Upload
august-francis
View
219
Download
1
Embed Size (px)
Citation preview
Transport of gases Transport of gases in the bloodin the blood
Gas exchange between the alveolar air and the blood in pulmonary capillaries results in an increased oxygen concentration and a decreased carbon dioxide concentration in the blood leaving the lungs. This blood enters the systemic arteries, where blood gas measurements are taken to assess the effectiveness of lung function.
Composition of respired airComposition of respired airin QUIET BREATING (of the 500 ml atmospheric air)in QUIET BREATING (of the 500 ml atmospheric air)
INSPIREDINSPIRED in a single inspirationin a single inspiration
OXYGEN makes up about 21%OXYGEN makes up about 21%
NITROGEN about 79%NITROGEN about 79%
CARBON DIOXIDE about 0.04%CARBON DIOXIDE about 0.04%
150 150 ml occupy the conducting passages – “dead space” air.ml occupy the conducting passages – “dead space” air.
This remains unchanged in composition since it is not in contact This remains unchanged in composition since it is not in contact
with respiratory surfaces.with respiratory surfaces.
350 ml reach the respiratory units and mix with 2.4 liters alveolar air 350 ml reach the respiratory units and mix with 2.4 liters alveolar air (Functional Residual Capacity).(Functional Residual Capacity).
Alveolar air is saturated with Alveolar air is saturated with WATER VAPOURWATER VAPOUR. It constantly gives up . It constantly gives up OXYGEN to the bloodOXYGEN to the blood, and constantly takes up , and constantly takes up CARBON DIOXIDE CARBON DIOXIDE from the bloodfrom the blood..
EXSPIRED EXSPIRED in a single expirationin a single expirationOXYGEN makes up 15.7%OXYGEN makes up 15.7%
NITROGEN 74.5%NITROGEN 74.5%
CARBON DIOXIDE 3.6%CARBON DIOXIDE 3.6%
WATER VAPOUR 6.2%WATER VAPOUR 6.2%
This represents a mixture of: “This represents a mixture of: “dead space” airdead space” air – air which has moved out – air which has moved out
unchanged from the unchanged from the conducting passages conducting passages AndAnd
Alveolar airAlveolar air - air which has been in contact with respiratory surfaces and - air which has been in contact with respiratory surfaces and
has given up some has given up some oxygenoxygen to the blood and taken up to the blood and taken up carbon dioxidecarbon dioxide from it. from it.
OXYGEN 13.6%OXYGEN 13.6%
NITROGEN 74.9%NITROGEN 74.9%
CARBON DIOXIDE 5.3%CARBON DIOXIDE 5.3%
WATER VAPOUR 6.2%WATER VAPOUR 6.2%
MOVEMENT OF RESPIRATORY GASESMOVEMENT OF RESPIRATORY GASES
A gas moves from an area where it is present A gas moves from an area where it is present at higher pressure to an area where it is at higher pressure to an area where it is present at lower pressure. The movement of present at lower pressure. The movement of gas molecules continues till pressure exerted gas molecules continues till pressure exerted by them is the same throughout both area. by them is the same throughout both area. Dry atmospheric air (at sea level) has a Dry atmospheric air (at sea level) has a pressure of 1 atmosphere = 760 mmHg = pressure of 1 atmosphere = 760 mmHg = 101.3 kilopascals (kPa).101.3 kilopascals (kPa).
Partial pressures of gases in blood
ALVEOLAR VENTILATION and DEAD SPACEALVEOLAR VENTILATION and DEAD SPACE
At rest, with each breath, we breathe in about At rest, with each breath, we breathe in about 500 ml of fresh atmospheric air (the TIDAL 500 ml of fresh atmospheric air (the TIDAL volume). Of this volume 350 ml mix with air volume). Of this volume 350 ml mix with air already in the already in the lung alveoli and 150 ml occupy lung alveoli and 150 ml occupy the air passages (anatomical dead space) the air passages (anatomical dead space) and do not take part in exchangeand do not take part in exchange with gases with gases in the blood. It is instructive to consider the in the blood. It is instructive to consider the fate of one breath of dry air at rest. For fate of one breath of dry air at rest. For simplicity, consider the rate of breathing to be simplicity, consider the rate of breathing to be 10 breaths per minute.10 breaths per minute.
Stage 1Stage 1
Stage 2Stage 2
Stage 3Stage 3
Stage 4Stage 4
In this case,In this case, Dead space ventilationDead space ventilation = = 150 x 10 =1,500 ml/min.150 x 10 =1,500 ml/min. Alveolar ventivationAlveolar ventivation = = 350 x 10 = 3,500 ml/min.350 x 10 = 3,500 ml/min. Total ventilationTotal ventilation = = 500 x 10 = 5,000 ml/min.500 x 10 = 5,000 ml/min.
For simplicity, the COFor simplicity, the CO22 in 350 ml of atmospheric air in 350 ml of atmospheric air
which would be 0.14 ml has been called 0 ml and Nwhich would be 0.14 ml has been called 0 ml and N22
which would be approximately 276 ml has not been which would be approximately 276 ml has not been quantified, not has the water output.quantified, not has the water output.
Forms of oxygen transportForms of oxygen transport
Physically dissolved in plasma
Chemically bound to
hemoglobin
Physically dissolved oxygenPhysically dissolved oxygen
2*760
Ргаз
кровімлнамлО 1003,095*760
024,02
Henry-Dalton law
The value of physically dissolved oxygenThe value of physically dissolved oxygen
provides diffusion of O2 (the transition into provides diffusion of O2 (the transition into the blood or from the blood O2 must go in the blood or from the blood O2 must go in physically dissolved state and only in this physically dissolved state and only in this form can diffuse);form can diffuse);
physically dissolved oxygen significantly physically dissolved oxygen significantly affects the properties of hemoglobinaffects the properties of hemoglobin
Chemically bound to hemoglobinChemically bound to hemoglobin
Oxyhemoglobin dissociation curveOxyhemoglobin dissociation curve
The curve describes the dependence of The curve describes the dependence of the degree of hemoglobin oxygen the degree of hemoglobin oxygen saturation from O2 tension in the blood.saturation from O2 tension in the blood.
Hemoglobin oxygen saturation (SO2) - the Hemoglobin oxygen saturation (SO2) - the percentage between oxyhemoglobin and percentage between oxyhemoglobin and total hemoglobin content.total hemoglobin content.
%100*
2
22 НbНbО
HbОSO