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| Cocaine dependence Classification and external resources |
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| ICD-10 | F14..2 |
|---|---|
| ICD-9 | 304.2 |
| eMedicine | med/3116 |
| MeSH | D019970 |
Cocaine dependence (or addiction) is physical and psychological dependency on the regular use of cocaine. It can result in severe physiological damage, psychosis, schizophrenia, lethargy, depression, or a potentially fatal overdose.
Contents |
Presentation
The immediate craving of the addict for more soon after use is due to the short-lived high that usually subsides within an hour, leading to prolonged, multi-dose binge use. When administration stops after binge use, it is followed by a "crash" (also known as a "come down"), the onset of severely dysphoric mood with escalating exhaustion until sleep is achieved, which is sometimes accomplished by taking sleeping medications, or sedatives, a popular one being Seroquel, or by combination use of alcohol and cannabis. Resumption of use may occur upon awakening or may not occur for several days, but the intense euphoria of such use can, as it has in many users, produce intense craving and develop rather quickly into addiction. The risk[1] of becoming cocaine-dependent within 2 years of first use (recent-onset) is 5-6%; after 10 years, it's 15-16%. These are the aggregate rates for all types of use considered, i.e., smoking, snorting, injecting. Among recent-onset users, the relative rates are higher for smoking (3.4 times) and much higher for injecting. They also vary, based on other characteristics, such as gender: among recent-onset users, females are 3.3 times more likely to become addicted, compared to males; age: among recent-onset users, those who started using at ages 12 or 13 were 4 times as likely to become addicted, compared to those who started between ages 18 and 20; and race: among recent-onset users, non-Hispanic Blacks are 7 times as likely to become addicted, compared to non-Hispanic Whites. Many habitual abusers develop a transient manic-like condition similar to amphetamine psychosis and schizophrenia, whose symptoms include aggression, severe paranoia, and tactile hallucinations (including the feeling of insects under the skin, or "coke bugs") during binges.[2]
Cocaine has positive reinforcement effects, which refers to the effect that certain stimuli have on behavior. Good feelings become associated with the drug, causing a frequent user to take the drug as a response to bad news or mild depression. This activation strengthens the response that was just made. If the drug was taken by a fast acting route such as injection or inhalation, the response will be the act of taking more cocaine, so the response will be reinforced. Powder cocaine, being a club drug, is mostly consumed in the evening and night hours. Because cocaine is a stimulant, a user will often drink large amounts of alcohol during and after usage or smoke cannabis to dull "crash" or "come down" effects and hasten slumber. Benzodiazepines (e.g., Restoril, Rohypnol Xanax, Klonopin) are also used for this purpose. Other drugs such as heroin and various pharmaceuticals are often used to amplify reinforcement or to minimize such negative effects, further increasing addiction potential and harmfulness.
Case Study in Rhesus Monkeys[3]
One study showed that rhesus monkeys, provided with a mechanism of cocaine self-administration, prefer the drug over food that is in the cage. This happens even when the monkeys are starving. Female monkeys with offspring will abandon their young upon being introduced to cocaine, and in a few cases, mothers killed their offspring. In all cases, a monkey aggressively protected the apparatus which delivered the cocaine, and in most cases, fights to the death between monkeys occurred to secure access to cocaine. The monkeys who self-administered cocaine, did virtually nothing else. Complete disregard for food, sex, sleep, water, hygiene, offspring, and life in general was always the case for those monkeys addicted to cocaine. Monkeys that were provided with a mechanism of heroin self-administration also self-administered it indefinitely, but when starved, the monkeys on heroin chose food and water over heroin without hesitation, unlike those monkeys on cocaine who consistently chose the cocaine over food, despite the fact that some were near death by starvation. Some monkeys which were deprived of water and then given the choice of cocaine or water, chose cocaine without hesitation. Those on heroin also continued to care for, and be protective of their offspring, they slept, and showed that they cared about their hygiene by grooming themselves continuously. Protective or aggressive and/or violent behavior over the apparatus which provided the heroin was not observed, as was seen with cocaine. Unlike the monkeys put on cocaine, the monkeys that were put on heroin were easier to manage and deal with. Only a very small number of monkeys became irritable and aggressive upon removing the apparatus which delivered the heroin. Within the cocaine group, all monkeys became enraged and violent upon the removal of the apparatus which provided them with the cocaine. Several monkeys tried to break free of their cages, others became psychotic, bouncing around in their cages, shrieking loudly, and some even began to bite pieces of their arms and legs. One monkey cried for several hours, while at the same time mutilating his arms. No other major drug of abuse has shown a capacity to produce an addiction as extreme as has cocaine.
Mechanism of Dependence
It is speculated that cocaine's intense addictive properties stem partially from its DAT-blocking effects (in particular, increasing the dopaminergic transmission from ventral tegmental area neurons). However, a study has shown that mice with no dopamine transporters still exhibit the rewarding effects of cocaine administration.[4] Later work demonstrated that a combined DAT/SERT knockout eliminated the rewarding effects.[5] The rewarding effects of cocaine are influenced by circadian rhythms,[6] possibly by involving a set of genes termed "clock genes".[7]
However, chronic cocaine addiction is not solely due to cocaine reward. Chronic repeated use is needed to produce cocaine-induced changes in brain reward centers and consequent chronic dysphoria (described above under Effects and Health Issues - Chronic). Dysphoria magnifies craving for cocaine because cocaine reward rapidly, albeit transiently, improves mood. This contributes to continued use and a self-perpetuating, worsening condition, since those addicted usually cannot appreciate that long-term effects are opposite those occurring immediately after use.
Treatment
Cognitive Behavioral Therapy (CBT) combined with Motivational Therapy (MT) proven to be effective to treat drug and alcohol addictions. Cocaine vaccines are on trial that will stop desirable effects from the drug."Baylor Doctors are Working on Cocaine Vaccine". CocaineHelp.org (January 17, 2008). Retrieved on 2008-09-11. The National Institutes of Health of US, particularly National Institute on Drug Abuse (NIDA) is researching modafinil, a narcolepsy drug and mild stimulant, as a potential cocaine treatment. Twelve-step programs such as Cocaine Anonymous (modeled on Alcoholics Anonymous) are claimed by participants to be helpful in achieving long-term abstinence; however, the 12 step based programs have no statistically-measurable effect and does not release any quantifiable measure of its success rates. Cocaine addiction continues to be the most difficult to manage, and according to some scientists, addiction to cocaine may be almost impossible to stop. Relapse rates among cocaine users is in the range of 94-99%, the highest among all common drugs of abuse.[7]
A study published in May, 2008, in the journal Molecular Psychiatry, detailed the effect of long-term cocaine intake on the amount and activity of thousands of proteins in monkeys. The researchers used “proteomic” technology, which enables the simultaneous analysis of thousands of proteins, to compare the “proteome” (all proteins expressed at a given time) between a group of monkeys that self-administered cocaine and a group that did not receive the drug. The study provides a comprehensive assessment of biochemical changes occurring in the cocaine-addicted brain. The profound changes in structure, metabolism and signaling of neurons may explain why relapse occurs and why it is difficult to reverse these changes after the drug use is discontinued. [8]
Side effects may include anxiety, panic attacks, sleeplessness, delusional thinking which mirrors paranoid schizophrenia, visual hallucinations including snowlights (bright spots of lights which delude the user into believing their existence, or trails of light which the user views in an anxiety ridden state, or a state close to overdose), irritability, frustration, depression following comedown, depression when cocaine has been cut (composed of chemicals other than cocaine), depression when the desired high is not achieved, convoluted thinking, and a possible unpleasant feeling of disassociation with oneself (Novick, Robyne M., Cocaine and the Common User, Phelps and Duringer Weekly, 2007).
See also
- SB-277011-A - a dopamine D3 receptor antagonist, used in the study of cocaine addiction. Where cocaine reduces the threshold for brain electrical self-stimulation in rats, an indication of cocaine's rewarding effects, SB-277011-A completely reverses this effect.
References
- ^ O'Brien MS, Anthony JC (2005). “Risk of becoming cocaine dependent: epidemiological estimates for the United States, 2000–2001.”. Neuropsychopharmacology 30: 1006–1018. doi:. PMID 15785780.
- ^ Gawin. FH. (1991). “Cocaine addiction: Psychology and neurophysiology”. Science 251: 1580–1586. doi:. PMID 2011738.
- ^ Aigner TG, Balster RL (1978). “Choice behavior in rhesus monkeys: cocaine versus food”. Science Science 201: 534–535. doi:. PMID 96531.
- ^ Sora, et al. (June 23, 1998). “Cocaine reward models: Conditioned place preference can be established in dopamine- and in serotonin-transporter knockout mice”. PNAS 95 (13): 7600–7704. doi:. PMID 9636213.
- ^ Sora, et al. (April 24, 2001). “Molecular mechanisms of cocaine reward: Combined dopamine and serotonin transporter knockouts eliminate cocaine place preference”. PNAS 98 (9): 5300–5305. doi:. PMID 11320258.
- ^ Kurtuncu et al. (April 12, 2004). “Involvement of the pineal gland in diurnal cocaine reward in mice”. European Journal of Pharmacology 489 (3): 203–205. doi:.
- ^ a b Yuferov V, Butelman ER, Kreek MJ (2005). "Biological clock: biological clocks may modulate drug addiction". Eur. J. Hum. Genet. 13 (10): 1101–3. doi:. PMID 16094306.
- ^ Newswise: Research Reveals Molecular Fingerprint of Cocaine Addiction
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- This page was last modified on 11 October 2008, at 23:10.
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