Exercise physiology

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Created by
Lila Beaman-Patel

Cards (37)

  • Cardiovascular system
    Serves numerous important functions within the human body that supports all other physiological systems including:
    • Delivery of oxygen and energy substrates
    • Removal of CO2 and other metabolic waste products
    • Transport of hormones
    • Thermoregulation and control of body fluid balance
    • Maintenance of acid-based balance (to control pH)
    • Regulation of immune function
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  • Cardiovascular system
    • Essential for health, disease and performance
    High adaptive to stress
    Vulnerable to disease
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  • Cardiovascular responses to acute exercise
    In response to exercise, there are several interrelated changes that occur with the main aim of supplying greater volumes of oxygenated blood to the working muscles
    Involves a coordinated response of both the central and peripheral circulation in order to ensure enough blood supply for metabolism
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  • Heart rate
    Number of beats within one minute
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  • Systole
    The phase of heart contractility
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  • Diastole
    The phase of heart relaxation
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  • Stroke volume
    The volume of blood pumped from the left ventricle per beat
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  • Cardiac output
    Volume of blood pumped through the circulatory system per minute
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    1. vO2 difference
    Difference in the O2 saturation between arterial and the venous blood
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  • VO2 and VO2max
    Volume of oxygen that is used by your body to convert the energy
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  • Heart rate
    • Simple but informative measure often used in the physiological assessment of patients/athletes as an indirect measure of cardiovascular stress and strain
    Can be used to inform the relative intensity of exercise
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  • Key measures of heart rate
    • Resting heart rate
    Maximum heart rate
    Heart rate reserve
    Heart rate variability
    Heart rate recovery
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  • Increase in exercise intensity
    Directly proportional increase in heart rate
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  • If we continue to increase the intensity beyond 100%, would HR continue to rise?
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  • To accurately determine the HR response to a given intensity, we must achieve steady-state
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  • Steady-state is the optimal HR for meeting the circulatory demands of work and takes approximately 3 minutes
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  • An example of changes in HR indices
    • Resting HR and post-ex HR provides a measure of the rhythmic fluctuation due to a continuous change in sympathetic and parasympathic rhythm
    HRR - the rate of reduction in HR once exercise has ended (i.e. no. beats in 60 seconds)
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  • Stroke volume
    The volume of blood pumped from the heart (left ventricle) per beat
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  • Factors influencing stroke volume
    • Venous return
    Ventricular distensibility
    Ventricular contractility
    Aortic or pulmonary pressure
    End diastolic volume (preload)
    Afterload (systole)
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  • Think of a disease that might affect one or more of these factors of stroke volume
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  • Stroke volume response to exercise
    Increases rapidly up to 40-60% of VO2max
    After this, stroke volume rises but at a much slower rate - it reaches a limit of the four factors mentioned
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  • Cardiac output response to exercise
    50% VO2max = increase in stroke volume and increase in heart rate
    50% VO2max = no change in stroke volume and increase in heart rate
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  • Stroke volume plateaus at approximately 50% of VO2max
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  • Contrasting evidence suggests that stroke volume can continue to increase at intensities > 50% VO2max
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  • Factors affecting stroke volume response to exercise
    • Activity type
    Age
    Fitness levels
    Sex
    Hydration status
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  • At 70 b·min-1 filling time is ~0.55 s but at 195 b·min-1 this is reduced to 0.12
    Greater filling = greater stretch = greater ejection fraction (Frank-Starling mechanism)
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  • Increase in preload
    Increases stroke volume
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  • Decrease in afterload (total peripheral resistance)

    Increases stroke volume
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  • Cardiac output
    Q = SV x HR
    Rest = ~ 5 L
    Max = 20 to 40 L
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  • At max intensity, cardiac output reaches a plateau
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  • Fick principle
    VO2 = Q x (a-v)O2 difference
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    1. vO2 difference
    Resting metabolism consumes about 5 mL of oxygen from the 20 mL oxygen in each decilitre of arterial blood (50 mL ⋅ L−1) that passes through the tissue capillaries
    This changes to 4 mL ⋅ dL−1 during maximum exertion
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  • Factors affecting resting cardiovascular values
    • Sex
    Age
    Exercise & physical activity status
    Body position
    Activity type
    Muscle contraction(s)
    Various clinical conditions
    Activity level before assessment
    Body composition
    Genetics / Epigenetics
    Activity intensity / volume
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  • Effect of bed rest on cardiovascular function
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  • Effect of age on VO2max
    Children: Absolute values similar up to 12yrs after which males and females differ
    Relative values: boys remain constant (52 ml·kg-1·min-1); girls decrease to about 40 ml·kg-1·min-1 at 16 yrs
    Decrease after 25 yrs at about 1% per year
    Evident even with training
    Physical activity levels have greater influence on VO2max than chronological age
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  • Effect of sex on VO2max
    Females < males by 15 - 30%
    Magnitude dependent upon how VO2max is expressed (absolute vs relative)
    Differences attributed to body fat levels, haemoglobin concentration, and activity levels
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  • Exercise modality and VO2max
    Treadmill > Cycle
    Significant difference
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