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'''Pulse oximetry''' is a [[non-invasive (medical)|non-invasive]] method which allows health care providers to monitor the [[oxygenation]] of a patient's [[blood]].   
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'''Pulse oximetry''' is a [[non-invasive (medical)|non-invasive]] method which uses [[colorimetric]] techniques to monitor the [[oxygenation]] of a patient's [[blood]].  Pulse oximeters are small units that variously can be used in [[field medicine]], at the bedside in a hospital or home care, and in the operating room. They complement more sophisticated [[blood gas analysis]].  Particularly in anesthesia or advanced field medicine where an artificial airway is inserted, direct [[carbon dioxide]] measurement with [[capnography]] is another complementary technique.   


A sensor is placed on a relatively thin part of the patient's [[anatomy]], usually a [[fingertip]] or [[earlobe]], or in the case of a neonate, across a foot, and red and infrared light is passed from one side to the otherChanging absorbance of each of the two wavelengths is measured, allowing determination of the absorbances due to the pulsing arterial blood alone, factoring out venous blood, skin, bone, muscle, fat, and even (in most cases) fingernail polish.  Based upon the ratio of changing absorbances of the red and infrared light caused by the difference in color between oxygen-bound (bright red) and unbound (dark red or in severe cases blue) [[hemoglobin]] in the blood, a measure of [[oxygenation]] (the percent of hemoglobin molecules bound with oxygen molecules) can be made.   
==Principle==
A sensor is placed on a relatively thin part of the patient's [[anatomy]], usually a [[fingertip]] or [[earlobe]]. In the case of a neonate, the sensor can be placed around the heel of the foot.  Then, light at two wavelengths is passed through the skin, and detected by a sensor on the other side of the skinChanges in the [[spectrophotometric]] absorbance of each of the two wavelengths is measured, allowing determination of the absorbances due to the pulsing arterial blood alone.  The measurement factors out venous blood, skin, bone, muscle, fat, and even (in most cases) fingernail polish.  Based upon the ratio of changing absorbances of the red and infrared light caused by the difference in color between oxygen-carrying (bright red) and non-carrying (dark red or in severe cases blue) [[hemoglobin]] in the blood, a measure of [[oxygen]] saturation (the percent of hemoglobin molecules bound with oxygen molecules) can be made.   


==Indication==
==History==
This is useful in any setting where a patient's oxygenation is unstable, including [[intensive care]], operating, recovery, emergency and hospital ward settings, pilots in unpressurized aircraft, for assessment of any patient's oxygenation, and determining the effectiveness of or need for supplemental [[oxygen]]. Assessing a patient's need for oxygen is often referred to as the ultimate vital sign; no human life thrives in the absence of oxygenAlthough pulse oximetry is used to monitor oxygenation, it cannot determine the metabolism of oxygen, or the amount of oxygen being used by a patient.  For this purpose, it is necessary to also measure [[carbon dioxide]] (CO<sub>2</sub>) levelsIt is possible that it can also be used to detect abnormalities in ventilation. However, the use of pulse oximetry to detect [[hypoventilation]] is impaired with the use of supplemental oxygen, as it is only when patients breathe room air that abnormalities in respiratory function can be detected reliably with its use. Therefore, the routine administration of supplemental oxygen may be unwarranted if the patient is able to maintain adequate oxygenation in room air, since it can result in hypoventilation going undetected.
Pulse Oximetry was developed by [[Nellcor]] Incorporated in 1982, and introduced into the US operating room market in 1983.  Prior to its introduction, a patient's oxygenation could only be determined by an [[blood gas analysis|arterial blood gas]], a single point measure which typically took a minimum of 20-30 minutes processing by a laboratory. (In the absence of oxygenation, damage to the brain starts in 5 minutes with brain death in another 10-15 minutes).  In the US alone, approximately $2 billion was spent annually on this measurementWith the introduction of pulse oximetry, a non-invasive, continuous measure of patient's oxygenation was possible, revolutionizing the practice of [[anesthesia]] and greatly improving patient safetyPrior to its introduction, studies in anesthesia journals estimated US patient mortality as a consequence of undetected [[hypoxemia]] at 2,000 to 10,000 deaths per year, with no known estimate of patient morbidity.


==History==
By 1987, the standard of care for the administration of a [[general anesthetic]] in the US included pulse oximetry.  From the operating room, the use of pulse oximetry rapidly spread throughout the hospital, first in the recovery room, and then into the various [[intensive care units]]Pulse oximetry was of particular value in the neonatal ICU, where the patients can suffer from inadequate [[oxygen]] levels, but also can be blinded by excessive concentrations of [[oxygen]]Furthermore, obtaining an [[arterial blood gas]] from a neonatal patient is extremely difficult.
Pulse Oximetry was developed by [[Nellcor]] Incorporated in 1982, and introduced into the US operating room market in 1983.  Prior to its introduction, a patient's oxygenation was determined by a painful arterial blood gas, a single point measure which typically took a minimum of 20-30 minutes processing by a laboratory.  (In the absence of oxygenation, damage to the brain starts in 5 minutes with brain death in another 10-15 minutes).  In the US alone, approximately $2 billion was spent annually on this measurementWith the introduction of pulse oximetry, a non-invasive, continuous measure of patient's oxygenation was possible, revolutionizing the practice of anesthesia and greatly improving patient safetyPrior to its introduction, studies in anesthesia journals estimated US patient mortality as a consequence of undetected [[hypoxemia]] at 2,000 to 10,000 deaths per year, with no known estimate of patient morbidity.


By 1987, the standard of care for the administration of a general anesthetic in the US included pulse oximetryFrom the operating room, the use of pulse oximetry rapidly spread throughout the hospital, first in the recovery room, and then into the various intensive care unitsPulse oximetry was of particular value in the neonatal unit where the patients do not thrive with inadequate oxygenation, but also can be blinded with too much oxygen.  Furthermore, obtaining an arterial blood gas from a neonatal patient is extremely difficult.
==Indications==
This is useful in any setting where a patient's [[oxygenation]] is unstable, including [[intensive care]], surgery, postoperative recovery, emergency and hospital ward settings, pilots in unpressurized aircraft, and determining the effectiveness of or need for supplemental [[oxygen]].  Assessing a patient's need for [[oxygen]] is often referred to as the ultimate vital sign; human life is not feasible in the absence of [[oxygen]]Although pulse oximetry is used to monitor [[oxygen]] delivery to peripheral tissues, it cannot determine the [[metabolism]] of [[oxygen]], or the amount of [[oxygen]] actually being used by a patientFor this purpose, it is necessary to also measure [[carbon dioxide]] (CO<sub>2</sub>) levels with [[arterial blood gas]] testing.


==Limitations==
==Limitations==
This is a measure solely of oxygenation, not of [[Ventilation (physiology)|ventilation]], and is not a substitute for [[blood gases]] checked in a laboratory as it gives no indication of [[carbon dioxide]] levels, blood [[pH]], or [[sodium bicarbonate]] levels. The metabolism of oxygen can be readily measured by monitoring expired CO<sub>2</sub>.
This is a measure solely of oxygenation, not of [[Ventilation (physiology)|ventilation]], and is not a substitute for [[blood gas analysis|arterial blood gas analysis]] checked in a laboratory or by specialized sensors inserted through intravascular catheters.  Oxygenation is generally not limited by [[ventilation]].    [[Hypoxia]] detectable by pulse oximetry is a relatively late finding in [[hypoventilation]], the earlier finding being [[hypercarpia]] ([[carbon dioxide]] buildup). [[Ventilation]], as measured by the [[minute volume]], is actually more intimately intertwined with the [[carbon dioxide]] level in the blood, and this will build quickly in [[hypoventilation]] than [[hypoxemia]].  Pulse oximetry gives no indication of [[carbon dioxide]] levels, blood [[pH]], or [[sodium bicarbonate]] levels. The metabolism of [[oxygen]] can be readily calculated by monitoring expired [[CO<sub>2</sub>|carbon dioxide]].
 
Falsely low readings may be caused by [[hypoperfusion]] of the extremity being used for monitoring (often due to the part being cold or from [[vasoconstriction]] secondary to the use of vasopressor agents); incorrect sensor application; highly calloused skin; and movement (such as shivering), especially during [[hypoperfusion]].  To ensure accuracy, the sensor should return a steady pulse and/or pulse waveform.  Falsely high or falsely low readings will occur when hemoglobin is bound to something other than oxygen. In cases of [[carbon monoxide]] poisoning, the falsely high reading may delay the recognition of [[Hypoxia (medical)|hypoxemia]] (low blood oxygen level). [[Cyanide]] poisoning can also give a false high reading.
 
It should be noted that Pulse oximetry only reads the percentage of bound hemoglobin. It can be bound to other gasses such as carbon monoxide and still read high even though the patient is hypoxic.


==See also==
Immediately after [[endotracheal intubation]], a formerly [[hypoventilated]] patient may "blow off" too much [[carbon dioxide]].  The resultant [[hypocapnia]] can lead to [[metabolic alkalosis]], and this is also not assessed by pulse oximetry. [{Capnography]], however, does measure the CO<sub>2</sub>  Clearly, pulse oximetry is not a replacement for measurement of the [[partial pressure]] of [[oxygen]] and [[carbon dioxide]] afforded by an [[arterial blood gas]] test.
*[[Oxygen sensor]]
*[[Oxygen saturation]]
*[[Pulse oximeter]]


== External links ==
Falsely low readings may be caused by [[hypoperfusion]] of the extremity being used for monitoring (often due to the part being cold or from [[vasoconstriction]] secondary to the use of [[vasopressor]] agents); incorrect sensor application; highly callused skin; and movement (such as shivering), especially during [[hypoperfusion]]. To ensure accuracy, the sensor should return a steady pulse and/or pulse waveform before a measurement undertaken.
* [http://www.nonin.com Nonin Medical]
* [http://www.nellcor.com Nellcor Incorporated]
* [http://www.emant.com/694006.page Learn how an oximeter works by building an optical heart rate monitor]


[[Category:Medical tests|CZ Live]]
Falsely high or falsely low readings will occur when [[hemoglobin]] is bound to a molecule other than [[oxygen]]. In cases of [[carbon monoxide]] poisoning, the falsely high reading may delay the recognition of [[hypoxia (medical)|hypoxemia]] (low [[blood]] [[oxygen]] level). [[Cyanide]] poisoning can also give a falsely high reading.[[Category:Suggestion Bot Tag]]

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Pulse oximetry is a non-invasive method which uses colorimetric techniques to monitor the oxygenation of a patient's blood. Pulse oximeters are small units that variously can be used in field medicine, at the bedside in a hospital or home care, and in the operating room. They complement more sophisticated blood gas analysis. Particularly in anesthesia or advanced field medicine where an artificial airway is inserted, direct carbon dioxide measurement with capnography is another complementary technique.

Principle

A sensor is placed on a relatively thin part of the patient's anatomy, usually a fingertip or earlobe. In the case of a neonate, the sensor can be placed around the heel of the foot. Then, light at two wavelengths is passed through the skin, and detected by a sensor on the other side of the skin. Changes in the spectrophotometric absorbance of each of the two wavelengths is measured, allowing determination of the absorbances due to the pulsing arterial blood alone. The measurement factors out venous blood, skin, bone, muscle, fat, and even (in most cases) fingernail polish. Based upon the ratio of changing absorbances of the red and infrared light caused by the difference in color between oxygen-carrying (bright red) and non-carrying (dark red or in severe cases blue) hemoglobin in the blood, a measure of oxygen saturation (the percent of hemoglobin molecules bound with oxygen molecules) can be made.

History

Pulse Oximetry was developed by Nellcor Incorporated in 1982, and introduced into the US operating room market in 1983. Prior to its introduction, a patient's oxygenation could only be determined by an arterial blood gas, a single point measure which typically took a minimum of 20-30 minutes processing by a laboratory. (In the absence of oxygenation, damage to the brain starts in 5 minutes with brain death in another 10-15 minutes). In the US alone, approximately $2 billion was spent annually on this measurement. With the introduction of pulse oximetry, a non-invasive, continuous measure of patient's oxygenation was possible, revolutionizing the practice of anesthesia and greatly improving patient safety. Prior to its introduction, studies in anesthesia journals estimated US patient mortality as a consequence of undetected hypoxemia at 2,000 to 10,000 deaths per year, with no known estimate of patient morbidity.

By 1987, the standard of care for the administration of a general anesthetic in the US included pulse oximetry. From the operating room, the use of pulse oximetry rapidly spread throughout the hospital, first in the recovery room, and then into the various intensive care units. Pulse oximetry was of particular value in the neonatal ICU, where the patients can suffer from inadequate oxygen levels, but also can be blinded by excessive concentrations of oxygen. Furthermore, obtaining an arterial blood gas from a neonatal patient is extremely difficult.

Indications

This is useful in any setting where a patient's oxygenation is unstable, including intensive care, surgery, postoperative recovery, emergency and hospital ward settings, pilots in unpressurized aircraft, and determining the effectiveness of or need for supplemental oxygen. Assessing a patient's need for oxygen is often referred to as the ultimate vital sign; human life is not feasible in the absence of oxygen. Although pulse oximetry is used to monitor oxygen delivery to peripheral tissues, it cannot determine the metabolism of oxygen, or the amount of oxygen actually being used by a patient. For this purpose, it is necessary to also measure carbon dioxide (CO2) levels with arterial blood gas testing.

Limitations

This is a measure solely of oxygenation, not of ventilation, and is not a substitute for arterial blood gas analysis checked in a laboratory or by specialized sensors inserted through intravascular catheters. Oxygenation is generally not limited by ventilation. Hypoxia detectable by pulse oximetry is a relatively late finding in hypoventilation, the earlier finding being hypercarpia (carbon dioxide buildup). Ventilation, as measured by the minute volume, is actually more intimately intertwined with the carbon dioxide level in the blood, and this will build quickly in hypoventilation than hypoxemia. Pulse oximetry gives no indication of carbon dioxide levels, blood pH, or sodium bicarbonate levels. The metabolism of oxygen can be readily calculated by monitoring expired [[CO2|carbon dioxide]].

Immediately after endotracheal intubation, a formerly hypoventilated patient may "blow off" too much carbon dioxide. The resultant hypocapnia can lead to metabolic alkalosis, and this is also not assessed by pulse oximetry. [{Capnography]], however, does measure the CO2 Clearly, pulse oximetry is not a replacement for measurement of the partial pressure of oxygen and carbon dioxide afforded by an arterial blood gas test.

Falsely low readings may be caused by hypoperfusion of the extremity being used for monitoring (often due to the part being cold or from vasoconstriction secondary to the use of vasopressor agents); incorrect sensor application; highly callused skin; and movement (such as shivering), especially during hypoperfusion. To ensure accuracy, the sensor should return a steady pulse and/or pulse waveform before a measurement undertaken.

Falsely high or falsely low readings will occur when hemoglobin is bound to a molecule other than oxygen. In cases of carbon monoxide poisoning, the falsely high reading may delay the recognition of hypoxemia (low blood oxygen level). Cyanide poisoning can also give a falsely high reading.