Respiratory System 

-The respiratory system  is responsible for the exchange of

 oxygen and carbon dioxide by the body .                

 -The gas exchange organs are the lungs . In addition to gas  exchange , the lungs have a variety of other functions,   including   contributing to the bodys acid-base balance,     speech, metabolism of certain vasoactive compounds , and defense against infection.                                                    

-Metabolizing cells require a continuous supply of oxygen and continuously produce carbon dioxide.

-To provide adequate oxygen to the cells and remove sufficient amounts of carbon dioxide from them, the lungs must be ventilated and perfused at all times.

-Gas exchange is limited if the lungs ( or a region of the lungs) are ventilated but not receiving a dequate blood flow or vice versa.            

 -Major functional evets of respiration include ventilation, is how air moves in and out of the alveoli ; diffusion of oxygen ( O2) and CO2 between the blood and alveoli ; transport of O2 and CO2 to and from the peripheral tissues ; and regulation of respiration.

Anatomy of the lungs 

-Air passes into the trachiobronchial tree ( air ways) through the nose and mouth.

-It is warmmed to body temperature, humidified , and ,         if entering through the nose , filtered .

-The airways  bring the inspired air to the gas- exchange region of the lungs ; these are the respiratory bronchioles, alveolar ducts and alveoli.

- From the trachea to the alveolar sacs , there are approximately  23generations of sequential branching.         

-The first 16 of so generations constitute the conducting zone. The blood flow to this portion of the airways is primarily to provide nutrients to the smooth muscle of the air ways that constitute the conducting zone. 

- Because no gas is exchanged in these airways , the conducting zone constitutes the anatomic dead space.

- Each generation of branching increases the collective cross sectional area of the air ways, while reducing the radius of each individual airway & the velocity of the air flow within that airway.                                       

-Around the sixteenth or seventeenth branching generation  ( between the terminal  and respiratory bronchioles ) , there is a transitional zone.                                                                  -Generations 17 to 23 constitute the respiratory zone , comprising respiratory bronchioles , alveolar ducts ( with smooth muscle sphincters only ) , and alveolar sacs.

- It is in the respiratory zone , principally the alveolar sacs , that gas exchange occurs.                                

-There are approximately300 million alveoli in the lung, each with an average diameter of 0.3 mm.

-These multiple generations of branching translate into an enormous area for gas exchange ( 50 to 100 m² ,average 70 m²).                 

-The large contact area between alveolar gas and pulmonary capillary blood , coupled with a very thin alveolar- capillary barrier ( approximately 0.5 µ  ) , highly soluble respiratory gases ( O2 and CO2 ) , and driving pressures for both O2 and CO2 between the alveoli and pulmonary capillary blood endow the respiratory system with the ideal characteristics for exchanging gas by passive diffusion.                                   -The alveoli are lined by two types of epithelial cells , Type I cells are flat cells with large cytoplasmic extensions and are the primary lining cells.                                                             -Type II cells (granular pneumocytes ) are thicker and contain numerous lamellar inclusion bodies. These cells secrete surfactant.                                                                        -There may be other special types of epithelial cells, and the   lung also contains pulmonary alveolar macrophages

 ( PAMS ) , lymphocytes , plasma cells and mast cells.           

The process of respiration can be divided into four major events:-                                         (1) - Pulmonary ventilation; which means the inflow and      outflow of air between the atmosphere and the lung alveoli.  

(2)- Diffusion of oxygen and carbon dioxide between the alveoli and the blood.                                                                  (3)- Transport of O2 and CO2 in the blood and body fluids to and from the cells.                                                                  (4)- Regulation of ventilation .

Pulmonary ventilation                                                      -Pulmonary ventilation includes inspiration and expiration.

-The lungs and the chest wall are elastic structures.

- Lung movement during inspiration results from the forces generated by the respiratory muscles.                                                                Muscles of respiration                       Inspiration occurs through :-                                 

 -The diaphragm is the most important muscle of inspiration.   ( it is the only respiratory muscle used during rest.)              - Contraction of the diaphragm elongates the thoracic cavity , causing the lungs to expand.

 -During strenuous activity , muscles of inspiration also      include the external intercostals and accessory muscles in the neck , which pull the rib cage up ward and forward in a” bucket handle” motion , increasing the thickness of the chest cavity.

Expiration occurs :-                                                          -Passively during quiet breathing by elastic recoil of the lungs and chest wall. The lungs and chest wall elastic and tend to return to their resting positions following inspiration.

-Expiration becomes an active process during exercise and other strenuous activities in which breathing increases greatly.

 -Expiration is also active when airway resistance is increased in  diseases such as asthma.  

-The major muscles of expiration are the abdominal muscles.

 -Contraction of these forces the abdominal viscera upward    against the bottom of the diaphragm .                                       -The internal intercostals help with expiration by pulling the chest cage downward and inward , which decreases the   thickness of the chest cavity.

The breathing cycle

-Lung volume increases and decreases as the thoracic cavity expands and contracts.                                                                -The lungs float freely in the thoracic cavity ; whenever the length or thickness of the thoracic cavity increases or decreases  , simultaneous changes in lung volume must also occur.

-The space between the visceral pleura of the lungs and parietal pleura of the thoracic cage is called the intrapleural. -Continuous absorption of fluid by lymphatic channels keeps the space nearly empty except for a few milliliters of pleural fluid that provide lubrication for the moving lungs.

-So normally, there is no more than a thin layer of fluid         between the lungs and the chest wall.                                  

-The lungs slide easily on the chest wall but resist being       pulled away from it.                                                                

 -The pressure in the space between the lungs and chest wall   ( intrapleural pressure ) is subatmospheric.                            -The lungs are stretched when they are expanded at birth, and at the end of quiet expiration their tendency to recoil from the chest wall is just balanced by the tendency of the chest wall to recoil in the opposite direction.                              -If the chest wall is opened , the lungs collapse; and if the lungs lose their elasticity , the chest expands and becomes barrel – shaped .

During rest before inspiration begins                             -The pressures in all parts of the pulmonary tree are equal to the atmospheric pressure, which is considered to  be zero cm.water.                                                                                      -Thus, there is no pressure gradient for air to flow.          

-Intrapleural pressure is subatmospheric (about – 2.5 mmHg) because of the  opposing tendencies of lungs to collapse and the chest to expand.                                                                                     During inspiration                          -Inspiration is an active process.                          

-The contraction of the inspiratory muscles ( primarily the diaphragm ) increases intrathoracic volume.                            -The intrapleural pressure at the base of the lungs , which is normally about (-2.5 mmHg or –5 cm H2O )(relative to atmospheric ) . At the start of inspiration , decreases to about  ( -6 mmHg ).                                                                    –The lungs are pulled into a more expanded position.             -The pressure in the airway becomes slightly negative, and air flows into the lungs. At the end of inspiration, alveolar        pressure is again zero and air flow ceases.              

During expiration 

-When inspiration terminates, the diaphragm relax, and the elastic recoil of the lungs compresses the alveolar gases, increasing alveolar pressure to about +1 cm water.                 -Since alveolar pressure is now greater than atmospheric pressure, air flows out of the lungs. Intrapleural pressure returns to its preinspiratory level.                                             -Thus, during a normal respiratory cycle, intrapleural pressure fluctuates solely in the negative range between about –5 and –8 cm water.                                                         -At the end of expiration, alveolar pressure is once again equal to atmospheric pressure, causing air flow to stop.