Respiratory III: Blood Transport of Gases/Regulation of Respiration PDF

Summary

These lecture notes cover the topic of respiratory physiology, specifically focusing on blood transport of gases and regulation of respiration. The document delves into the mechanisms of oxygen and carbon dioxide transport, highlighting the role of hemoglobin and related factors. It also touches on the respiratory system.

Full Transcript

Respiratory III: Blood Transport of Gases/ Regulation of Respiration ANSC 3080 G. Bedecarrats Learning Objective  Explain the transport of oxygen in the blood  Explain the transport of carbon dioxide in the blood  Describe the mechanisms regulating the respiratory system ...

Respiratory III: Blood Transport of Gases/ Regulation of Respiration ANSC 3080 G. Bedecarrats Learning Objective  Explain the transport of oxygen in the blood  Explain the transport of carbon dioxide in the blood  Describe the mechanisms regulating the respiratory system  Brief overview of the respiratory system in birds Oxygen Transport in Blood  Most of the oxygen in blood (>97%) is reversibly bound to hemoglobin  Rest circulates dissolved in blood  Henry’s Law: amount of gas dissolved is directly proportional to partial pressure of that gas  However, solubility of O2 very low in aqueous solution  At a usual arterial pressure (PaO2=100mm Hg): 3 ml of O2 per L of blood is dissolved  In reality blood leaving the lungs contains ~200 ml O 2 per liter  197 ml/liter bound to hemoglobin Significance  At rest, a greyhound (25 kg) consumes 125 ml O2 per min  During a race, O2 consumption jumps to 4500 ml per min  If O2 was carried only as dissolved in blood  What would be the necessary cardiac output to sustain the effort? 1500 liters of blood Hemoglobin  Contains 4 heme groups, each with 1 iron atom that can bind 1 molecule of O2  1 hemoglobin binds 4 molecules of O2  Oxygen saturation is the amount of oxygen carried divided by the total oxygen capacity of blood  % saturation = amount O2 bound / max capacity of Hb for O2  When all 4 sites of all the blood Hb are bound: saturation = 100%  When half the potential binding sites are occupied: saturation = 50% FYI Saturation Curve  Binding of O2 to Hb follows a mass action law  At equilibrium: Hb + O2  HbO2  If the concentration of 1 reagent changes, the equilibrium is displaced  pO2 is responsible for the amount of O2 dissolved in blood  Saturation directly linked to the pO2 (lungs, tissue)  Blood in lung capillaries = dissolved O2  = more HbO2  Blood passes through tissue capillaries = dissolved O2  = dissociation of HbO2 occurs  Oxygen saturation curve follows a sigmoid shape  Relation between Hb content and the pO2  Normal condition:  100% saturation out of lung  75% saturated out of tissue  Since is Hb completely saturated in the lungs. The main factor is the concentration of Hb  1g Hb caries 1.34 ml of O2  Normal concentration = 150g/l  200 ml of O2  Anemia: O2 transport reduced proportionally to amount of Hb  In high altitude, pO2 in air decrease  compensate by increasing the number of erythrocytes and Hb Saturation Factors Affecting Hb Saturation  pH: increase in metabolism = increase in H+  Decreases affinity of Hb for O2  Curve shifted to the right: need higher pO2 for saturation, unloading occurs more rapidly  Temperature: increased metabolism = increased heat  Result similar to acidity  2,3DPG (diphosphoglycerate): result from glycolysis in erythrocytes. Binds to Hb  Similar effect  NOTE: the pO2 in the lung is generally sufficient to maintain 100% saturation in most situation. pH, T and DPG mainly affect the unloading (convenient during exercising) Blood Transport of CO2 Carried in three forms:  Physical solution (5-10 %) = dissolved in blood  20 times more soluble in water than O2  Carbamino compounds (bound to proteins)  bind to –NH groups on proteins, especially hemoglobin  Stronger affinity for deoxyhemoglobin (no O2)  15%-20% of total carbon dioxide content  Bicarbonate (HCO3-), 70%-75%  CO2 + H2O  H2CO3  HCO3- + H+  Reaction in erythrocytes  HCO3- diffuse in plasma (much more soluble than CO2)  In the lung opposite reaction occurs (back to CO2 form) Ex. Cel Fluid Regulation of Respiration  As the heart, respiratory muscles contract rhythmically  Contrary to the heart, no pace maker cells = skeletal muscle needs APs from motor neurons  Ventilation is automatic and is constantly adjusted to needs  Rhythmic nature originate in the Respiratory Center of the brain stem (medulla oblongata) Respiratory Center  Network of synchronized neurons within the brain stem  Inspiratory neurons  stimulate motor neurons in the spinal cord  contraction of respiratory muscles  Inspiratory neurons controlled by another network in the brain stem: Central Pattern Generator (CPG)  Respiratory center under constant influence of pO2, pCO2 and H+ concentrations (chemicals)  Inspiratory neurons also under the influence of stretch receptor in the lung, bronchiole, and muscles  Reflex: stretch  sensory fiber  brain stem  in activity Chemical Regulation  Chemoreceptors detect O2, CO2 and H+  Central chemoreceptors:  In brain stem  Indirectly detect changes in pCO2 in the blood to the brain  CO2 enters cerebrospinal fluid by diffusion from the blood across the blood-brain barrier, transformed into HCO3- + H+  H+ is the trigger  Peripheral chemoreceptors:  In carotid and the aorta  Detect direct arterial changes in pO2, pCO2 and H+  Information sent to the respiratory centers:   pCO2,  H+ or  pO2  increase ventilation  pCO2 most important factor leads to increase in H+ Hypoxia  Deficit in O2 supply to the cells  Symptoms: Confusion, hallucination, loss of consciousness  Causes: Low arterial pO2 from pulmonary diseases/failure, high altitude Reduced transport capacity = problem with Hb Reduced blood flow to tissues Impaired cell metabolism (cyanide poisoning)  Remedy: inhalation pure O2 Respiration in Birds (FYI)  Gas exchange identical to mammals (diffusion)  Ventilation is different  Lungs relatively small and rigid; do not change in volume during inspiration/expiration  Air sacs (8): Thin-walled distensible Communicate with the lungs and the bronchi  Both inspiration and expiration are active processes  Possess unidirectional parabronchi that runs in the lung. Also involved in gas exchange Parabronchi Cycle 1:  Inspiration air enters airways goes to caudal air sacs and the lung  Expiration pushes air out the caudal air sac flows through the lungs  Air flows through the lung during both inspiration and expiration Cycle 2:  Inspiration air from the lung fills the cranial air sacs  Expiration air pushed out the cranial sac outside  Note that what happened in cycle 1 also happens in cycle 2

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