Summary

This document presents an overview of respiratory physiology, covering volumes, capacities, and ventilation. It discusses the role of spirometry, chemoreceptors, and the effects of hyperventilation and hypoventilation on cardiovascular function.

Full Transcript

3/15/23 Respiratory Physiology Lab #7 1 Volume and Capacity Spirometer measures respiratory volume • Can be used to assess respiratory health • Standard values are available (e.g., for people of different ages) • Four volumes measured by spirometry • Tidal volume: amount of air inhaled or exhale...

3/15/23 Respiratory Physiology Lab #7 1 Volume and Capacity Spirometer measures respiratory volume • Can be used to assess respiratory health • Standard values are available (e.g., for people of different ages) • Four volumes measured by spirometry • Tidal volume: amount of air inhaled or exhaled per breath during quiet breathing • Inspiratory reserve volume (IRV): amount of air that can be forcibly inhaled beyond the tidal volume • Measure of compliance • Expiratory reserve volume (ERV): amount that can be forcibly exhaled beyond tidal volume • Measure of elasticity • Residual volume: amount of air left in the lungs after the most forceful expiration 2 1 3/15/23 Volume and Capacity Four capacities calculated from respiratory volumes • Inspiratory capacity (IC) • Tidal volume + inspiratory reserve volume • Functional residual capacity (FRC) • Expiratory reserve volume + residual volume • Volume left in the lungs after a quiet expiration • Vital capacity • Tidal volume + inspiratory and expiratory reserve volumes • Total amount of air a person can exchange through forced breathing • Sometimes referred to as the Forced Vital Capacity (FVC) • Total lung capacity (TLC) • Sum of all volumes, including residual volume • Maximum volume of air that the lungs can hold 3 Pulmonary Ventilation (VE) Pulmonary ventilation • Process of moving air into and out of the lungs • Amount of air moved between atmosphere and alveoli in 1 minute Tidal volume = amount of air per breath Respiration rate = number of breaths per minute Tidal volume × Respiration rate = Pulmonary ventilation 500 mL × 12 breaths/min = 6000 mL/minute (typical amount) 4 2 3/15/23 Respiratory Volumes and Capacities Spirogram Figure 23.24 5 Generating Sample Spirogram • Log into computer (using bb login and pw) • Power on black box leads go into (green light is on) • Open program (BMS applications on desktop -> lab files -> BMS 251 -> Spirogram -> teaching -> English) • Hit “record” • Autoscale to make it look clear: 6 3 3/15/23 Tidal Volume 7 Respiratory Rate 8 4 3/15/23 Pulmonary Ventilation (VE) Pulmonary Ventilation (VE) in mL/min or L/min = TV (in mL/breath) x RR (breaths/minute); Convert to L/min if asked. (Use TV from last slide 5: 782 mL) 30 seconds 9 Inspiratory Reserve Volume 10 5 3/15/23 Expiratory Reserve Volume 11 Vital Capacity Sometimes referred to as the Forced Vital Capacity (FVC) 12 6 3/15/23 Forced Expiratory Volume (FEV) FEV is the percentage of vital capacity that can be expelled in specific period of time 13 Forced Expiratory Volume in 1 second (FEV1) Airway resistance ratio (FEV1.0/FVC ratio) x 100 = % of vital capacity expired in 1 second. In this example, (3.013L / 3.504L) X 100 = 85.98% Healthy individual should expel 75%-85% of vital capacity in 1 second, and indicates normal airway resistance. The lower the %, the higher the resistance. 14 7 3/15/23 Nervous Control of Breathing H2O + CO2 H2CO3 H+ + HCO3- Chemoreceptors monitor changes in concentrations of H+, PCO2 and PO2 • Central chemoreceptors in medulla monitor pH (specifically H+) of CSF • CSF pH changes are caused by changes in blood PCO2 • CO2 diffuses from blood to CSF where carbonic anhydrase is present • Carbonic anhydrase builds carbonic acid from CO2 and water • More CO2 in the blood means more H+ in the CSF • Peripheral chemoreceptors are in aortic and carotid bodies • Stimulated by changes in CO2 or O2 in blood • Unlike central receptors, they can respond to H+ produced independently of CO2 • E.g., H+ from ketoacidosis (from fatty acid metabolism) 15 Regulation of Breathing chemoreceptors !!!!! How would breathing rate change? H2O + CO2 H2CO3 H+ + HCO3- 16 8 3/15/23 17 Effects of Hyperventilation and Hypoventilation on Cardiovascular Function Hyperventilation: breathing rate or depth above body’s demand • PO2 rises and PCO2 fall in the air of alveoli • Additional oxygen does not enter blood because hemoglobin is already 98% saturated • Hyperventilation will allow longer breath holding time because we exhale more CO2 during faster and deeper breathing. 18 9 3/15/23 Respiratory Volumes and Capacities Figure 23.24 19 Respiratory Volumes and Capacities Figure 23.24 20 10 3/15/23 Respiratory Volumes and Capacities Figure 23.24 21 11

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