Pharmacotherapy of Alcohol Dependence
Correspondence Address :
Dr. P. Ravi Shankar
Dept. Of Clinical Pharmacology
KIST Medical College
P.O. Box 14142
Kathmandu, Nepal.
E-mail: ravi.dr.shankar@gmail.com
Alcohol is a commonly used psychoactive substance all over the world and responsible for a significant proportion of mortality and morbidity. The treatment of alcohol dependence consists of two phases, detoxification and rehabilitation. Pharmacotherapy is being investigated to enhance abstinence and prevent relapse and complement interventions at a psychosocial level.
Alcohol activates dopamine in the nucleus accumbens and mediates positive reinforcement and reward. The US Food and Drug Administration (FDA) have approved three medications, disulfiram, naltrexone and acamprosate for the treatment of alcohol dependence. The selective serotonin reuptake inhibitors (SSRIs) particularly fluoxetine and citalopram have been evaluated. Buspirone and Ondansetron have also been tried for alcohol dependence.
Combination of naltrexone and acamprosate has shown promising results. It is essential to develop clinically useful pharmacological treatments, which can be evaluated using large-scale clinical trials. Clinical trial methodologies to evaluate combination treatments and using medications along with psychosocial treatments are required.
Alcohol; Dependence; Detoxification; Pharmacotherapy; Rehabilitation
Alcohol is a commonly used psychoactive substance all over the world. In Nepal, alcohol has been consumed since a long time. The substance has deep-rooted religious, cultural and traditional dimensions and social implications (1). Alcohol use is common among both genders and around 25% of respondents were found to be dependent on alcohol in a survey in a town of Eastern Nepal (2).
Brief epidemiology:
Up to 25% of accidents in the workplace and around 60% of total accidents at work may be associated with alcohol (3). Almost one third of Americans consume enough alcohol to be considered at risk for alcohol dependence and there are more than 100,000 deaths each year from alcohol related diseases and injures (4). In Australia, alcohol accounted for an estimated 3668 deaths and 95917 hospital admissions in the financial year 1996-97 (5). In Korea, a recent study had established that 10.2% of the adult population had a lifetime prevalence of alcohol dependence and this makes the condition, the second most common psychiatric disorder in Korea (6). In India, about 15-20% of people consume alcohol and the number of drinkers has increased to about one in twenty and about five million people are addicted to alcohol (7).
Alcohol dependence:
The criteria for alcohol dependence have been defined by the fourth edition of the Diagnostic and Statistical Manual of Mental disorders (8). Among the criteria are tolerance, characteristic withdrawal symptoms on stopping use, abandonment of important social, occupational or recreational activities because of alcohol ingestion and continued use of alcohol despite problems. Alcohol dependence is a chronic disorder, which results from a variety of genetic, psychosocial and environmental factors (9).
Management of alcohol dependence:
The treatment of alcohol dependence consists of two phases, detoxification and rehabilitation. The initial detoxification phase deals with the acute withdrawal symptoms while rehabilitation attempts to prevent relapse and develop long-term abstinence (10). Psychosocial treatments have been shown to be effective in reducing alcohol consumption and maintaining abstinence. However, 40 to 70% of patients relapse and start drinking within a year following treatment (11).
Pharmacotherapy is being investigated to enhance abstinence and prevent relapse and complement interventions at a psychosocial level. Recent advances in neurobiology have identified the effects of alcohol on various neurotransmitter systems and these can be targets for drugs (10). Alcohol dependence is a heterogeneous condition.
Neurobiology of alcohol dependence:
Alcohol changes the 3-dimensional structure of proteins. The ion channels, neurotransmitter receptors and enzymes involved in signal transduction are particularly sensitive (12). Dopamine, serotonin, gamma amino butyric acid (GABA), glutamic acid, adenosine, neuropeptide Y, nor-epinephrine, cannabinoid receptors and opioid peptides are affected (13).
The dopamine system plays a central role in the biology of alcoholism. Alcohol activates releases dopamine in the nucleus accumbens and mediates positive reinforcement and reward (14). Alcohol use increases release of endorphins and indirectly activates the dopaminergic reinforcement and reward system (15).
Alcohol is a depressant of the central nervous system (CNS) and potentates GABAergic inhibition. On chronic exposure, there is a compensatory up regulation of glutamatergic and down regulation of the GABA system, which can result in an increased tolerance for alcohol (16).
Medications for treating alcohol dependence:
The US Food and Drug Administration (FDA) have approved three medications, disulfiram, naltrexone and acamprosate for the treatment of alcohol dependence (4). (Table/Fig 1) shows pharmacokinetics of selected drugs used in management of alcohol dependence while (Table/Fig 2) shows dosage, adverse effects, contraindications and precautions regarding use of selected drugs for management of alcohol dependence
Aversive agents: Disulfiram
Disulfiram inhibits the enzyme aldehyde dehydrogenase (ALDH) which catalyses oxidation of acetaldehyde to acetic acid. Blood levels of acetaldehyde increases and a characteristic disulfiram-ethanol reaction (DER) is produced (17). A number of studies have been performed with disulfiram; however controlled clinical trials have failed to establish clearly the benefit of disulfiram in enhancing abstinence (18).
The usual dose is 250 mg per day and the maximum dose is 500 mg per day. On consuming alcohol while on disulfiram adverse reaction like palpitations, flushing, nausea, vomiting and headache may develop (4). Myocardial infarction, congestive cardiac failure, respiratory depression and even death can occur. The drug is contraindicated in patients on metronidazole, with psychosis or cardiovascular disease. It is also not recommended in patients with severe pulmonary disease, chronic renal failure, diabetes, peripheral neuropathy, seizure, liver cirrhosis or more than 60 years of age. Disulfiram is converted to 5-ethyl N, N-diethylthiocarbamate sulphoxide (DETC-MeSO) and this metabolite is responsible for inactivating ALDH (19). A number of factors can influence the metabolism of disulfiram and other medications metabolised by the same cytochrome P-450 enzymes can inhibit disulfiram metabolism (20). DETC-MeSO is potent and its pharmaceutical characteristics may make a transdermal or a sustained release formulation feasible (17). The variability in metabolism can also be reduced. Further development of this metabolite as a drug can be considered. Disulfiram implants can improve compliance. However, the bioavailability of disulfiram following implantation is variable (18).
Serotonergic agents:
The selective serotonin reuptake inhibitors (SSRIs) particularly fluoxetine and citalopram have been most extensively evaluated (17). Naranjo and coworkers in 1990 first reported on the effects of fluoxetine on alcohol consumption in heavy drinkers (21). Fluoxetine 60 mg/day decreased average daily alcohol consumption by around 17% compared to base line. Further studies have shown conflicting results (17).
In 1987, Naranjo et al reported that citalopram 40 mg daily reduced number of drinks and increased number of abstinent days in non-depressed, early stage problem drinkers. However further studies have shown diverse results (17). The diversity of subject samples may be partly responsible for the variable effects of SSRIs.
Fluoxetine is usually started at a dose of 20 mg per day and may be increased to 60mg daily as needed. Nausea, headache and sexual dysfunction may be among the adverse effects.
Other agents acting on serotonergic receptors:
Buspirone and ondansetron have also been tried for alcohol dependence (18). Ondansetron is usually given in a dose of 4 μg per kg body weight twice daily and malaise, fatigue, headache, dizziness and anxiety are the major side effects. The therapy is however more expensive compared to other agents.
Drugs acting on the opioid receptors:
Naltrexone is an opioid receptor antagonist and has been approved for the treatment of alcohol dependence by the US FDA [10, 18]. Two small, double-blind, placebo-controlled trials had shown a reduced rate of drinking relapse, reduced craving and less frequent drinking in patients treated with naltrexone (22) (23). A systematic review of 11 trials found that naltrexone reduced short term relapse rates in alcohol dependent patients when combined with psychosocial treatments (24). However, more recent RCTs working at longer term outcomes have reported mixed results (4).
Naltrexone may act by blocking the μ opioid receptors, which reduces alcohol’s reinforcing effects. The recommended dose is 50 mg daily in a single dose (4). The drug undergoes extensive hepatic first pass metabolism to Q-naltrexol, which is a weaker antagonist but has a longer half life (25). The drug is generally well tolerated. Non-specific symptoms like headache, flu–like symptoms, nausea and anorexia have been reported (25). Naltrexone blocks the action of opioid analgesics and is contraindicated in patients on long-term opioid therapy for chronic pain or heroin dependence.
Compliance may be a limiting factor in naltrexone treatment (26). Sinclair had suggested that naltrexone is useful to prevent relapse rather than to maintain absolute abstinence (27). The most common side effects are nausea, headache, anxiety and sedation (28). Dose dependent hepatotoxicity may be a problem and the drug is contraindicated in patients with hepatitis or liver failure (10). In April 2006, the US FDA approved an extended-release (30 day) injectable suspension of naltrexone (29).
It has been suggested that patients with high level of alcohol craving are more likely to benefit from naltrexone treatment (30). Naltrexone not only blocks the opioid receptors but also indirectly increases the hypothalamo pituitary adrenal (HPA) activity and results in higher level of ACTH and cortisol (31).
Nalmefene
Nalmefene has similar properties and a similar mechanism of action to naltrexone (32). A RCT had used nalmefene in dosage of 20 or 30 mg orally daily and observed that the drug significantly reduced relapse in heavy drinking (32). Out side of research studies, the drug is available only in an injectable form.
NMDA/GABA receptor modulator:
Acamprosate
Acamprosate (calcium acetyl homotaurinate) blocks the glutaminergic NMDA receptors and activates GABAA receptors and is approved by the FDA for treating alcohol dependence (4). Acamprosate has a structure similar to GABA and enhances GABA transmission by increasing the number of sites for GABA uptake (25). The drug also affects the calcium channels which increase in number as alcohol dependence develops (33).
The drug is available in 333 mg enteric-coated tablets and dosing is by weight. For an adult weighing above 60 kg the dose is six tablets orally in three divided doses along with meals (25). For adults under 60 kg the dose is four tablets daily. Only 10% of acamprosate is absorbed and 90% is excreted unchanged in urine.
The side effects are mainly confined to the gastrointestinal system and can be minimized by gradually increasing the dose. Low frequencies of rash, pruritus, paresthesiae, decreased libido and confusion have been reported (25). Transient diarrhea is the most common adverse effect and occurs in about 10% of patients.
The calcium component may inactivate tetracyclines during concurrent use. The safety of the drug in pregnancy or lactation has not been established (25). Like naltrexone and disulfiram the FDA pregnancy category is C. The drug is contraindicated in patients with renal insufficiency or advanced cirrhosis but may be safely taken by patients with liver dysfunction.
Acamprosate has been studied in over 3000 patients and evidence of the efficacy in rehabilitation of alcoholics is generally consistent (17). The drug has a prominent role to play in treating alcohol dependence. Chick and coworkers have raised the possibility that certain subgroups of alcoholics may be more responsive to treatment with acamprosate (34).
Chronic exposure to alcohol causes compensatory up regulation of the glutamatergic and down regulation of the GABA system and causes increased tolerance. Abrupt alcohol withdrawal causes a hyper excitable state. This is perceived as disagreeable by the patients. Acamprosate is an antiglutamatergic agent and reduces motivation to drink by suppressing alcohol withdrawal symptoms (10). Acamprosate may have other beneficial effects such as substituting for deficits in negative feedback signals and reducing the development of tolerance and sensitization to alcohol (35).
Lithium:
The exact mechanism of action is not known but it affects phosphoinositide signaling and enhances serotonin action in the brain (18). Garbutt and coworkers concluded that lithium lacks efficacy in treating primary alcohol dependence.
Combination of naltrexone and acamprosate:
Combining these two drugs is attractive for several reasons. The drugs have different mechanisms of action (36). Combination of two drugs would act simultaneously on two different aspects of craving and have a synergistic effect. Naltrexone reduces the quantity of ingested alcohol by decreasing the priming effect of initial intake or alcohol associated cues while acamprosate increases the probability that currently abstinent subjects remain abstinent (36).
A study observed that co administration significantly increased the rate and extent of absorption of acamprosate (37). A RCT observed that the combination was pharmacologically and behaviourally safe (38). The COMBINE study had shown good initial results (39). The study will answer important questions regarding the effectiveness of the drugs alone and in combination as well as that of psychosocial treatment. Combination treatment seems to be well tolerated and no serious adverse effects were reported. An increased incidence of diarrhoea and nausea has been seen perhaps due to a pharmacokinetic interaction.
Future perspectives:
It is essential to develop clinically useful pharmacological treatments, which can be evaluated using large-scale clinical trials. Clinical trial methodologies to evaluate combination treatments especially involving multiple medications and using medications along with psychosocial treatments are required (17). Small scale, exploratory studies to develop new candidate medications or formulations are however important. Combining medications with participations in self help groups may be a challenge (40). Factors which may predict poor compliance with treatment and appropriate efforts to remedy these will be important. The optimal duration of treatment is not well defined. The role of pharmacotherapy in efforts at secondary prevention should also be defined. Alcoholics with co morbid drug use disorders and with other disorders are not included often in drug trials. This can form a population for future studies.
Changes are taking place in the pharmacotherapy of alcoholism. Pharmacotherapy should be combined with concurrent counselling through professional or self-help programmes. Acamprosate and naltrexone are the best choices for relapse prevention. Disulfiram shows limited efficacy and may be used less frequently. SSRIs can be used in alcoholics with co morbid disorders. Topiramate and ondansetron show promise in treating alcohol dependence. The biology of addiction and dependence is being elucidated and this may lead to more effective drug treatments.
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