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Drugs of Abuse

Drugs of Abuse. Yacoub Irshaid MD, PhD, ABCP Department of Pharmacology. Drugs of Abuse. Drugs are abused when they are used in ways that are not medically approved, because they cause strong feelings of euphoria or alter perception.

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Drugs of Abuse

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  1. Drugs of Abuse Yacoub Irshaid MD, PhD, ABCP Department of Pharmacology

  2. Drugs of Abuse • Drugs are abused when they are used in ways that are not medically approved, because they cause strong feelings of euphoria or alter perception. • Repetitive exposure induces widespread adaptive changes in the brain. As a consequence drug use may become compulsive—the hallmark of addiction.

  3. Drugs of Abuse • The older term "physical dependence" is now denoted dependence, while "psychological dependence" is more simply called addiction. • Once the abused drug is no longer available, signs of withdrawal become apparent, which definesdependence.

  4. Drugs of Abuse • Dependence is not always a correlate of drug abuse — it can also occur with many classes of nonpsychoactive drugs such as sympathomimetic vasoconstrictors and bronchodilators, and organic nitrate vasodilators.

  5. Drugs of Abuse • Addiction,on the other hand, consists of compulsive, relapsing drug use (after a successful withdrawal) despite negative consequences.

  6. Drugs of Abuse • As a general rule, all addictive drugs activate the mesolimbic dopamine system  increase in dopamine (?). Mesolimbic dopamine codes for the difference between expected and actual reward, and thus, constitutes a strong learning signal.

  7. Major connections of the mesolimbic dopamine system in the brain. Schematic diagram of brain sections illustrating that the dopamine projections originate in the ventral tegmental area and target the nucleus accumbens, prefrontal cortex, amygdala, and hippocampus. The dashed lines on the sagittal section indicate where the horizontal and coronal sections were made.

  8. Drugs of Abuse • Addictive drugs can be distinguished into 3 classes: • A first group binds to Gio-coupled receptorswhich inhibit neurons through postsynaptic hyperpolarization and presynaptic regulation of transmitter release. The action of these drugs is preferential on GABA neurons that act as local inhibitory interneurons.

  9. Drugs of Abuse 2. A second group interacts with ionotropic receptors or ion channels, and have combined effects on dopamine neurons and GABA neurons, eventually leading to enhanced release of dopamine.

  10. Drugs of Abuse 3. A third group targets monoamine transporters, which block reuptake of or stimulate nonvesicular release of dopamine, causing an accumulation of extracellular dopamine in target structures.

  11. Neuropharmacologic classification of addictive drugs by primary target (see text and Table 32-1). DA, dopamine; GABA,  -aminobutyric acid; GHB,  -hydroxybutyric acid; GPCRs, G protein-coupled receptors; THC, ∆9-tetrahydrocannabinol.

  12. Drugs of Abuse • Antidepressants that block serotonin and norepinephrine uptake, but not dopamine uptake, do not cause addiction even after prolonged use.

  13. Addiction • Is a disease of maladaptive learning. • It is characterized by a high motivation to obtain and use a drug despite negative consequences. • With time, drug use becomes compulsive ("wanting without liking") (رغبة من دون محبة). • Addicted individuals are at high risk of relapsing.

  14. Addiction • Relapse is typically triggered by one of the following three conditions: A. Re-exposure to the drug of abuse. B. Stress. C. A context that recalls prior drug use. ((أصدقاء السوء على سبيل المثال، لا الحصر

  15. Addiction • Large individual differences exist in vulnerability to addiction. Whereas one person may become “addict" after a few doses, others may be able to use a drug occasionally during their entire lives without ever having difficulty in stopping. Even when dependence is induced with chronic exposure, only a fraction of dependent users will go on to become addicted.

  16. Addiction • Heritability of addiction, as determined by comparing monozygotic with dizygotic twins, is relatively modest for cannabinoids but very high for cocaine.

  17. Nonaddictive Drugs of Abuse • Some drugs of abuse do not lead to addiction. • This occurs with substances that alter perceptionwithout causing sensations of reward and euphoria, such as the hallucinogens and the dissociative anesthetics. • These agents primarily target cortical and thalamic circuits unlike addictive drugs which primarily target the mesolimbic dopamine system.

  18. Cannabinoids • Endogenous cannabinoids that act as neurotransmitters include 2-arachidonyl glycerol (2-AG) and anandamide, both of which bind to CB1 receptors. • These very lipid-soluble compounds are released at the postsynaptic somatodendritic membrane, and diffuse through the extracellular space to bind at presynaptic CB1 receptors, where they inhibit the release of either glutamate or GABA.

  19. Disinhibition of dopamine (DA) neurons in the ventral tegmental area (VTA) through drugs that act via Gio-coupled receptors. Top: Opioids target  -opioid receptors (MORs) that in the VTA are located exclusively on  -aminobutyric acid (GABA) neurons. MORs are expressed on the presynaptic terminal of these cells and the somatodendritic compartment of the postsynaptic cells. Each compartment has distinct effectors (insets). G protein-     -mediated inhibition of voltage-gated calcium channels (VGCC) is the major mechanism in the presynaptic terminal. Conversely, in dendrites MORs activate K channels. Middle:   9-tetrahydrocannabinol (THC) and other cannabinoids mainly act through presynaptic inhibition. Bottom: Gama-hydroxybutyric acid (GHB) targets GABAB receptors, which are located on both cell types. However, GABA neurons are more sensitive to GHB than are DA neurons, leading to disinhibition at concentrations typically obtained with recreational use. CB1R, cannabinoid receptors.

  20. Cannabinoids • Because of such backward signaling, endocannabinoids are called retrograde messengers. • In the hippocampus, release of endocannabinoids from pyramidal neurons selectively affects inhibitory transmission, and may contribute to the induction of synaptic plasticity during learning and memory formation.

  21. Cannabinoids • Exogenous cannabinoids (in marijuana), comprise several pharmacologically active substances including Δ9-tetrahydrocannabinol (THC), a powerful psychoactive substance. • THC causes disinhibition of dopamine neurons, mainly by presynaptic inhibition of GABA neurons in the ventral tegmental area (VTA).

  22. Cannabinoids • The half-life of THC is about 4 hours. • The onset of effects of THC after smoking marijuana occurs within minutes and reaches a maximum after 1–2 hours. • The most prominent effects are euphoria and relaxation. • Users also report feelings of well-being, grandiosity, and altered perception of passage of time.

  23. Cannabinoids • Dose-dependent perceptual changes (visual distortions), drowsiness, diminished coordination, and memory impairment may occur. • Cannabinoids can also create a dysphoric state and in rare cases, following the use of very high doses, may result in visual hallucinations, depersonalization, and frank psychotic episodes.

  24. Cannabinoids • Additional effects of THC include: increased appetite, attenuation of nausea, decreased intraocular pressure, and relief of chronic pain, have led to the use of cannabinoids in medical therapeutics. • Chronic exposure to marijuana leads to dependence, which is revealed by a distinctive, but mild and short-lived, withdrawal syndrome that includes:

  25. Cannabinoids Restlessness, irritability, mild agitation, insomnia, nausea, and cramping. • Synthetic agents include Δ9-THC analogs dronabinol and nabilone.

  26. LSD, Mescaline, and Psilocybin • They are commonly called hallucinogens because of their ability to alter consciousness such that the individual senses things that are not present. • They induce, often in an unpredictable way, perceptual symptoms, including shape and color distortion. Psychosis-like manifestations (depersonalization, hallucinations, distorted time

  27. LSD, Mescaline, and Psilocybin perception) have led some to classify these drugs as psychotomimetics. • They also produce somatic symptoms (dizziness, nausea, paresthesias, and blurred vision). • Some users have reported intense reexperiencing of perceptual effects (flashbacks) up to several years after the last drug exposure.

  28. LSD, Mescaline, and Psilocybin • They induce neither dependence nor addiction. • However repetitive exposure still leads to rapid tolerance. • These drugs also fail to stimulate dopamine release, further supporting the idea that only drugs that activate the mesolimbic dopamine system are addictive.

  29. LSD, Mescaline, and Psilocybin • Instead, hallucinogens increase glutamate release in the cortex, presumably by enhancing excitatory afferent input from the thalamus. • The molecular target of hallucinogens is the 5-HT2A receptor. This receptor couples to G proteins of the Gq type and generates inositol trisphosphate (IP3), leading to a release of intracellular calcium.

  30. Nicotine • Its addiction exceeds all other forms of addiction, touching more than 50% of all adults in some countries. • Nicotine withdrawal is mild, and involves irritability and sleeplessness. However, nicotine is among the most addictive drugs and relapse after attempted cessation is very common. • Treatment for nicotine addiction includes: • Substitution of nicotine. • The antidepressant bupropion. Both combined with behavioral therapies.

  31. Alcohol (Ethanol) • The pharmacology of alcohol is complex and no single receptor mediates all of its effects. • On the contrary, alcohol alters the function of several receptors and cellular functions, including GABAA receptors, Kir3/GIRK channels (G protein regulated inward rectifying potassium channels), adenosine reuptake (through the equilibrative nucleoside transporter, ENT1), glycine receptor, NMDA receptor, and 5-HT3 receptor. They are all, with the exception of ENT1, either ionotropic receptors or ion channels.

  32. Alcohol (Ethanol) • It is not clear which of these targets is responsible for the increase of dopamine release from the mesolimbic reward system. • Dependence becomes apparent 6–12 hours after cessation of heavy drinking. • Withdrawal syndrome include tremor (mainly of the hands), nausea and vomiting, excessive sweating, agitation, and anxiety.

  33. Alcohol (Ethanol) • In some individuals this is followed by visual, tactile, and auditory hallucinations 12–24 hours after cessation. • Generalized seizures may manifest after 24–48 hours. • Finally, 48–72 hours after cessation, an alcohol withdrawal delirium (delirium tremens) may become apparent in which the person hallucinates, is disoriented, and shows evidence of autonomic instability. • Delirium tremens is associated with 5–15% mortality.

  34. Alcohol (Ethanol) • Treatment of ethanol withdrawal is supportive and relies on benzodiazepines, taking care to use compounds such as oxazepam and lorazepam, which are not as dependent on hepatic metabolism as most other benzodiazepines. • Psychosocial approaches is perhaps even more important for the alcoholic patient because of the presence of alcohol in many social contexts.

  35. Alcohol (Ethanol) • Naltrexone, an antagonist and partial agonist of the opioid receptor, may decrease the craving for alcohol, resulting in fewer relapses. • Topiramate facilitates GABA function and antagonizes glutamate receptors (presumably the AMPA type), and may decrease mesocorticolimbic dopamine release after alcohol and reduce cravings.

  36. Phencyclidine (PCP) & Ketamine • Ketamine and PCP were developed as general anesthetics. • They owe their effects to their use-dependent, noncompetitive antagonism of the NMDA receptor. • They are sold as a liquids, capsules, or pills, which can be snorted, ingested, injected, or smoked.

  37. Phencyclidine (PCP) & Ketamine • Psychedelic effects last for about 1 hour and also include increased blood pressure, impaired memory function, and visual alterations. • At high doses unpleasant out-of-body and near-death experiences have been reported. • Although ketamine and phencyclidine do not cause dependence and addiction, chronic exposure, particularly to PCP, may lead to long-lasting psychosis closely resembling schizophrenia, which may persist beyond drug exposure.

  38. Cocaine • The prevalence of cocaine abuse has increased greatly over the past decade and now represents a major public health problem worldwide. • Cocaine is highly addictive, and its use is associated with a number of complications. • Cocaine is an alkaloid found in the leaves of Erythroxylon coca, a shrub indigenous to the Andes.

  39. Cocaine • Can be injectedor inhaled. • In the peripheral nervous system, cocaine inhibits voltage-gated sodium channels, thus blocking initiation and conduction of action potentials. • This effect is not responsible for the acute rewarding or the addictive effects.

  40. Cocaine • In the central nervous system, cocaine blocks the uptake of dopamine, noradrenaline, and serotonin through their respective transporters. • The block of the dopamine transporter (DAT), by increasing dopamine concentrations in the nucleus accumbens, has been implicated in the rewarding effects of cocaine.

  41. Mechanism of action of cocaine and amphetamine on synaptic terminal of dopamine (DA) neurons. Left: Cocaine inhibits the dopamine transporter (DAT), decreasing DA clearance from the synaptic cleft and causing an increase in extracellular DA concentration. Right: Since amphetamine (Amph) is a substrate of the DAT, it competitively inhibits DA transport. In addition, once in the cell, amphetamine interferes with the vesicular monoamine transporter (VMAT) and impedes the filling of synaptic vesicles. As a consequence, vesicles are depleted and cytoplasmic DA increases. This leads to a reversal of DAT direction, strongly increasing nonvesicular release of DA, and further increasing extracellular DA concentrations.

  42. Cocaine • The activation of the sympathetic nervous system results mainly from the block of the norepinephrine transporter (NET) and leads to an acute increase in arterial pressure, tachycardia, and often, ventricular arrhythmias. • Subjects typically lose appetite, are hyperactive, and sleep little. • Cocaine exposure increases the risk for intracranial hemorrhage, ischemic stroke, myocardial infarction, and generalized or partial seizures.

  43. Cocaine • Cocaine overdose may lead to hyperthermia, coma, and death. • Susceptible individuals may become dependent and addicted after only a few exposures to cocaine. • Although a withdrawal syndrome is reported, it is not as strong. • Tolerance may develop, but in some users a reverse tolerance is observed; that is, they become sensitized to small doses of cocaine.

  44. Cocaine • This behavioral sensitization is in part context-dependent. • Cravings are very strong and underline the very high addiction liability of cocaine. • To date, no specific antagonist is available.

  45. Amphetamines • Amphetamines are a group of synthetic, indirect-acting sympathomimetic drugs that cause the release of endogenous biogenic amines, such as dopamine. serotonin and norepinephrine. • Amphetamine, methamphetamine, and their many derivatives exert their effects by reversing the action of biogenic amine transporters at the plasma membrane.

  46. Amphetamines • Amphetamines are substrates of these transporters and are taken up into the cell. • Once in the cell, amphetamines interfere with the vesicular monoamine transporter (VMAT), depleting synaptic vesicles of their neurotransmitter content.

  47. Amphetamines • As a consequence, levels of dopamine (or other transmitter amine) in the cytoplasm increase and quickly become sufficient to cause release into the synapse by reversal of the plasma membrane DAT. • Normal vesicular release of dopamine consequently decreases, while nonvesicular release increases.

  48. Mechanism of action of cocaine and amphetamine on synaptic terminal of dopamine (DA) neurons. Left: Cocaine inhibits the dopamine transporter (DAT), decreasing DA clearance from the synaptic cleft and causing an increase in extracellular DA concentration. Right: Since amphetamine (Amph) is a substrate of the DAT, it competitively inhibits DA transport. In addition, once in the cell, amphetamine interferes with the vesicular monoamine transporter (VMAT) and impedes the filling of synaptic vesicles. As a consequence, vesicles are depleted and cytoplasmic DA increases. This leads to a reversal of DAT direction, strongly increasing nonvesicular release of DA, and further increasing extracellular DA concentrations.

  49. Amphetamines • In general, amphetamines lead to elevated catecholamine levels that increase arousal and reduce sleep, while the effects on the dopamine system mediate euphoria but may also cause abnormal movements and precipitate psychotic episodes. • Effects on serotonin transmission may play a role in the hallucinogenicand anorexigenic functions as well as in the hyperthermia often caused by amphetamines.

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