Transcript Slide 1
Cardiorespiratory Responses to Acute Exercise CHAPTER 8 Overview • Cardiovascular responses to acute exercise – Cardiac responses – Vascular responses – Integration of exercise responses • Respiratory responses to acute exercise – Ventilation (normal exercise, irregularities) – Ventilation and energy metabolism – Respiratory limitations – Respiratory regulation of acid-base balance Cardiovascular Responses to Acute Exercise • Increases blood flow to working muscle • Involves altered heart function, peripheral circulatory adaptations – – – – – – Heart rate Stroke volume Cardiac output Blood pressure Blood flow Blood Cardiovascular Responses: Resting Heart Rate (RHR) • Normal ranges – Untrained RHR: 60 to 80 beats/min – Trained RHR: as low as 30 to 40 beats/min – Affected by neural tone, temperature, altitude • Anticipatory response: HR above RHR just before start of exercise – Vagal tone – Norepinephrine, epinephrine Cardiovascular Responses: Heart Rate During Exercise • Directly proportional to exercise intensity • Maximum HR (HRmax): highest HR achieved in all-out effort to volitional fatigue – – – – Highly reproducible Declines slightly with age Estimated HRmax = 220 – age in years Better estimated HRmax = 208 – (0.7 x age in years) Cardiovascular Responses: Heart Rate During Exercise • Steady-state HR: point of plateau, optimal HR for meeting circulatory demands at a given submaximal intensity – If intensity , so does steady-state HR – Adjustment to new intensity takes 2 to 3 min • Steady-state HR basis for simple exercise tests that estimate aerobic fitness and HRmax Figure 8.1 Figure 8.2 Cardiovascular Responses: Stroke Volume (SV) • With intensity up to 40 to 60% VO2max – Beyond this, SV plateaus to exhaustion – Possible exception: elite endurance athletes • SV during maximal exercise ≈ double standing SV • But, SV during maximal exercise only slightly higher than supine SV – Supine SV much higher versus standing – Supine EDV > standing EDV Figure 8.3 Figure 8.4 Cardiovascular Responses: Factors That Increase Stroke Volume • Preload: end-diastolic ventricular stretch – Stretch (i.e., EDV) contraction strength – Frank-Starling mechanism • Contractility: inherent ventricle property – Norepinephrine or epinephrine contractility – Independent of EDV ( ejection fraction instead) • Afterload: aortic resistance (R) Cardiovascular Responses: Stroke Volume Changes During Exercise • Preload at lower intensities SV – Venous return EDV preload – Muscle and respiratory pumps, venous reserves • Increase in HR filling time slight in EDV SV • Contractility at higher intensities SV • Afterload via vasodilation SV Cardiac Output and Stroke Volume: Untrained Versus Trained Versus Elite Cardiovascular Responses: Cardiac Output (Q) • Q = HR x SV • With intensity, plateaus near VO2max • Normal values – Resting Q ~5 L/min – Untrained Qmax ~20 L/min – Trained Qmax 40 L/min • Qmax a function of body size and aerobic fitness Figure 8.5 Figure 8.6a Figure 8.6b Figure 8.6c Cardiovascular Responses: Fick Principle • Calculation of tissue O2 consumption depends on blood flow, O2 extraction • VO2 = Q x (a-v)O2 difference • VO2 = HR x SV x (a-v)O2 difference Cardiovascular Responses: Blood Pressure • During endurance exercise, mean arterial pressure (MAP) increases – Systolic BP proportional to exercise intensity – Diastolic BP slight or slight (at max exercise) • MAP = Q x total peripheral resistance (TPR) – Q , TPR slightly – Muscle vasodilation versus sympatholysis Cardiovascular Responses: Blood Pressure • Rate-pressure product = HR x SBP – Related to myocardial oxygen uptake and myocardial blood flow • Resistance exercise periodic large increases in MAP – Up to 480/350 mmHg – More common when using Valsalva maneuver Figure 8.7 Cardiovascular Responses: Blood Flow Redistribution • Cardiac output available blood flow • Must redirect blood flow to areas with greatest metabolic need (exercising muscle) • Sympathetic vasoconstriction shunts blood away from less-active regions – Splanchnic circulation (liver, pancreas, GI) – Kidneys Cardiovascular Responses: Blood Flow Redistribution • Local vasodilation permits additional blood flow in exercising muscle – Local VD triggered by metabolic, endothelial products – Sympathetic vasoconstriction in muscle offset by sympatholysis – Local VD > neural VC • As temperature rises, skin VD also occurs – Sympathetic VC, sympathetic VD – Permits heat loss through skin Figure 8.8 Cardiovascular Responses: Cardiovascular Drift • Associated with core temperature and dehydration • SV drifts – Skin blood flow – Plasma volume (sweating) – Venous return/preload • HR drifts to compensate (Q maintained) Figure 8.9 Cardiovascular Responses: Competition for Blood Supply • Exercise + other demands for blood flow = competition for limited Q. Examples: – Exercise (muscles) + eating (splanchnic blood flow) – Exercise (muscles) + heat (skin) • Multiple demands may muscle blood flow Cardiovascular Responses: Blood Oxygen Content • (a-v)O2 difference (mL O2/100 mL blood) – Arterial O2 content – mixed venous O2 content – Resting: ~6 mL O2/100 mL blood – Max exercise: ~16 to 17 mL O2/100 mL blood • Mixed venous O2 ≥4 mL O2/100 mL blood – Venous O2 from active muscle ~0 mL – Venous O2 from inactive tissue > active muscle – Increases mixed venous O2 content Figure 8.10 Cardiovascular Responses: Plasma Volume • Capillary fluid movement into and out of tissue – Hydrostatic pressure – Oncotic, osmotic pressures • Upright exercise plasma volume – Compromises exercise performance – MAP capillary hydrostatic pressure – Metabolite buildup tissue osmotic pressure – Sweating further plasma volume Figure 8.11 Cardiovascular Responses: Hemoconcentration • Plasma volume hemoconcentration – Fluid percent of blood , cell percent of blood – Hematocrit increases up to 50% or beyond • Net effects – Red blood cell concentration – Hemoglobin concentration – O2-carrying capacity Central Regulation of Cardiovascular Responses • What stimulates rapid changes in HR, Q, and blood pressure during exercise? – Precede metabolite buildup in muscle – HR increases within 1 s of onset of exercise • Central command – Higher brain centers – Coactivates motor and cardiovascular centers Central Cardiovascular Control During Exercise Cardiovascular Responses: Integration of Exercise Response • Cardiovascular responses to exercise complex, fast, and finely tuned • First priority: maintenance of blood pressure – Blood flow can be maintained only as long as BP remains stable – Prioritized before other needs (exercise, thermoregulatory, etc.) Figure 8.12 Respiratory Responses: Ventilation During Exercise • Immediate in ventilation – Begins before muscle contractions – Anticipatory response from central command • Gradual second phase of in ventilation – Driven by chemical changes in arterial blood – CO2, H+ sensed by chemoreceptors – Right atrial stretch receptors Respiratory Responses: Ventilation During Exercise • Ventilation increase proportional to metabolic needs of muscle – At low-exercise intensity, only tidal volume – At high-exercise intensity, rate also • Ventilation recovery after exercise delayed – Recovery takes several minutes – May be regulated by blood pH, PCO2, temperature Figure 8.13 Respiratory Responses: Breathing Irregularities • Dyspnea (shortness of breath) – Common with poor aerobic fitness – Caused by inability to adjust to high blood PCO2, H+ – Also, fatigue in respiratory muscles despite drive to ventilation • Hyperventilation (excessive ventilation) – Anticipation or anxiety about exercise – PCO2 gradient between blood, alveoli – Blood PCO2 blood pH drive to breathe Respiratory Responses: Breathing Irregularities • Valsalva maneuver: potentially dangerous but accompanies certain types of exercise – Close glottis – Intra-abdominal P (bearing down) – Intrathoracic P (contracting breathing muscles) • High pressures collapse great veins venous return Q arterial blood pressure Respiratory Responses: Ventilation and Energy Metabolism • Ventilation matches metabolic rate • Ventilatory equivalent for O2 – VE/VO2 (L air breathed/L O2 consumed/min) – Index of how well control of breathing matched to body’s demand for oxygen • Ventilatory threshold – Point where L air breathed > L O2 consumed – Associated with lactate threshold and PCO2 Figure 8.14 Respiratory Responses: Estimating Lactate Threshold • Ventilatory threshold as surrogate measure? – Excess lactic acid + sodium bicarbonate – Result: excess sodium lactate, H2O, CO2 – Lactic acid, CO2 accumulate simultaneously • Refined to better estimate lactate threshold – Anaerobic threshold – Monitor both VE/VO2, VE/VCO2 Ventilatory Equivalents During Exercise Respiratory Responses: Limitations to Performance • Ventilation normally not limiting factor – Respiratory muscles account for 10% of VO2, 15% of Q during heavy exercise – Respiratory muscles very fatigue resistant • Airway resistance and gas diffusion normally not limiting factors at sea level • Restrictive or obstructive respiratory disorders can be limiting Respiratory Responses: Limitations to Performance • Exception: elite endurance-trained athletes exercising at high intensities – Ventilation may be limiting – Ventilation-perfusion mismatch – Exercise-induced arterial hypoxemia (EIAH) Respiratory Responses: Acid-Base Balance • Metabolic processes produce H+ pH • H+ + buffer H-buffer • At rest, body slightly alkaline – 7.1 to 7.4 – Higher pH = Alkalosis • During exercise, body slightly acidic – 6.6 to 6.9 – Lower pH = Acidosis Figure 8.15 Respiratory Responses: Acid-Base Balance • Physiological mechanisms to control pH – Chemical buffers: bicarbonate, phosphates, proteins, hemoglobin – Ventilation helps H+ bind to bicarbonate – Kidneys remove H+ from buffers, excrete H+ • Active recovery facilitates pH recovery – Passive recovery: 60 to 120 min – Active recovery: 30 to 60 min Table 8.1 Table 8.2 Figure 8.16 Respiratory Responses: Air Pollution • Carbon monoxide (CO) – Derived from burning fuel, tobacco smoke – Hemoglobin’s affinity for CO much greater than for O2 VO2 • Ozone (O3) – Eye irritation, tight chest, dyspnea, cough, nausea – Transfer of O2 at lung alveolar PO2 • Sulfur oxide (SO2) – Upper airway and bronchial irritant – Aerobic exercise performance