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Respiratory System

Respiratory System. Biology for Majors. Direct Diffusion. This flatworm’s process of respiration works by diffusion across the outer membrane. Tracheal System in Insects. The tracheal system (not the circulatory system) carries oxygen to the entire body efficiently. Skin and Gills in Fish.

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Respiratory System

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  1. Respiratory System Biology for Majors

  2. Direct Diffusion This flatworm’s process of respiration works by diffusion across the outer membrane

  3. Tracheal System in Insects The tracheal system (not the circulatory system) carries oxygen to the entire body efficiently

  4. Skin and Gills in Fish

  5. Mammalian Respiratory System

  6. Trachea and Bronchi Air enters the respiratory system through the nasal cavity and pharynx, and then passes through the trachea and into the bronchi, which bring air into the lungs

  7. Lungs

  8. Alveoli

  9. Protective Mechanisms The bronchi and bronchioles contain cilia that help move mucus and other particles out of the lungs

  10. Lung Capacity The lungs can hold a large volume of air, but they are not usually filled to maximal capacity. Lung volume measurements include tidal volume, expiratory reserve volume, inspiratory reserve volume, and residual volume. The sum of these equals the total lung capacity

  11. Lung Volumes and Capacities (Avg Adult Male)

  12. Human Lung Volumes and Capacities

  13. Equations for Gas Exchange P=(Patm)×(percent content in mixture) Patm, the atmospheric pressure, is the sum of all of the partial pressures of the atmospheric gases added together, Patm=PN2+PO2+PH2O+PCO2=760 mm Hg×(percent content in mixture)

  14. Gas Exchange Across the Alveoli

  15. Boyle’s Law Boyle’s Law is the gas law that states that in a closed space, pressure and volume are inversely related. As volume decreases, pressure increases and vice versa 

  16. The Lungs, Chest Wall, and Diaphragm in Respiration

  17. Pleura A tissue layer called pleura surrounds the lung and interior of the thoracic cavity

  18. The Work of Breathing • Flow-resistive refers to the work of the alveoli and tissues in the lung • Elastic work refers to the work of the intercostal muscles, chest wall, and diaphragm. Increasing the respiration rate increases the flow-resistive work of the airways and decreases the elastic work of the muscles.

  19. The Ratio of FEV1 to FVC

  20. Types of Lung Disease Restrictive Obstructive Airway obstruction results in slow exhalation as well as reduced FVC Emphysema Asthma pulmonary edema • FVC is reduced but airways are not obstructed, so the person is able to expel air reasonably fast • Respiratory distress syndrome • Pulmonary fibrosis

  21. Ventilation/Perfusion Mismatch • As cardiac output increases, the number of capillaries and arteries that are perfused (filled with blood) increases • At times, however, there is a mismatch between the amount of air (ventilation, V) and the amount of blood (perfusion, Q) in the lungs

  22. Dead Space Dead space are regions of broken down or blocked lung tissue. Dead spaces reduce the surface area available for gas diffusion. As a result, the amount of oxygen in the blood decreases, whereas the carbon dioxide level increases. Dead space is created when no ventilation and/or perfusion takes place: • Anatomical dead space or anatomical shunt, arises from an anatomical failure • Physiological dead space or physiological shunt, arises from a functional impairment of the lung or arteries

  23. Hemoglobin Hemoglobin is a protein found in red blood cells that is comprised of two alpha and two beta subunits that surround an iron-containing heme group. Oxygen readily binds this heme group

  24. Oxygen Dissociation Curve The oxygen dissociation curve demonstrates that, as the partial pressure of oxygen increases, more oxygen binds hemoglobin. However, the affinity of hemoglobin for oxygen may shift to the left or the right depending on environmental conditions

  25. Diseases and Oxygen Binding Individuals with sickle cell anemia have crescent-shaped red blood cells. Disease states and altered conditions in the body can affect the binding ability of oxygen, and increase or decrease its ability to dissociate from hemoglobin

  26. Transport of Carbon Dioxide in the Blood Carbon dioxide can be transported through the blood via three methods: • dissolved directly in the blood • bound to plasma proteins or hemoglobin • converted into bicarbonate

  27. Practice Question Why is the mammalian left lung smaller than the right lung?

  28. Quick Review • How does air pass from the outside environment to the lungs? • How does gas pressure influence how gases move into and out of the body? • How do the structures of the respiratory system control the mechanics of breathing? • How are gases transported in the body?

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