
    or no improvement (nonresponders)
    to the same training programs - genetic influence

15
  • Specificity of Training
  • Selection of appropriate training program -
    closely matched with athletes individual needs
    to maximize the physiological adaptations to
    training
  • Cross Training
  • Training for more than one sport at the same
    time or tr. for several fitness components
    (endurance strength) at one time

16
  • Cardiorespiratory Endurance and Performance
  • E. - the most important component of physical
    fitness.
  • E. - athletes major defense against fatigue -
    major deterrent to optimal performance (muscle
    strength decreased, reaction and movement times
    prolonged, neuromuscular coordination reduced,
    concentration and alertness reduced).

    Extent of
    endurance training needed varies, dependence on
    E. demands of chosen activity (marathon runner x
    baseball, golf player)
  • All Athletes Can Benefit from Maximizing Their
    Endurance
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