National Institute on Alcohol Abuse and Alcoholism No. 27 PH 355 January 1995
Alcohol-Medication Interactions
Many medications can interact with alcohol, leading to
increased risk of illness, injury, or death. For example, it is estimated that
alcohol-medication interactions may be a factor in at least 25 percent of all
emergency room admissions (1). An unknown number of less serious interactions
may go unrecognized or unrecorded. This Alcohol Alert notes some of the
most significant alcohol-drug interactions. (Although alcohol can interact with
illicit drugs as well, the term "drugs" is used here to refer exclusively to
medications, whether prescription or nonprescription.)
How Common Are Alcohol-Drug Interactions?
More than 2,800 prescription drugs are available in the United
States, and physicians write 14 billion prescriptions annually; in addition,
approximately 2,000 medications are available without prescription (2).
Ap proximately 70 percent of the adult population consumes
alcohol at least occasionally, and 10 percent drink daily (3). About 60 percent
of men and 30 percent of women have had one or more adverse alcohol-related life
events (4). Together with the data on medication use, these statistics suggest
that some concurrent use of alcohol and medications
is inevitable.
The elderly may be especially likely to mix drugs and alcohol
and are at particular risk for the adverse consequences of such combinations.
Although persons age 65 and older constitute only 12 percent of the population,
they consume 25 to 30 percent of all prescription medications (5) . The elderly
are more likely to suffer medication side effects compared with younger persons,
and these effects tend to be more severe with advancing age (5). Among persons
age 60 or older, 10 percent of those in the community--and 40 percent of those
in nursing homes--fulfill criteria for alcohol abuse (6).
How Alcohol and Drugs Interact
To exert its desired effect, a drug generally must travel
through the bloodstream to its site of action, where it produces some change in
an organ or tissue. The drug's effects then diminish as it is processed
(metabolized) by enzymes and eliminated from the body. Alcohol behaves
similarly, traveling through the bloodstream, acting upon the brain to cause
intoxication, and finally being metabolized and eliminated, principally by the
liver. The extent to which an administered dose of a drug reaches its site of
action may be termed its availability. Alcohol can influence the
effectiveness of a drug by altering its availability. Typical alcohol-drug
interactions include the following (7): First, an acute dose of alcohol
(a single drink or several drinks over several hours) may inhibit a drug's
metabolism by competing with the drug for the same set of metabolizing enzymes.
This interaction prolongs and enhances the drug's availability, potentially
increasing the patient's risk of experiencing harmful side effects from the
drug. Second, in contrast, chronic (long-term) alcohol ingestion may
activate drug-metabolizing enzymes, thus decreasing the drug's availability and
diminishing its effects. After these enzymes have been activated, they remain so
even in the absence of alcohol, affecting the metabolism of certain drugs for
several weeks after cessation of drinking (8). Thus, a recently abstinent
chronic drinker may need higher doses of medications than those required by
nondrinkers to achieve therapeutic levels of certain drugs. Third, enzymes
activated by chronic alcohol consumption transform some drugs into toxic
chemicals that can damage the liver or other organs. Fourth, alcohol can magnify
the inhibitory effects of sedative and narcotic drugs at their sites of action
in the brain. To add to the complexity of these interactions, some drugs affect
the metabolism of alcohol, thus altering its potential for intoxication and the
adverse effects associated with alcohol consumption (7).
Some Specific Interactions
Anesthetics. Anesthetics are administered prior to
surgery to render a patient unconscious and insensitive to pain. Chronic alcohol
consumption increases the dose of propofol (Diprivan)1 required to induce loss
of consciousness (9). Chronic alcohol consumption increases the risk of liver
damage that may be caused by the anesthetic gases enflurane (Ethrane) (10) and
halothane (Fluothane) (11).
Antibiotics. Antibiotics are used to treat infectious
diseases. In combination with acute alcohol consumption, some antibiotics may
cause nausea, vomiting, headache, and possibly convulsions; among these
antibiotics are furazolidone (Furoxone), griseofulvin (Grisactin and others),
metronidazole (Flagyl), and the antimalarial quinacrine (Atabrine) (7).
Isoniazid and rifampin are used together to treat tuberculosis, a disease
especially problematic among the elderly (12) and among homeless alcoholics
(13). Acute alcohol consumption decreases the availability of isoniazid in the
bloodstream, whereas chronic alcohol use decreases the availability of rifampin.
In each case, the effectiveness of the medication may be reduced (7).
Anticoagulants. Warfarin (Coumadin) is prescribed to
retard the blood's ability to clot. Acute alcohol consumption enhances
warfarin's availability, increasing the patient's risk for life-threatening
hemorrhages (7). Chronic alcohol consumption reduces warfarin's availability,
lessening the patient's protection from the consequences of blood-clotting
disorders (7).
Antidepressants. Alcoholism and depression are
frequently associated (14), leading to a high potential for
alcohol-antidepressant interactions. Alcohol increases the sedative effect of
tricyclic antidepressants such as amitriptyline (Elavil and others), impairing
mental skills required for driving (15). Acute alcohol consumption increases the
availability of some tricyclics, potentially increasing their sedative effects
(16); chronic alcohol consumption appears to increase the availability of some
tricyclics and to decrease the availability of others (17,18). The significance
of these interactions is unclear. These chronic effects persist in recovering
alcoholics (17).
A chemical called tyramine, found in some beers and wine,
interacts with some anti-depressants, such as monoamine oxidase inhibitors, to
produce a dangerous rise in blood pressure (7). As little as one standard drink
may create a risk that this interaction will occur.
Antidiabetic medications. Oral hypoglycemic drugs are
prescribed to help lower blood sugar levels in some patients with diabetes.
Acute alcohol consumption prolongs, and chronic alcohol consumption decreases,
the availability of tolbutamide (Orinase). Alcohol also interacts with some
drugs of this class to produce symptoms of nausea and headache such as those
described for metronidazole (see "Antibiotics") (7).
Antihistamines. Drugs such as diphenhydramine (Benadryl
and others) are available without prescription to treat allergic symptoms and
insomnia. Alcohol may intensify the sedation caused by some antihistamines (15).
These drugs may cause excessive dizziness and sedation in older persons; the
effects of combining alcohol and antihistamines may therefore be especially
significant in this population (19).
Antipsychotic medications. Drugs such as chlorpromazine
(Thorazine) are used to diminish psychotic symptoms such as delusions and
hallucinations. Acute alcohol consumption increases the sedative effect of these
drugs (20), resulting in impaired coordination and potentially fatal breathing
difficulties (7). The combination of chronic alcohol ingestion and antipsychotic
drugs may result in liver damage (21).
Antiseizure medications. These drugs are prescribed
mainly to treat epilepsy. Acute alcohol consumption increases the availability
of phenytoin (Dilantin) and the risk of drug-related side effects. Chronic
drinking may decrease phenytoin availability, significantly reducing the
patient's protection against epileptic seizures, even during a period of
abstinence (8,22).
Antiulcer medications. The commonly prescribed antiulcer
medications cimetidine (Tagamet) and ranitidine (Zantac) increase the
availability of a low dose of alcohol under some circumstances (23,24). The
clinical significance of this finding is uncertain, since other studies have
questioned such interaction at higher doses of alcohol (25-27).
Cardiovascular medications. This class of drugs includes
a wide variety of medications prescribed to treat ailments of the heart and
circulatory system. Acute alcohol consumption interacts with some of these drugs
to cause dizziness or fainting upon standing up. These drugs include
nitroglycerin, used to treat angina, and reserpine, methyldopa (Aldomet),
hydralazine (Apresoline and others), and guanethidine (Ismelin and others), used
to treat high blood pressure. Chronic alcohol consumption decreases the
availability of propranolol (Inderal), used to treat high blood pressure (7),
potentially reducing its therapeutic effect.
Narcotic pain relievers. These drugs are prescribed for
moderate to severe pain. They include the opiates morphine, codeine,
propoxyphene (Darvon), and meperidine (Demerol). The combination of opiates and
alcohol enhances the sedative effect of both substances, increasing the risk of
death from overdose (28). A single dose of alcohol can increase the availability
of propoxyphene (29), potentially increasing its sedative side effects.
Nonnarcotic pain relievers. Aspirin and similar
nonprescription pain relievers are most commonly used by the elderly (5) . Some
of these drugs cause stomach bleeding and inhibit blood from clotting; alcohol
can exacerbate these effects (30). Older persons who mix alcoholic beverages
with large doses of aspirin to self-medicate for pain are therefore at
particularly high risk for episodes of gastric bleeding (19). In addition,
aspirin may increase the availability of alcohol (31), HEIGHTening the effects
of a given dose of alcohol.
Chronic alcohol ingestion activates enzymes that transform
acetaminophen (Tylenol and others) into chemicals that can cause liver damage,
even when acetaminophen is used in standard therapeutic amounts (32,33). These
effects may occur with as little as 2.6 grams of acetaminophen in persons
consuming widely varying amounts of alcohol (34).
Sedatives and hypnotics ("sleeping pills").
Benzodiazepines such as diazepam (Valium) are generally prescribed to treat
anxiety and insomnia. Because of their greater safety margin, they have largely
replaced the barbiturates, now used mostly in the emergency treatment of
convulsions (2).
Doses of benzodiazepines that are excessively sedating may
cause severe drowsiness in the presence of alcohol (35), increasing the risk of
household and automotive accidents (15,36). This may be especially true in older
people, who demonstrate an increased response to these drugs (5,19). Low doses
of flurazepam (Dalmane) interact with low doses of alcohol to impair driving
ability, even when alcohol is ingested the morning after taking Dalmane. Since
alcoholics often suffer from anxiety and insomnia, and since many of them take
morning drinks, this interaction may be dangerous (37).
The benzodiazepine lorazepam (Ativan) is being increasingly
used for its antianxiety and sedative effects. The combination of alcohol and
lorazepam may result in depressed heart and breathing functions; therefore,
lorazepam should not be administered to intoxicated patients (38).
Acute alcohol consumption increases the availability of
barbiturates, prolonging their sedative effect. Chronic alcohol consumption
decreases barbiturate availability through enzyme activation (2). In addition,
acute or chronic alcohol consumption enhances the sedative effect of
barbiturates at their site of action in the brain, sometimes leading to coma or
fatal respiratory depression (39).
Alcohol-Medication Interactions--A Commentary by
NIAAA
Director Enoch Gordis, M.D.
Individuals who drink alcoholic beverages should be
aware that simultaneous use of alcohol and medications--both prescribed and
over-the-counter--has the potential to cause problems. For example, even very
small doses of alcohol probably should not be used with antihistamines and other
medications with sedative effects. Individuals who drink larger amounts of
alcohol may run into problems when commonly used medications (e.g.,
acetaminophen) are taken at the same time or even shortly after drinking has
stopped. Elderly individuals should be especially careful of these potential
problems due to their generally greater reliance on multiple medications and
age-related changes in physiology.
1The U.S. Government does not endorse or favor any specific
commercial product (or commodity, service, or company). Trade or proprietary
names appearing in this publication are used only because they are considered
essential in the context of the studies reported herein.
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ACKNOWLEDGMENT: The National Institute on Alcohol Abuse
and Alcoholism wishes to acknowledge the valuable contributions of Charles S.
Lieber, M.D., Director, Alcohol Research Center, Bronx VAMC, and professor,
Mount Sinai School of Medicine, to the development of this Alcohol Alert.
All material contained in the Alcohol Alert is in the
public domain and may be used or reproduced without permission from NIAAA.
Citation of the source is appreciated.
Copies of the Alcohol Alert are available free of charge
from the Scientific Communications Branch, Office of Scientific Affairs, NIAAA,
Willco Building, Suite 409, 6000 Executive Boulevard, Bethesda, MD 20892-7003.
Telephone: 301-443-3860.
