Control of Ventilation Respiratory control center Receives neural and humoral input Feedback from muscles CO2 level in the blood Regulates respiratory rate
Location of Respiratory Control Centers
Neural Input to the Respiratory Control Center motor cortex - impulses from cortex may “spill over” when passing through medulla on way to heart and muscles afferent - from GTO, muscle spindles or joint pressure receptors mechanoreceptors in the heart relay changes in Q
Humoral Input to the Respiratory Control Center central chemoreceptors - respond to changes in CO2 or H+ in CSF peripheral chemoreceptors - aortic bodies and carotid bodies both similar to central receptors, carotids also respond to increases in K+ and decreases in PO2
Ventilation vs. Increasing PCO2
Ventilation vs. Decreasing PO2
Ventilatory Control During Exercise Submaximal exercise Linear increase due to: Central command Humoral chemoreceptors Neural feedback Heavy exercise Exponential rise above Tvent Increasing blood H+
Respiration Control during Submaximal Exercise
Respiratory Control during Exercise Central commmand initially responsible for increase in VE at onset combination of neural and humoral feedback from muscles and circulatory system fine-tune VE Ventilatory threshold may be result of lactate or CO2 accumulation (H+) as well as K+ and other minor contributors
Effect of Training on Ventilation Ventilation is lower at same work rate following training May be due to lower blood acidity Results in less feedback to stimulate breathing
Training Reduces Ventilatory Response to Exercise
Final Note the pulmonary system is not thought to be a limiting factor to exercise in healthy individuals the exception is elite endurance athletes who can succumb to hypoxemia during intense near maximal exercise
Acid-Base Balance
Acids and Bases Acid - compound that can loose an H+ and lower the pH of a solution lactic acid, sulphuric acid Base - compound that can accept free H+ and raise the pH of a solution bicarbonate (HCO3-) Buffer - compound that resists changes in pH bicarbonate (sorry)
pH pH = -log10 [H+] pH of pure water = 7.0 (neutral) pH goes up, acidity goes down pH of pure water = 7.0 (neutral) pH of blood = 7.4 (slightly basic) pH of muscle = 7.0
Acidosis and Alkalosis
Acid Production during Exercise CO2 - volatile because gas can be eliminated by lungs CO2 + H2O <--> H2CO3 <--> H+ + HCO3- The next point is erroneous Lactic acid and acetoacetic acid - CHO and fat metabolism respectively termed organic acids at rest converted to CO2 and eliminated, but during intense exercise major load on acid-base balance
Sulphuric and Phosphoric acids - produced by oxidation of proteins and membranes or DNA called fixed because not easily eliminated minor contribution to acid accumulation
Sources of H+
Buffers maintain pH of blood and tissues accept H+ when they accumulate release H+ when pH increases
Intracellular Buffers proteins phosphates PC bicarbonate
Insert table 11.1
Extracellular Buffers bicarbonate - most important buffer in body remember the reaction hemoglobin - important buffer when deoxygenated picks up H+ when CO2 is being dumped into blood proteins - not important due to low conc.
Buffering Capacity of Muscles vs. Blood
Respiration and Acid-Base Balance CO2 has a strong influence on blood pH as CO2 increases pH decreases (acidosis) CO2 + H2O > H+ + HCO3- as CO2 decreases pH increases (alkalosis) so, by blowing off excess CO2 can reduce acidity of blood
Changes in Lactate, Bicarb and pH vs. Work Rate
Lines of Defense against pH Change during Intense Exercise