When doctors, nurses or paramedics need a quick estimate of a patient's oxygen levels, they use technology called CMS pulse oximeters. These little gadgets can be easily clipped onto a finger or an earlobe and indirectly measure oxygen levels by determining the percentage of hemoglobin, a respiratory pigment, that is saturated with the life-giving gas. Normal values in most people are 95 percent or more.
It isn't obvious how a non-invasive instrument can measure with any degree of accuracy something down to the molecular level. Without getting too technical, oximetry works on the principle that different substances absorb light differently. Two different wavelengths of light are passed through the patient and the instrument is able to determine the absorbance, and therefore the concentration, of oxygen in pulsating arterial blood.
While this technology can reveal the oxygen saturation of a person's hemoglobin, it is at best an indirect means of finding out how much actual oxygen is circulating in the bloodstream. To measure this directly, it is necessary to sample the blood passing through the arteries in real time. This involves placing a needle into an artery.
Jamming a needle into an artery, which are by design very thick, is very painful for the patient. Because of this, it is not routinely done unless it is really necessary. The feeling of having a needle pierce into an artery has been compared to having a sharp implement poking directly into a bone.
A pulse oximeter may also be used for research purposes, for example, during sleeping studies. These investigations are performed when a patient is suspected to have a condition called sleep apnea. People with this type of disorder are unable to breathe, sometimes for dangerously long periods, while they are sleeping. This can result in stroke, heart attack or even death. At best, it can leave people foggy headed and tired the next day.
There are two categories of sleep apnea, neurological and obstructive. Obstructive sleep apnea (OSA) is more common than neurological sleep apnea, but no less dangerous. Treatments may include a device that is prescribed by a dentist to keep the mouth partially open at night, continuous positive airway pressure (CPAP) or, in extreme cases, surgery to correct an anatomic deformity that makes the airway unable to open.
The other form of sleep apnea, central, is less common and potentially more serious than OSA. This is because the center of the brain that regulates physiological processes like heart rate and breathing, malfunctions to the point where the body won't try to breathe. Either type of apnea may occur on its own or in conjunction with the other form.
Although anyone can have any type of sleep apnea, the major risk factors are male gender over the age of 40 and being overweight. Sleep apnea is particularly dangerous in infants, who can stop breathing for as long as twenty seconds. This is a very daunting prospect for new parents. Fortunately, there are apnea alarms available that will alert the parents when a baby stops breathing for a set number of seconds. It is also possible to obtain CMS pulse oximeters for home use.
It isn't obvious how a non-invasive instrument can measure with any degree of accuracy something down to the molecular level. Without getting too technical, oximetry works on the principle that different substances absorb light differently. Two different wavelengths of light are passed through the patient and the instrument is able to determine the absorbance, and therefore the concentration, of oxygen in pulsating arterial blood.
While this technology can reveal the oxygen saturation of a person's hemoglobin, it is at best an indirect means of finding out how much actual oxygen is circulating in the bloodstream. To measure this directly, it is necessary to sample the blood passing through the arteries in real time. This involves placing a needle into an artery.
Jamming a needle into an artery, which are by design very thick, is very painful for the patient. Because of this, it is not routinely done unless it is really necessary. The feeling of having a needle pierce into an artery has been compared to having a sharp implement poking directly into a bone.
A pulse oximeter may also be used for research purposes, for example, during sleeping studies. These investigations are performed when a patient is suspected to have a condition called sleep apnea. People with this type of disorder are unable to breathe, sometimes for dangerously long periods, while they are sleeping. This can result in stroke, heart attack or even death. At best, it can leave people foggy headed and tired the next day.
There are two categories of sleep apnea, neurological and obstructive. Obstructive sleep apnea (OSA) is more common than neurological sleep apnea, but no less dangerous. Treatments may include a device that is prescribed by a dentist to keep the mouth partially open at night, continuous positive airway pressure (CPAP) or, in extreme cases, surgery to correct an anatomic deformity that makes the airway unable to open.
The other form of sleep apnea, central, is less common and potentially more serious than OSA. This is because the center of the brain that regulates physiological processes like heart rate and breathing, malfunctions to the point where the body won't try to breathe. Either type of apnea may occur on its own or in conjunction with the other form.
Although anyone can have any type of sleep apnea, the major risk factors are male gender over the age of 40 and being overweight. Sleep apnea is particularly dangerous in infants, who can stop breathing for as long as twenty seconds. This is a very daunting prospect for new parents. Fortunately, there are apnea alarms available that will alert the parents when a baby stops breathing for a set number of seconds. It is also possible to obtain CMS pulse oximeters for home use.
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