oxygenation
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OxygenationOxygenationGroup 10 BSN III - CGroup 10 BSN III - C
Gas Exchange in Lungs Gas Exchange in Lungs
The body requires oxygen in order to produce energy for our cells to do work. Therefore, it is essential that we have an efficient system of obtaining oxygen from the air. Our bodies also produce a toxic gas called carbon dioxide that must be efficiently removed from the body to prevent cell damage. When we inhale, we pick up oxygen from air. When we exhale, we flush out carbon dioxide.
The body requires oxygen in order to produce energy for our cells to do work. Therefore, it is essential that we have an efficient system of obtaining oxygen from the air. Our bodies also produce a toxic gas called carbon dioxide that must be efficiently removed from the body to prevent cell damage. When we inhale, we pick up oxygen from air. When we exhale, we flush out carbon dioxide.
The Structures of the Respiratory System
The Structures of the Respiratory System
Mouth and Nose- these are the openings where respiratory gases enter and leave the body.
Trachea (windpipe)- this passage way connects the mouth and nose to the lungs.
Lungs- these are the balloon-like structures that temporarily hold air in the body.
Bronchial tube- the trachea breaks up into these smaller tubes to enter the right and left lungs.
Bronchioles- within the lungs the bronchi split into these even smaller tubes which attach to the alveoli.
Alveoli- these are the small sac-like structures where gas exchange occurs with the blood.
Mouth and Nose- these are the openings where respiratory gases enter and leave the body.
Trachea (windpipe)- this passage way connects the mouth and nose to the lungs.
Lungs- these are the balloon-like structures that temporarily hold air in the body.
Bronchial tube- the trachea breaks up into these smaller tubes to enter the right and left lungs.
Bronchioles- within the lungs the bronchi split into these even smaller tubes which attach to the alveoli.
Alveoli- these are the small sac-like structures where gas exchange occurs with the blood.
Gas Exchange in the lungs
Gas Exchange in the lungs
Alveoli are tiny balloon-like sacs, in the lungs, where gas exchange takes place and they serve as the barrier between the external environment (the air) and the internal environment (the blood).
Alveoli are tiny balloon-like sacs, in the lungs, where gas exchange takes place and they serve as the barrier between the external environment (the air) and the internal environment (the blood).
AlveoliAlveoli
These small sacs have very thin walls that are full of blood vessels called capillaries. The walls are so thin that the oxygen, brought in during inhalation, can diffuse through them to enter your blood.
Likewise, carbon dioxide is carried by your blood to the blood vessels in the alveoli where it diffuses through the thin walls and into the air in your lungs. That "used" air is now ready for exhalation. Each lung has millions of alveoli, and your body needs all of them to get enough oxygen into your blood!
These small sacs have very thin walls that are full of blood vessels called capillaries. The walls are so thin that the oxygen, brought in during inhalation, can diffuse through them to enter your blood.
Likewise, carbon dioxide is carried by your blood to the blood vessels in the alveoli where it diffuses through the thin walls and into the air in your lungs. That "used" air is now ready for exhalation. Each lung has millions of alveoli, and your body needs all of them to get enough oxygen into your blood!
Muscles involved in Gas Exchange
Muscles involved in Gas Exchange
Breathing requires the help of a muscle known as the diaphragm.
The diaphragm is a large, sheet-like muscle at the bottom of your chest cavity. It helps you exhale and inhale by moving up and down, respectively.
When your diaphragm contracts (moves up), you inhale air.
When your diaphragm relaxes (moves down), you exhale air.
Without your diaphragm, you lungs couldn’t fill up with fresh air
or push old air out.
Breathing requires the help of a muscle known as the diaphragm.
The diaphragm is a large, sheet-like muscle at the bottom of your chest cavity. It helps you exhale and inhale by moving up and down, respectively.
When your diaphragm contracts (moves up), you inhale air.
When your diaphragm relaxes (moves down), you exhale air.
Without your diaphragm, you lungs couldn’t fill up with fresh air
or push old air out.
Five Parts of Gas Exchange
Five Parts of Gas Exchange
BreathingExternal RespirationGas Transport Internal RespirationCellular Respiration
BreathingExternal RespirationGas Transport Internal RespirationCellular Respiration
BreathingBreathing
It is consists of two phases: inspiration and expiration
During inspiration, the diaphragm and the intercostal muscles contract. The diaphragm moves downwards increasing the volume of the thoracic (chest) cavity, and the intercostal muscles pull the ribs up expanding the rib cage and further increasing this volume.
During expiration the diaphragm and intercostal muscles relax. This returns the thoracic cavity to it's original volume, increasing the air pressure in the lungs, and forcing the air out.
It is consists of two phases: inspiration and expiration
During inspiration, the diaphragm and the intercostal muscles contract. The diaphragm moves downwards increasing the volume of the thoracic (chest) cavity, and the intercostal muscles pull the ribs up expanding the rib cage and further increasing this volume.
During expiration the diaphragm and intercostal muscles relax. This returns the thoracic cavity to it's original volume, increasing the air pressure in the lungs, and forcing the air out.
External Respiration External Respiration
It is the exchange of oxygen and carbon dioxide between the air and the blood in the lungs.
It is the exchange of oxygen and carbon dioxide between the air and the blood in the lungs.
Gas TransportGas Transport
Haemoglobin, the main means of oxygen transport in the body. The respiratory pigment haemoglobin is made up of an iron-containing porphyron, haem, combined with the protein globin. Each iron atom in haem is attached to four pyrole groups by covalent bonds. A fifth covalent bond of the iron is attached to the globin part of the molecule and the sixth covalent bond is available for combination with oxygen. There are four iron atoms in each heamoglobin molecule and therefore four heam groups.
Haemoglobin, the main means of oxygen transport in the body. The respiratory pigment haemoglobin is made up of an iron-containing porphyron, haem, combined with the protein globin. Each iron atom in haem is attached to four pyrole groups by covalent bonds. A fifth covalent bond of the iron is attached to the globin part of the molecule and the sixth covalent bond is available for combination with oxygen. There are four iron atoms in each heamoglobin molecule and therefore four heam groups.
Oxygen Transport Oxygen Transport
Oxygen needs to be transported from the lungs to the tissues.
Most of the oxygen (97%) combines loosely with hemoglobin in the RBC and is carried to the tissues as oxyhemoglobin.
The remaining oxygen is dissolved and transported in the fluid of the plasma and cells.
Oxygen needs to be transported from the lungs to the tissues.
Most of the oxygen (97%) combines loosely with hemoglobin in the RBC and is carried to the tissues as oxyhemoglobin.
The remaining oxygen is dissolved and transported in the fluid of the plasma and cells.
Carbon Dioxide TransportCarbon Dioxide Transport
Out of the carbon dioxide released from respiring cells, 7% dissolves into the plasma, 23% binds to the multiple amino groups of haemoglobin (Caroxyhaemoglobin), and 70% is carried as bicarbonate ions. Carbon dioxide created by respiring cells diffuses into the blood plasma and then into the red blood cells, where most of it is converted to bicarbonate ions.
Out of the carbon dioxide released from respiring cells, 7% dissolves into the plasma, 23% binds to the multiple amino groups of haemoglobin (Caroxyhaemoglobin), and 70% is carried as bicarbonate ions. Carbon dioxide created by respiring cells diffuses into the blood plasma and then into the red blood cells, where most of it is converted to bicarbonate ions.
Internal Respiration Internal Respiration
The body tissues need the oxygen and have to get rid of the carbon dioxide, so the blood carried throughout the body exchanges oxygen and carbon dioxide with the body's tissues. Internal respirtaion is basically the exchange of gasses between the blood in the capillaries and the body's cells.
The body tissues need the oxygen and have to get rid of the carbon dioxide, so the blood carried throughout the body exchanges oxygen and carbon dioxide with the body's tissues. Internal respirtaion is basically the exchange of gasses between the blood in the capillaries and the body's cells.
Cellular RespirationCellular Respiration
Cellular respiration describes the metabolism reactions and processes that take place in a cell to obtain biochemical energy from fuel molecules and the release of the cells' waste products. Energy is released by the oxidation of fuel molecules and is stored as "high-energy" carriers. The reactions involved in respiration are catabolic reactions in metabolism.
Cellular respiration describes the metabolism reactions and processes that take place in a cell to obtain biochemical energy from fuel molecules and the release of the cells' waste products. Energy is released by the oxidation of fuel molecules and is stored as "high-energy" carriers. The reactions involved in respiration are catabolic reactions in metabolism.
Gas Transport (Circulatory System)
Gas Transport (Circulatory System)
The heart, the blood, and the blood vessels make up a system for the transport of gases, nutrients, and chemical wastes. The primary functions of the circulatory system are the following: To transport nutrients and oxygen to the cells. To remove waste and carbon dioxide from the
cells. To provide for efficient gas exchange.
Blood vessels allow oxygenated blood and nutrients to reach the tissues and wastes to be removed from the tissues.
The blood is the medium that carries oxygen and nutrients to the tissue and is also the medium by which waste is transported to the appropriate locations.
The heart, the blood, and the blood vessels make up a system for the transport of gases, nutrients, and chemical wastes. The primary functions of the circulatory system are the following: To transport nutrients and oxygen to the cells. To remove waste and carbon dioxide from the
cells. To provide for efficient gas exchange.
Blood vessels allow oxygenated blood and nutrients to reach the tissues and wastes to be removed from the tissues.
The blood is the medium that carries oxygen and nutrients to the tissue and is also the medium by which waste is transported to the appropriate locations.
The HeartThe Heart
The heart is made up of cardiac muscle and is divided into 4 different chambers. The top two compartments are called atria, while the bottom two compartments are called ventricles.
The heart is made up of cardiac muscle and is divided into 4 different chambers. The top two compartments are called atria, while the bottom two compartments are called ventricles.
The Blood Vessel
The Blood Vessel
There are three basic types of blood vessels:Arteries- these carry "oxygen rich"
blood away from the heart, except in the case of the artery to the lungs.
Capillaries- these are the sites of gas exchange between the tissues.
Veins- these return "oxygen poor" blood to the heart, except for the vein that carries blood from the lungs.
There are three basic types of blood vessels:Arteries- these carry "oxygen rich"
blood away from the heart, except in the case of the artery to the lungs.
Capillaries- these are the sites of gas exchange between the tissues.
Veins- these return "oxygen poor" blood to the heart, except for the vein that carries blood from the lungs.
Circulatory path of blood
Circulatory path of blood
Arterial blood (oxygen rich blood) is in red , and venous blood (contains less oxygen) is in blue.
Arterial blood (oxygen rich blood) is in red , and venous blood (contains less oxygen) is in blue.
Blood FlowBlood Flow
For gas exchange to occur in the lungs and the rest of the body's tissues, blood must flow continuously through the tissues. The heart pushes blood through the tissues and provides a constant force for blood flow to occur.
The heart provides enough force to propel the blood through the arteries and veins in the body. The arteries entering tissues, called arterioles, can constrict (become more narrow) or dilate (become relaxed and less narrow) to change the amount of blood flowing to an area. If an arteriole constricts, less blood is available for the tissues it supplies. If an arteriole dilates, more blood reaches the tissues it supplies.
For gas exchange to occur in the lungs and the rest of the body's tissues, blood must flow continuously through the tissues. The heart pushes blood through the tissues and provides a constant force for blood flow to occur.
The heart provides enough force to propel the blood through the arteries and veins in the body. The arteries entering tissues, called arterioles, can constrict (become more narrow) or dilate (become relaxed and less narrow) to change the amount of blood flowing to an area. If an arteriole constricts, less blood is available for the tissues it supplies. If an arteriole dilates, more blood reaches the tissues it supplies.
Oxygen TherapyOxygen Therapy
The administration of oxygen at a concentration greater than that found in the environmental atmosphere.
The goal of oxygen therapy is to provide adequate transport of oxygen in the blood while decreasing the work of breathing and reducing stress in the myocardium.
The administration of oxygen at a concentration greater than that found in the environmental atmosphere.
The goal of oxygen therapy is to provide adequate transport of oxygen in the blood while decreasing the work of breathing and reducing stress in the myocardium.
IndicationIndication
Hypoxemia – a decrease in arterial oxygen tension in the blood
Hypoxemia – a decrease in arterial oxygen tension in the blood
Oxygen Administration Devices
Oxygen Administration Devices
Low Flow Systems1.Cannula
Suggested flow rate: 1-2 L/min, 3-6L/min; 6L/min
Oxygen Percentage Setting: 23-30; 30-40; 42
Advantages: lightweight, comfortable, inexpensive, continuous use with meals and activities.
Disadvantages: nasal mucosal drying, variable FiO2
Low Flow Systems1.Cannula
Suggested flow rate: 1-2 L/min, 3-6L/min; 6L/min
Oxygen Percentage Setting: 23-30; 30-40; 42
Advantages: lightweight, comfortable, inexpensive, continuous use with meals and activities.
Disadvantages: nasal mucosal drying, variable FiO2
Low Flow SystemsLow Flow Systems
2. Oropharyngeal catheterSuggested flow rate: 1-6 L/minOxygen percentage: 23-42Advantages: inexpensive does not
require tracheostomy Disadvantages: nasal mucosa
irritation; catheter should be changed frequently to alternate nostril
2. Oropharyngeal catheterSuggested flow rate: 1-6 L/minOxygen percentage: 23-42Advantages: inexpensive does not
require tracheostomy Disadvantages: nasal mucosa
irritation; catheter should be changed frequently to alternate nostril
Low Flow SystemsLow Flow Systems
3. Simple MaskSuggested flow rate: 6-8 L/minOxygen percentage setting: 40-60Advantages: simple to use,
inexpensiveDisadvantage: poor fitting, variable
FiO2, must remove to eat
3. Simple MaskSuggested flow rate: 6-8 L/minOxygen percentage setting: 40-60Advantages: simple to use,
inexpensiveDisadvantage: poor fitting, variable
FiO2, must remove to eat
Low Flow SystemsLow Flow Systems
4. Partial Rebreather MaskSuggested flow rate: 8-11L/minOxygen percentage setting: 50-75Advantages: moderate oxygen
concentration Disadvantage: warm, poorly fitting,
must remove to eat
4. Partial Rebreather MaskSuggested flow rate: 8-11L/minOxygen percentage setting: 50-75Advantages: moderate oxygen
concentration Disadvantage: warm, poorly fitting,
must remove to eat
Low Flow SystemsLow Flow Systems
5. Non breather MaskSuggested flow rate: 12L/minOxygen percentage setting: 80-100Advantages: high oxygen
concentration Disadvantage: poorly fitting
5. Non breather MaskSuggested flow rate: 12L/minOxygen percentage setting: 80-100Advantages: high oxygen
concentration Disadvantage: poorly fitting
High Flow SystemsHigh Flow Systems
1. Transtracheal catheter1. Suggested flow rate: ¼-4L/min2. Oxygen percentage setting: 60-1003. Advantages: high comfortable,
concealed by clothing, less oxygen L/min needed than nasal cannula
4. Disadvantage: requires frequent and regular cleaning, requires surgical intervention
1. Transtracheal catheter1. Suggested flow rate: ¼-4L/min2. Oxygen percentage setting: 60-1003. Advantages: high comfortable,
concealed by clothing, less oxygen L/min needed than nasal cannula
4. Disadvantage: requires frequent and regular cleaning, requires surgical intervention
High Flow SystemsHigh Flow Systems
2. Venturi Mask1. Suggested flow rate: 4-6L/min; 6-
8L/min2. Oxygen percentage setting:
24,26,28; 30, 35, 403. Advantages: provides low levels of
supplemental oxygen; precise FiO2, additional humidity available
4. Disadvantage: must remove to eat
2. Venturi Mask1. Suggested flow rate: 4-6L/min; 6-
8L/min2. Oxygen percentage setting:
24,26,28; 30, 35, 403. Advantages: provides low levels of
supplemental oxygen; precise FiO2, additional humidity available
4. Disadvantage: must remove to eat
High Flow SystemsHigh Flow Systems
3. Aerosol Mask1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
accurate FiO24. Disadvantage: uncomfortable for
some
3. Aerosol Mask1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
accurate FiO24. Disadvantage: uncomfortable for
some
High Flow SystemsHigh Flow Systems
4. Tracheostomy Collar1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
comfortable, fairly accurate FiO2
4. Tracheostomy Collar1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
comfortable, fairly accurate FiO2
High Flow SystemsHigh Flow Systems
5. T – piece 1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
comfortable, fairly accurate FiO24. Disadvantage: heavy with tubing
5. T – piece 1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity,
comfortable, fairly accurate FiO24. Disadvantage: heavy with tubing
High Flow SystemsHigh Flow Systems
6. Face Tent1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity, fairly
accurate FiO24. Disadvantage: Bulky and
cumbersome
6. Face Tent1. Suggested flow rate: 8-10L/min2. Oxygen percentage setting: 30-1003. Advantages: good humidity, fairly
accurate FiO24. Disadvantage: Bulky and
cumbersome
Common Nursing Diagnosis for Clients with oxygenation
problems
Common Nursing Diagnosis for Clients with oxygenation
problems Ineffective Airway Pattern- inability to clear
secretions or obstructions from respiratory tract to maintain a clear airway.
Ineffective Breathing Pattern- inspiration and expiration that does not provide adequate ventilation.
Impaired Gas Exchange- Excess or deficit in oxygenation and/or carbon dioxide elimination at the alveolar-capillary membrane.
Activity intolerance- Insufficient physiological or psychological energy to endure or complete required or desired daily activities.
Ineffective Airway Pattern- inability to clear secretions or obstructions from respiratory tract to maintain a clear airway.
Ineffective Breathing Pattern- inspiration and expiration that does not provide adequate ventilation.
Impaired Gas Exchange- Excess or deficit in oxygenation and/or carbon dioxide elimination at the alveolar-capillary membrane.
Activity intolerance- Insufficient physiological or psychological energy to endure or complete required or desired daily activities.
Other related Nursing Diagnosis
Other related Nursing Diagnosis
Anxiety related to ineffective airway clearance and feeling of suffocation.
Fear related to chronic disabling respiratory illness.
Powerlessness related to inability to maintain independence in self-care activities because of the ineffective breathing pattern.
Disturbed Sleeping Pattern related to orthopnea and required O2 therapy.
Social Isolation related to activity intolerance and inability to travel to usual social activities.
Anxiety related to ineffective airway clearance and feeling of suffocation.
Fear related to chronic disabling respiratory illness.
Powerlessness related to inability to maintain independence in self-care activities because of the ineffective breathing pattern.
Disturbed Sleeping Pattern related to orthopnea and required O2 therapy.
Social Isolation related to activity intolerance and inability to travel to usual social activities.
Intervention by the nurse to maintain the normal
respirations of clients include
Intervention by the nurse to maintain the normal
respirations of clients include Positioning the client to allow for
maximum chest expansion.Encouraging or providing frequent
changes in position.Encouraging ambulation. Implementing measures that
promote comfort, such as giving pain medications.
Positioning the client to allow for maximum chest expansion.
Encouraging or providing frequent changes in position.
Encouraging ambulation. Implementing measures that
promote comfort, such as giving pain medications.
Promoting Healthy Breathing
Promoting Healthy Breathing
Sit straight and stand erect to permit full lung expansion.
Exercise regularly. Breathe through the nose. Breathe in to expand the chest fully. Do not smoke cigarettes, cigars or
pipes. Eliminate or reduce the use of
household pesticides and irritating chemical substances.
Sit straight and stand erect to permit full lung expansion.
Exercise regularly. Breathe through the nose. Breathe in to expand the chest fully. Do not smoke cigarettes, cigars or
pipes. Eliminate or reduce the use of
household pesticides and irritating chemical substances.
Do not incinerate garbage in the house.
Avoid exposure to second hand smoke.
Use building materials that do not emit vapors.
Make sure furnaces, ovens and wood stoves are correctly ventilated.
Support a pollution-free environment.
Do not incinerate garbage in the house.
Avoid exposure to second hand smoke.
Use building materials that do not emit vapors.
Make sure furnaces, ovens and wood stoves are correctly ventilated.
Support a pollution-free environment.
Promoting Healthy Breathing
Promoting Healthy Breathing
Abdominal and Pursed-lip Breathing
Controlled and Huff Coughing Using Cough MedicationsUsing an Incentive Spirometer
Abdominal and Pursed-lip Breathing
Controlled and Huff Coughing Using Cough MedicationsUsing an Incentive Spirometer
Health EducationHealth Education
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