Dr. Thom is Professor of Emergency Medicine and Chief, Hyperbaric Medicine, University of Pennsylvania School of Medicine, Philadelphia, PA. Within the past 12 months, Dr. Thom reports no commercial conflicts of interest.
It's a deadly, odorless, colorless and tasteless gas we live with every day. You could be dying from it and never know something was wrong. Carbon monoxide is a by-product of the combustion from wood stoves, heaters, automobiles. It kills tens of thousands of people every year and is misdiagnosed and mistreated in thousands of others.
Much more common than most people believe, carbon monoxide poisoning occurs when carbon monoxide (CO) gas is inhaled in unventilated conditions.
Many poisonings could be prevented if people better understood the dangers of CO. Worldwide, CO may be responsible for over half of all fatal poisonings. Often it occurs from cooking or operating combustion engines indoors or leaking heating systems. It is estimated that CO poisoning is the third leading cause of unintentional deaths in the United States and that the incidence of nonfatal poisonings varies from 15,000 to 40,000 cases per year. Because misdiagnosis of CO poisoning is common, however, the real incidence is probably much higher.
Worldwide, CO may be responsible for over half of all fatal poisonings
How CO Damages the Body
When you inhale CO, it enters the bloodstream and takes the place of oxygen by binding with hemoglobin, turning this life-sustaining molecule into a killer: a compound called carboxyhemoglobin (COHb). Hemoglobin's normal role is to bind with oxygen and carry it to all parts of the body. Unfortunately CO binds to hemoglobin several hundred times more strongly than oxygen does; this means that carboxyhemoglobin tends to remain in the body for a long time, where it leads to oxygen starvation. The only way to clear it from the blood is lengthy exposure to fresh air or pure oxygen.
Even worse, because the brain regulates breathing based on the levels of carbon dioxide in the blood rather than on the amount of oxygen in the blood, a CO poisoning victim can easily lose consciousness without realizing that anything is wrong because the brain just doesn't register that oxygen levels in the blood and in the body are falling to dangerous levels.
Five basic processes occur simultaneously within the body that contribute to CO poisoning:
As described above, CO binds to hemoglobin. The resulting formation of carboxyhemoglobin (COHb) is a well understood effect of CO exposure. CO binding with hemoglobin interferes with the delivery of oxygen to bodily tissues.
- Impaired delivery and use of oxygen
- Disrupted O2-CO-Nitric Oxide balance
- Damage to blood vessels
- Damage to the nervous system
- Immune system responses during recovery
Levels of carbon monoxide in the blood can be determined by a simple blood test to measure carboxyhemoglobin. Carbon monoxide is produced naturally in the body and also functions as a neurotransmitter. Normal carboxyhemoglobin levels in an average person are less than 5%; heavy cigarette smokers may have levels as high as 9%.
Serious health problems tend to be seen when carboxyhemoglobin levels rise above 25%, and a serious risk of death with levels over 70%. Still, the relationship between carboxyhemoglobin levels and its toxic effects vary quite a bit from person to person. For this reason, carboxyhemoglobin levels tell us more about the degree of exposure than they do about how a poisoning victim will do in the short or long term.
Our bodies normally use oxygen, carbon monoxide and nitric oxide. The body makes use of all three of these gases in a fixed relationship with each other. When there are elevated levels of CO, this equilibrium is disturbed and the extra nitric oxide that often results can cause further toxic effects.
CO poisoning also causes deposits along vascular walls, causing damage to the lining of the blood vessels.
Elevations in neurotransmitters initiating nervous system activity occur in the brain during CO poisoning. This could be caused by any (or all) of the three components of CO poisoning listed above. This elevated activity can damage nerve cells and is the same sort of mechanism that is implicated in stroke, traumatic brain injury and diseases of the central nervous system (CNS) such as Lou Gehrig's Disease and amyotrophic lateral sclerosis (ALS).
Immune System Responses During Recovery
Other complications from CO poisoning can happen during treatment and recovery. The damage to blood vessels combined with the other components above damage myelin, an important protein coating neurons that helps transmit messages more quickly within the nervous system and brain. The damage to brain tissues arouses the immune system, which responds by causing brain inflammation, and which, in turn, causes brain damage. This kind of brain damage usually happens during the recovery period, causing memory and learning problems and movement disorders, and may not become apparent until days or weeks after the poisoning incident.
What to Look For: Signs and Symptoms
If you know what to look for, you can see early symptoms of CO poisoning. Headache, nausea and dizziness are early signs. Because these symptoms are shared by so many common conditions, the diagnosis and identification of CO poisoning is often overlooked by victims, who may take a pain killer rather than opening windows or going out into the fresh air. A tip-off that the headache you are having is related to CO exposure is that it subsides when you go outside. Often these headaches occur in the morning when people wake up from a night of sleeping in an over-insulated home (which has little fresh air) with woodstove or heater produced CO pollution. Victims commonly have increased heart rates and rapid breathing; blood pressure is variable. In some cases, heart attack and even cardiac arrest can occur.A rare symptom is red coloration and skin blisters, particularly when victims have been laying comatose for a period of time.
Testing for CO Poisoning
Doctors typically measure the patient's levels of carboxyhemoglobin (COHb) to confirm the diagnosis of CO exposure.
EKGs and plasma screens are also done, both because of the risk of circulatory system damage from CO and in light of the fact that those who suffer an acute cardiac injury from CO poisoning have an increased risk for cardiovascular-related death in the following 10 years. A chest X-ray also should be part of the ER evaluation, especially in cases of smoke inhalation.
Some studies have reported a correlation between blood COHb levels and symptoms of headache and dizziness among victims with relatively low COHb levels on the order of 2 to 10%. Unfortunately, no reliable correlation exists between COHb level and more severe symptoms. The lack of objective measures for establishing the severity of CO poisoning complicates diagnosis and treatment. While there is evidence showing brain abnormalities following CO poisoning, unless there is evidence of an intracranial bleed, neuroimaging is not likely to help with evaluation of the CO poisoning victim.
A tip-off that the headache you are having is related to CO exposure is that it subsides when you go outside.
Treating CO Poisoning
The first step in treating someone who is suffering from CO poisoning is to clear the victim's airway, get them breathing and give the person pure oxygen. Oxygen supplementation is the cornerstone of treatment for CO poisoning. Oxygen inhalation will hasten the separation of CO from hemoglobin, as well as bring vital oxygen to starving bodily tissues. There is a consensus among research studies that the average amount of time it takes a victim to rid their body of COHb while breathing air is around 320 minutes (5.5 hours), but measured times in individuals vary from 128 to 409 minutes. In victims breathing 100% high-flow oxygen through a mask, the average time is approximately two hours — 113 minutes, with individual times ranging from 27 to 464 minutes.
Hyperbaric oxygen therapy (HBOT) is the only treatment shown to improve outcome in severe CO poisoning. There are several mechanisms of action. It will speed up the replacement of COHb by oxygen. The time it takes to get rid of excess COHb decreases to approximately 23 minutes when breathing pure oxygen in a hyperbaric chamber. However, animal studies indicate that the benefits of HBOT are probably not based on quicker "flushing out" of COHb.
Even without oxygen treatment, HBOT alone has been proven to counteract several of the damaging effects of CO poisoning. For example, animals poisoned with CO and treated with HBOT alone have been found to have more rapid cardiovascular recovery, lower mortality and lower chances of long-term immune-related neurological problems.
CO poisoning is only partly the result of oxygen starvation from the binding of CO and hemoglobin. CO has several other damaging effects on the body, and these other effects are even more important than oxygen deprivation because they cause most of the long-term health problems suffered by CO poisoning victims. CO threatens life by causing heart failure. Neurological injuries arise from an interplay of oxygen deprivation, vascular damage, and neurological injuries.
The autoimmune events that evolve in the days and weeks following CO poisoning can be avoided by prompt intervention. There are a number of theoretical treatments that might benefit CO victims, but the only treatment known to be safe and effective right now is hyperbaric oxygen. It is also clear that the best intervention is education, in order to prevent CO poisoning before it occurs.