pulmonary diffusion negative linear EPOC can work areobically at higher intenisties for longer Tidal Volume VO2 Max Cardiac Output Oxygen deficit aorta AVO2 Difference maximal litres arteries submaximal VE = TV x RR Free! capillaries Hydrogen ions haemoglobin steady state increase pulmonary vein stomach pulmonary circulation left ventricle beats/min hypothermia mls muscles right ventricle pulmonary artery left atrium diffusion positive linear pre- capillary sphincters systemic circulation allows aerobic energy production breaths/min aim vena cava hyperthermia vasodilation Redistribution of blood flow stay the same right atrium Minute Ventilation vasconstriction decrease Q = SV x HR Heart Rate Stroke Volume viens Respiratory Rate metabolic by- products pulmonary diffusion negative linear EPOC can work areobically at higher intenisties for longer Tidal Volume VO2 Max Cardiac Output Oxygen deficit aorta AVO2 Difference maximal litres arteries submaximal VE = TV x RR Free! capillaries Hydrogen ions haemoglobin steady state increase pulmonary vein stomach pulmonary circulation left ventricle beats/min hypothermia mls muscles right ventricle pulmonary artery left atrium diffusion positive linear pre- capillary sphincters systemic circulation allows aerobic energy production breaths/min aim vena cava hyperthermia vasodilation Redistribution of blood flow stay the same right atrium Minute Ventilation vasconstriction decrease Q = SV x HR Heart Rate Stroke Volume viens Respiratory Rate metabolic by- products
(Print)
pulmonary diffusion
negative linear
EPOC
can work areobically at higher intenisties for longer
Tidal Volume
VO2 Max
Cardiac Output
Oxygen deficit
aorta
AVO2 Difference
maximal
litres
arteries
submaximal
VE = TV x RR
Free!
capillaries
Hydrogen ions
haemoglobin
steady state
increase
pulmonary vein
stomach
pulmonary circulation
left ventricle
beats/min
hypothermia
mls
muscles
right ventricle
pulmonary artery
left atrium
diffusion
positive linear
pre-capillary sphincters
systemic circulation
allows aerobic energy production
breaths/min
aim
vena cava
hyperthermia
vasodilation
Redistribution of blood flow
stay the same
right atrium
Minute Ventilation
vasconstriction
decrease
Q = SV x HR
Heart Rate
Stroke Volume
viens
Respiratory Rate
metabolic by-products
