Hypoxia (also known as Hypoxiation
or Anoxemia) is a condition in which the body or a region of the body is
deprived of adequate oxygen supply. Hypoxia may be classified as either generalized,
affecting the whole body, or local, affecting a region of the body.
Although hypoxia is often a pathological condition, variations in arterial oxygen
concentrations can be part of the normal physiology, for example, during hypoventilation training or strenuous
physical exercise.
Hypoxia differs from hypoxemia in
that hypoxia refers to a state in which oxygen supply is insufficient, whereas hypoxemia
refers specifically to states that have low arterial oxygen supply. Hypoxia in
which there is complete deprivation of oxygen supply is referred to as
"anoxia".
Generalized hypoxia occurs in
healthy people when they ascend to high
altitude, where it causes altitude
sickness leading to potentially fatal complications: high altitude pulmonary edema (HAPE) and high altitude cerebral edema (HACE). Hypoxia also
occurs in healthy individuals when breathing mixtures of gasses with a low
oxygen content, e.g. while diving underwater especially when using closed-circuit
rebreather
systems that control the amount of oxygen in the supplied air. A mild and
non-damaging intermittent hypoxia is used intentionally during altitude
trainings to develop an athletic performance adaptation at both the
systemic and cellular level.
Hypoxia is also a serious
consequence of preterm birth in the neonate. The main cause for this
is that the lungs of the human fetus are among the last organs to develop
during pregnancy. To assist the lungs to distribute oxygenated blood throughout
the body, infants at risk of hypoxia are often placed inside an incubator
capable of providing continuous positive airway pressure
(also known as a humidicrib).
Signs and symptoms
Generalised hypoxia
The symptoms of generalized
hypoxia depend on its severity and acceleration of onset.
In the case of altitude
sickness, where hypoxia develops gradually, the symptoms include
light-headedness / fatigue, numbness / tingling of extremities, nausea and
anorexia. In severe hypoxia, or hypoxia of very rapid onset, ataxia, confusion /
disorientation / hallucinations / behavioral change, severe headaches / reduced
level of consciousness, papilloedema, breathlessness,
pallor,tachycardia
and pulmonary hypertension eventually leading to
the late signs cyanosis,
bradycardia
/ cor
pulmonale and hypotension followed by death.
Because haemoglobin
is a darker red when it is not bound to oxygen (deoxyhaemoglobin),
as opposed to the rich red color that it has when bound to oxygen (oxyhaemoglobin),
when seen through the skin it has an increased tendency to reflect blue light
back to the eye. In cases where the oxygen is displaced by another molecule,
such as carbon monoxide, the skin may appear 'cherry red' instead of cyanotic.
Local hypoxia
If a tissue is not being perfused
properly, it may feel cold and appear pale; if severe, hypoxia can result in cyanosis, a
blue discoloration of the skin. If hypoxia is very severe, a tissue may
eventually gangrene.
Extreme pain may also be felt at
or around the site.
Cause
Oxygen passively diffuses in the
lung alveoli
according to a pressure gradient. Oxygen diffuses from the breathed air, mixed
with water vapour, to arterial blood, where its partial pressure is around
100 mmHg (13.3 kPa). In the blood, oxygen is bound to hemoglobin, a
protein in red blood cells. The binding capacity of hemoglobin
is influenced by the partial pressure of oxygen in the
environment, as described in the oxygen–hemoglobin dissociation
curve. A smaller amount of oxygen is transported in solution in the blood.
In peripheral tissues, oxygen
again diffuses down a pressure gradient into cells and their mitochondria,
where it is used to produce energy in conjunction with the
breakdown of glucose,
fats and some amino acids.
Hypoxia can result from a failure at
any stage in the delivery of oxygen to cells. This can include decreased
partial pressures of oxygen, problems with diffusion of oxygen in the lungs,
insufficient available hemoglobin, problems with blood flow to the end tissue,
and problems with breathing rhythm.
Experimentally, oxygen diffusion
becomes rate limiting (and lethal) when arterial oxygen partial pressure falls
to 40 mmHg (5.3 kPa) or below.
Ischemia
Ischemia,
meaning insufficient blood flow to a tissue, can also result in hypoxia. This
is called 'ischemic hypoxia'. This can include an embolic event, a heart attack that decreases overall blood
flow, or trauma to a tissue that results in damage. An example of insufficient
blood flow causing local hypoxia is gangrene that
occurs in diabetes.
Diseases such as peripheral vascular disease can also
result in local hypoxia. For this reason, symptoms are worse when a limb is
used. Pain may also be felt as a result of lactic acid
created as a result of anaerobic metabolism.
Hypoxemic hypoxia
This refers specifically to
hypoxic states where the arterial content of oxygen is insufficient. This can
be caused by alterations in respiratory
drive, such as in respiratory alkalosis, physiological or
pathological shunting of blood, diseases interfering in lung function resulting
in a ventilation-perfusion mismatch, such
as a pulmonary embolus, or alterations in the partial
pressure of oxygen in the environment or lung alveoli, such as may occur at
altitude or when diving.
Problems with hemoglobin
Almost all the oxygen in the blood
is bound to hemoglobin, so interfering with this carrier molecule limits oxygen
delivery to the periphery. Hemoglobin increases the oxygen-carrying capacity of
blood by about 40-fold,[14]
with the ability of hemoglobin to carry oxygen influenced by the partial
pressure of oxygen in the environment, a relationship described in the oxygen–hemoglobin dissociation
curve. When the ability of hemoglobin to carry oxygen is interfered with, a
hypoxic state can result.
Anemia
Hemoglobin plays a substantial
role in carrying oxygen throughout the body, and when it is deficient, anemia can result,
causing 'anaemic hypoxia' if tissue perfusion is
decreased. Iron deficiency is the most common cause of anemia.
As iron is used in the synthesis of hemoglobin, less hemoglobin will be
synthesised when there is less iron, due to insufficient intake, or poor
absorption.
Anemia is typically a chronic
process that is compensated over time by increased levels of red
blood cells via upregulated erythropoetin.
A chronic hypoxic state can result from a poorly compensated anaemia.
Carbon monoxide poisoning
Carbon
monoxide competes with oxygen for binding sites on hemoglobin molecules. As
carbon monoxide binds with hemoglobin hundreds of times tighter than oxygen, it
can prevent the carriage of oxygen. Carbon
monoxide poisoning can occur acutely, as with smoke intoxication, or over a
period of time, as with cigarette smoking. Due to physiological processes,
carbon monoxide is maintained at a resting level of 4-6 ppm. This is increased
in urban areas (7 - 13 ppm) and in smokers (20 - 40 ppm). A carbon monoxide
level of 40 ppm is equivalent to a reduction in hemoglobin levels of 10 g/L.
CO has a second toxic effect,
namely removing the allosteric shift of the oxygen dissociation curve and
shifting the foot of the curve to the left. In so doing, the hemoglobin is less
likely to release its oxygens at the peripheral tissues. Certain abnormal hemoglobin variants also have higher than
normal affinity for oxygen, and so are also poor at delivering oxygen to the
periphery.
Cyanide poisoning
Histotoxic hypoxia results when
the quantity of oxygen reaching the cells is normal, but the cells are unable
to use the oxygen effectively, due to disabled oxidative phosphorylation
enzymes. This may occur in Cyanide
poisoning.
Other
Hemoglobin's function can also be
lost by chemically oxidizing its iron atom to its ferric form. This form of
inactive hemoglobin is called methemoglobin
and can be made by ingesting sodium nitrite as well as certain drugs and other
chemicals.
Physiological compensation
Acute
If oxygen delivery to cells is
insufficient for the demand (hypoxia), hydrogen will be shifted to pyruvic
acid converting it to lactic acid. This temporary measure (anaerobic
metabolism) allows small amounts of energy to be released. Lactic acid build up
(in tissues and blood) is a sign of inadequate mitochondrial oxygenation, which
may be due to hypoxemia, poor blood flow (e.g., shock) or a combination of
both. If severe or prolonged it could lead to cell death.
In humans, hypoxia is detected by
chemoreceptors in the carotid body. This response does not control
ventilation rate at normal pO
2, but below normal the activity of neurons innervating these receptors increases dramatically, so much so to override the signals from central chemoreceptors in the hypothalamus, increasing pO
2 despite a falling pCO
2
2, but below normal the activity of neurons innervating these receptors increases dramatically, so much so to override the signals from central chemoreceptors in the hypothalamus, increasing pO
2 despite a falling pCO
2
In most tissues of the body, the
response to hypoxia is vasodilation. By widening the blood vessels, the tissue
allows greater perfusion.
By contrast, in the lungs, the response
to hypoxia is vasoconstriction. This is known as "Hypoxic pulmonary vasoconstriction",
or "HPV".
Chronic
When the pulmonary capillary
pressure remains elevated chronically (for at least 2 weeks), the lungs become
even more resistant to pulmonary edema because the lymph vessels expand
greatly, increasing their capability of carrying fluid away from the
interstitial spaces perhaps as much as 10-fold. Therefore, in patients with
chronic mitral stenosis, pulmonary capillary pressures of 40 to 45 mm Hg have
been measured without the development of lethal pulmonary edema.[Guytun and
Hall physiology]
Hypoxia exists when there is a
reduced amount of oxygen in the tissues of the body. Hypoxemia refers to a
reduction in PO2 below the normal range, regardless of whether gas exchange is
impaired in the lung, CaO2 is adequate, or tissue hypoxia exists. There are
several potential physiologic mechanisms for hypoxemia, but in patients with
COPD the predominant one is V/Q mismatching, with or without alveolar
hypoventilation, as indicated by PaCO2. Hypoxemia caused by V/Q mismatching as
seen in COPD is relatively easy to correct, so that only comparatively small
amounts of supplemental oxygen (less than 3 L/min for the majority of patients)
are required for LTOT. Although hypoxemia normally stimulates ventilation and
produces dyspnea, these phenomena and the other symptoms and signs of hypoxia
are sufficiently variable in patients with COPD as to be of limited value in
patient assessment. Chronic alveolar hypoxia is the main factor leading to
development of cor pulmonale--right ventricular hypertrophy with or without
overt right ventricular failure--in patients with COPD. Pulmonary hypertension
adversely affects survival in COPD, to an extent that parallels the degree to
which resting mean pulmonary artery pressure is elevated. Although the severity
of airflow obstruction as measured by FEV1 is the best correlate with overall
prognosis in patients with COPD, chronic hypoxemia increases mortality and
morbidity for any severity of disease. Large-scale studies of LTOT in patients
with COPD have demonstrated a dose-response relationship between daily hours of
oxygen use and survival. There is reason to believe that continuous,
24-hours-per-day oxygen use in appropriately selected patients would produce a
survival benefit even greater than that shown in the NOTT and MRC studies.
Treatment
To counter the effects of
high-altitude diseases, the body must return arterial pO
2 toward normal. Acclimatization, the means by which the body adapts to higher altitudes, only partially restores pO
2 to standard levels. Hyperventilation, the body’s most common response to high-altitude conditions, increases alveolar pO
2 by raising the depth and rate of breathing. However, while pO
2 does improve with hyperventilation, it does not return to normal. Studies of miners and astronomers working at 3000 meters and above show improved alveolar pO
2 with full acclimatization, yet the pO
2 level remains equal to or even below the threshold for continuous oxygen therapy for patients with chronic obstructive pulmonary disease (COPD). In addition, there are complications involved with acclimatization. Polycythemia, in which the body increases the number of red blood cells in circulation, thickens the blood, raising the danger that the heart can’t pump it.
2 toward normal. Acclimatization, the means by which the body adapts to higher altitudes, only partially restores pO
2 to standard levels. Hyperventilation, the body’s most common response to high-altitude conditions, increases alveolar pO
2 by raising the depth and rate of breathing. However, while pO
2 does improve with hyperventilation, it does not return to normal. Studies of miners and astronomers working at 3000 meters and above show improved alveolar pO
2 with full acclimatization, yet the pO
2 level remains equal to or even below the threshold for continuous oxygen therapy for patients with chronic obstructive pulmonary disease (COPD). In addition, there are complications involved with acclimatization. Polycythemia, in which the body increases the number of red blood cells in circulation, thickens the blood, raising the danger that the heart can’t pump it.
In high-altitude conditions, only
oxygen enrichment can counteract the effects of hypoxia. By increasing the
concentration of oxygen in the air, the effects of lower barometric pressure
are countered and the level of arterial pO
2 is restored toward normal capacity. A small amount of supplemental oxygen reduces the equivalent altitude in climate-controlled rooms. At 4000 m, raising the oxygen concentration level by 5 percent via an oxygen concentrator and an existing ventilation system provides an altitude equivalent of 3000 m, which is much more tolerable for the increasing number of low-landers who work in high altitude.[23] In a study of astronomers working in Chile at 5050 m, oxygen concentrators increased the level of oxygen concentration by almost 30 percent (that is, from 21 percent to 27 percent). This resulted in increased worker productivity, less fatigue, and improved sleep.
2 is restored toward normal capacity. A small amount of supplemental oxygen reduces the equivalent altitude in climate-controlled rooms. At 4000 m, raising the oxygen concentration level by 5 percent via an oxygen concentrator and an existing ventilation system provides an altitude equivalent of 3000 m, which is much more tolerable for the increasing number of low-landers who work in high altitude.[23] In a study of astronomers working in Chile at 5050 m, oxygen concentrators increased the level of oxygen concentration by almost 30 percent (that is, from 21 percent to 27 percent). This resulted in increased worker productivity, less fatigue, and improved sleep.
Oxygen concentrators are uniquely suited for
this purpose. They require little maintenance and electricity, provide a constant
source of oxygen, and eliminate the expensive, and often dangerous, task of
transporting oxygen cylinders to remote areas. Offices and housing already have
climate-controlled rooms, in which temperature and humidity are kept at a
constant level. Oxygen can be added to this system easily and relatively
cheaply.
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