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Physiology of Respiration

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Presentation on theme: "Physiology of Respiration"— Presentation transcript:

1 Physiology of Respiration
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2 Respiratory Volumes and Capacities
Tidal Volume (TV): (know this) - total air moved with each breath Normal breathing moves about 500 ml Inspiratory reserve volume (IRV): deep breath Amount of air that can be taken in forcibly over the tidal volume Usually around 3,100 ml Expiratory reserve volume (ERV): Amount of air that can be forcibly exhaled after a tidal expiration Approximately 1,200 ml © 2015 Pearson Education, Inc.

3 Respiratory Volumes and Capacities
Vital capacity (VC): (know this) The total amount of exchangeable air Vital capacity = TV + IRV + ERV Avg. 4,800 ml in men; 3,100 ml in women Residual volume: Air remaining in lung after expiration (about 1,200 ml) Allows gas exchange between breaths; keeps alveoli inflated spirometer –measures respiratory capacities © 2015 Pearson Education, Inc.

4 6,000 5,000 Inspiratory reserve volume 3,100 ml 4,000 Milliliters (ml)
Figure 13.9 Idealized tracing of the various respiratory volumes of a healthy young adult male. 6,000 5,000 Inspiratory reserve volume 3,100 ml 4,000 Vital capacity 4,800 ml Milliliters (ml) 3,000 Total lung capacity 6,000 ml Tidal volume 500 ml Expiratory reserve volume 1,200 ml 2,000 1,000 Residual volume 1,200 ml

5 Gas Transport in the Blood
Oxygen Transport: (two methods) Most attaches to hemoglobin to form oxyhemoglobin (HbO2) small dissolved amount is carried in the plasma Carbon dioxide: A small amount is carried in RBC bound to hemoglobin Hemoglobin has different binding sites for CO2 Most is transported in plasma as bicarbonate ion (HCO3–) Bicarbonate ion serves as a buffer © 2015 Pearson Education, Inc.

6 How CO2 diffuses into the alveoli
In order for CO2 to leave the body, it must dissociate from its bicarbonate ion form 1. it moves into the RBC 2. it breaks apart and forms carbonic acid with the available Hydrogen ions in the cell 3. it breaks apart again to form H2O and CO2 gas 4. diffusion of the gas into the alveoli occurs HCO3−+ H H2CO CO2+ H2O

7 Internal respiration in the body tissues
Figure 13.11b Diagrammatic representation of the major means of oxygen (O2) and carbon dioxide (CO2) loading and unloading in the body. (b) Internal respiration in the body tissues (systemic capillary gas exchange) Oxygen is unloaded and carbon dioxide is loaded into the blood. Tissue cells CO2 O2 Loading of CO2 Unloading of O2 CO2 +H2O H2CO3 H++ HCO3− Water Carbonic acid Bicar- bonate ion HbO2 Hb + O2 Plasma Systemic capillary Red blood cell

8 External respiration in the lungs (pulmonary gas exchange)
Figure 13.11a Diagrammatic representation of the major means of oxygen (O2) and carbon dioxide (CO2) loading and unloading in the body. (a) External respiration in the lungs (pulmonary gas exchange) Oxygen is loaded into the blood and carbon dioxide is unloaded. Alveoli (air sacs) O2 CO2 Loading of O2 Unloading of CO2 Hb + O2 HbO2 HCO3−+ H+ H2CO3 CO2+ H2O (Oxyhemoglobin is formed) Bicar- bonate ion Carbonic acid Water Plasma Red blood cell Pulmonary capillary

9 Breathing control centers: Pons centers Medulla centers
Figure Breathing control centers, sensory inputs, and effector nerves. Breathing control centers: Pons centers Medulla centers Afferent impulses to medulla Efferent nerve impulses from medulla trigger contraction of inspiratory muscles. Phrenic nerves Intercostal nerves Breathing control centers stimulated by: CO2 increase in blood (acts directly on medulla centers by causing a drop in pH of CSF) Nerve impulse from O2 sensor indicating O2 decrease Intercostal muscles Diaphragm O2 sensor in aortic body of aortic arch CSF in brain sinus

10 Neural Regulation of Respiration
Nerves: the phrenic and intercostal nerves Control diaphragm and external intercostals Receptors pick up on chemical composition of Oxygen and CO2 and make adjustments Medulla: Sets breathing rate and depth of breathing Controls overinflation of alveoli Stretch receptors in alveoli too Pons—coordinates/smoothens respiratory rate © 2015 Pearson Education, Inc.

11 Factors Influencing Respiratory Rate and Depth
Chemical : Increased levels of carbon dioxide causes: decreased or acidic pH of CSF an increase in rate and depth of breathing The body’s need to rid itself of CO2 is the most important stimulus for breathing Acts directly on the medulla oblongata Changes in Oxygen are monitored by chemoreceptors in the aorta and carotid © 2015 Pearson Education, Inc.

12 Breathing control centers: Pons centers Medulla centers
Figure Breathing control centers, sensory inputs, and effector nerves. Breathing control centers: Pons centers Medulla centers Afferent impulses to medulla Efferent nerve impulses from medulla trigger contraction of inspiratory muscles. Phrenic nerves Intercostal nerves Breathing control centers stimulated by: CO2 increase in blood (acts directly on medulla centers by causing a drop in pH of CSF) Nerve impulse from O2 sensor indicating O2 decrease Intercostal muscles Diaphragm O2 sensor in aortic body of aortic arch CSF in brain sinus

13 Factors Influencing Respiratory Rate and Depth
Physical factors/Emotional Factors Increased body temperature/Exercise Talking/Coughing Fear, anger, excitement Conscious control: holding your breath Respiratory centers override this when oxygen gets too low and pH drops © 2015 Pearson Education, Inc.

14 Summary of Respiration
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