Hypoxemia refers to low oxygen in the blood, and the more general term hypoxia is an abnormally low oxygen content in any tissue or organ, or the body as a whole. Hypoxemia can cause hypoxia (hypoxemic hypoxia), but hypoxia can also occur via other mechanisms, such as anemia.
Hypoxemia is usually defined in terms of reduced partial pressure of oxygen (mm Hg) in arterial blood, but also in terms of reduced content of oxygen (ml oxygen per dl blood) or percentage saturation of hemoglobin (the oxygen binding protein within red blood cells) with oxygen, which is either found singly or in combination.
While there is general agreement that an arterial blood gas measurement which shows that the partial pressure of oxygen is lower than normal constitutes hypoxemia, there is less agreement concerning whether the oxygen content of blood is relevant in determining hypoxemia. This definition would include oxygen carried by hemoglobin. The oxygen content of blood is thus sometimes viewed as a measure of tissue delivery rather than hypoxemia.
Just as extreme hypoxia can be called anoxia, extreme hypoxemia can be called anoxemia.
Chronic hypoxemia may be compensated or uncompensated. The compensation may cause symptoms to be overlooked initially, however, further disease or a stress such as any increase in oxygen demand may finally unmask the existing hypoxemia. In a compensated state, blood vessels supplying less-ventilated areas of the lung may selectively contract, to redirect the blood to areas of the lungs which are better ventilated. However, in a chronic context, and if the lungs are not well ventilated generally, this mechanism can result in pulmonary hypertension, overloading the right ventricle of the heart and causing cor pulmonale and right sided heart failure. Polycythemia can also occur. In children, chronic hypoxemia may manifest as delayed growth, neurological development and motor development and decreased sleep quality with frequent sleep arousals.
Hypoxemia refers to insufficient oxygen in the blood. Thus any cause that influences the rate or volume of air entering the lungs (ventilation) or any cause that influences the transfer of air from the lungs to the blood may cause hypoxemia. As well as these respiratory causes, cardiovascular causes such as shunts may also result in hypoxaemia.
Hypoxemia is caused by five categories of etiologies: hypoventilation, ventilation/perfusion mismatch, right-to-left shunt, diffusion impairment, and low PO2. Low PO2 and hypoventilation are associated with a normal A-a gradient whereas the other categories are associated with an increased A-a gradient.:229
If the alveolar ventilation is insufficient, there will not be enough oxygen delivered to the alveoli for the body's use. This can cause hypoxemia even if the lungs are normal, as the cause is in the brainstem's control of ventilation or in the body's inability to breathe effectively.
Respiration is controlled by centres in the medulla, which influence the rate of breathing and the depth of each breath. This is influenced by the blood level of carbon dioxide, as determined by central and peripheral chemoreceptors located in the central nervous system and carotid and aortic bodies, respectively. Hypoxia occurs when the breathing center doesn't function correctly or when the signal is not appropriate:
Central sleep apnea. During sleep, the breathing centers of the brain can pause their activity, leading to prolonged periods of apnea with potentially serious consequences.
Hyperventilation followed by prolonged breath-holding. This hyperventilation, attempted by some swimmers, reduces the amount of carbon dioxide in the lungs. This reduces the urge to breathe. However, it also means that falling blood oxygen levels are not sensed, and can result in hypoxemia.
A variety of conditions that physically limit airflow can lead to hypoxemia.
Suffocation, including temporary interruption temporary cessation of breathing as in obstructive sleep apnea, or bedclothes may interfere with breathing in infants, a putative cause of SIDS.
Structural deformities of the chest, such as scoliosis and kyphosis, which can restrict breathing and lead to hypoxia.
Muscle weakness, which may limit the ability of the diaphragm, the primary muscle for drawing new air into lungs, to function. This may be a result of a congenital disease, such as motor neuron disease, or an acquired condition, such as fatigue in severe cases of COPD.
Oxygen-Haemoglobin Dissassociation Curve.
In conditions where the proportion of oxygen in the air is low, or when the partial pressure of oxygen has decreased, less oxygen is present in the alveoli of the lungs. The alveolar oxygen is transferred to hemoglobin, a carrier protein inside red blood cells, with an efficiency that decreases with the partial pressure of oxygen in the air.
Altitude. The external partial pressure of oxygen decreases with altitude, for example in areas of high altitude or when flying. This decrease results in decreased carriage of oxygen by haemoglobin. This is particularly seen as a cause of cerebral hypoxia and mountain sickness in climbers of Mount Everest and other peaks of extreme altitude. For example, at the peak of Mount Everest, the partial pressure of oxygen is just 43 mmHg, whereas at sea level the partial pressure is 150 mmHg. For this reason, cabin pressure in aircraft is maintained at 5,000 to 6,000 feet (1500 to 1800 m).
Diving. Hypoxia in diving can result from sudden surfacing. The partial pressures of gases increases when diving, increases by one ATM every ten metres. This means that a partial pressure of oxygen sufficient to maintain good carriage by haemoglobin is possible at depth, even if it is insufficient at the surface. A diver that remains underwater will slowly consume their oxygen, and when surfacing, the partial pressure of oxygen may be insufficient (shallow water blackout). This may manifest at depth as deep water blackout.
Suffocation. Decreased concentration of oxygen in inspired air caused by reduced replacement of oxygen in the breathing mix.
Air depleted of oxygen has also proven fatal. In the past, anesthesia machines have malfunctioned, delivering low-oxygen gas mixtures to patients. Additionally, oxygen in a confined space can be consumed if carbon dioxide scrubbers are used without sufficient attention to supplementing the oxygen which has been consumed.
This refers to a disruption in the ventilation/perfusion equilibrium. Oxygen entering the lungs typically diffuses across the alveolar-capillary membrane into blood. However this equilibration does not occur when the alveolus is insufficiently ventilated, and as a consequence the blood exiting that alveolus is relatively hypoxemic. When such blood is added to blood from well ventilated alveoli, the mix has a lower oxygen partial pressure than the alveolar air, and so the A-a difference develops. Examples of states that can cause a ventilation-perfusion mismatch include:
Exercise. Whilst modest activity and exercise improves ventilation-perfusion matching, hypoxemia may develop during intense exercise as a result of preexisting lung diseases. During exercise, almost half of the hypoxemia is due to diffusion limitations (again, on average).
Aging. An increasingly poor match between ventilation and perfusion is seen with age, as well as a decreased ability to compensate for hypoxic states.:646
Disease that affect the pulmonary interstitum can also result in hypoxia, by affecting the ability of oxygen to diffuse into arteries. An example of these diseases is pulmonary fibrosis, where even at rest a fifth of the hypoxemia is due to diffusion limitations (on average).
Cirrhosis can be complicated by refractory hypoxemia due to high rates of blood flow through the lung, resulting in ventilation-perfusion mismatch.
Shunting refers to blood that bypasses the pulmonary circulation, meaning that the blood does not receive oxygen from the alveoli. In general, a shunt may be within the heart or lungs, and cannot be corrected by administering oxygen alone. Shunting may occur in normal states:
Physiological shunts, occur due to the effect of gravity. The highest concentration of blood in the pulmonary circulation occurs in the bases of the pulmonary tree compared to the highest pressure of gas in the apexes of the lungs. Alveoli may not be ventilated in shallow breathing.
Shunting may also occur in disease states:
Acute lung injury and adult respiratory distress syndrome, which may cause alveolar collapse. This will increase the amount of physiological shunting, and unlike many forms of shunting, can be managed by administering 100% Oxygen.
Exercise-induced arterial hypoxemia occurs during exercise when a trained individual exhibits an arterial oxygen saturation below 93%. It occurs in fit, healthy individuals of varying ages and genders. Adaptations due to training include an increased cardiac output from cardiac hypertrophy, improved venous return, and metabolic vasodilation of muscles, and an increased VO2 Max. There must be a corresponding increase in VCO2 thus a necessity to clear the carbon dioxide to prevent a metabolic acidosis. The hypoxemia occurs in these individuals whereby due to increased pulmonary blood flow:
Reduced capillary transit time occurs due to an increased blood flow within the pulmonary capillary. Capillary transit time (tc), at rest is around 0.8s, allowing plenty of time for the diffusion of oxygen into the circulation and the diffusion of CO2 out of the circulation. After training, the capillary volume is still the same however cardiac output is increased, resulting in a decreased capillary transit time, reducing to around 0.16s in trained individuals at maximal work rates. This does not give sufficient time for gas diffusion and results in a hypoxaemia.
Intrapulmonary arteriovenous shunts are dormant capillaries within the lungs that become recruited when venous pressures become too high. They are normally located within deadspace area thus the blood passing through does no become oxygenated resulting in a hypoxemia.
Key to understanding whether the lung is involved in a particular case of hypoxemia is the difference between the alveolar and the arterial oxygen levels; this A-a difference is often called the A-a gradient and is normally small. The arterial oxygen partial pressure is obtained directly from an arterial blood gas determination. The oxygen contained in the alveolar air can be calculated because it will be directly proportional to its fractional composition in air. Since the airways humidify (and so dilute) the inhaled air, the barometric pressure of the atmosphere is reduced by the vapor pressure of water.
The term hypoxemia was originally used to describe low blood oxygen occurring at high altitudes and was defined generally as defective oxygenation of the blood.
^Pollak, Charles P.; Thorpy, Michael J.; Yager, Jan (2010). The encyclopedia of sleep and sleep disorders (3rd ed.). New York, NY. p. 104. ISBN9780816068333.
^ abcMartin, Lawrence (1999). All you really need to know to interpret arterial blood gases (2nd ed.). Philadelphia: Lippincott Williams & Wilkins. p. xxvi. ISBN978-0683306040.
^Eckman, Margaret (2010). Professional guide to pathophysiology (3rd ed.). Philadelphia: Wolters Kluwer/Lippincott Williams & Wilkins. p. 208. ISBN978-1605477664.
Robert J. Mason, V. Courtney Broaddus, Thomas R. Martin, Talmadge E. King, Dean E. Schraufnagel, John F. Murray and Jay A. Nadel (eds.) (2010) Murray & Nadel's Textbook of Respiratory Medicine, 5th ed. Philadelphia: Saunders Elsevier. ISBN1-4160-4710-7.
Morris, Alan; Kanner, Richard; Crapo, Robert; Gardner, Reed. (1984) Clinical Pulmonary Function Testing. A manual of uniform laboratory procedures, 2nd ed.
Lorenzo Del Sorbo, Erica L. Martin, V. Marco Ranieri (2010) "Hypoxemic Respiratory Failure" In: Murray & Nadel's Textbook of Respiratory Medicine, Robert J. Mason, V. Courtney Broaddus, Thomas R. Martin, Talmadge E. King, Dean E. Schraufnagel, John F. Murray and Jay A. Nadel (eds.) 5th ed. Philadelphia: Saunders Elsevier. ISBN1-4160-4710-7.
^ abWilson, William C.; Grande, Christopher M.; Hoyt, David B., eds. (2007). Critical care. New York: Informa Healthcare. ISBN978-0-8247-2920-2.
^ abcdeColledge NR, Walker BR, Ralston SH, eds. (2010). Davidson's principles and practice of medicine (21st ed.). Edinburgh: Churchill Livingstone/Elsevier. ISBN978-0-7020-3085-7.
^Adde, FV; Alvarez, AE; Barbisan, BN; Guimarães, BR (Jan–Feb 2013). "Recommendations for long-term home oxygen therapy in children and adolescents". Jornal de Pediatria. 89 (1): 6–17. doi:10.1016/j.jped.2013.02.003. PMID23544805.
^Fauci, Anthony S.; Harrison, T. R., eds. (2008). Harrison's principles of internal medicine (17th ed.). New York: McGraw-Hill Medical. ISBN978-0-07-147692-8.
^West JB, Boyer SJ, Graber DJ, Hackett PH, Maret KH, Milledge JS, Peters RM, Pizzo CJ, Samaja M, Sarnquist FH (September 1983). "Maximal exercise at extreme altitudes on Mount Everest". Journal of Applied Physiology: Respiratory, Environmental and Exercise Physiology. 55 (3): 688–98. doi:10.1152/jappl.19184.108.40.2068. PMID6415008.
^Grocott, MP; Martin, DS; Levett, DZ; McMorrow, R; Windsor, J; Montgomery, HE; Caudwell Xtreme Everest Research, Group (Jan 8, 2009). "Arterial blood gases and oxygen content in climbers on Mount Everest". The New England Journal of Medicine. 360 (2): 140–9. doi:10.1056/NEJMoa0801581. PMID19129527.
Dean R. Hess, Neal R. MacIntyre, Shelley C. Mishoe, William F. Galvin, Alexander B. Adams (2012) Respiratory Care: Principles and Practice. (eds.) (2nd ed). Jones and Bartlet Learning ISBN978-0-7637-6003-8
Jacob Samuel and Cory Frankling, "Hypoxemia and Hypoxia" in Jonathan A. Myers, Keith W. Millikan and Theodore J. Saclarides (eds) (2008) Common Surgical Diseases. (2nd ed.). 391-394 ISBN978-0-387-75245-7