Drugs of Abuse Management PDF

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This document contains information on various aspects of substance abuse management and the effects of different drugs. It's targeted at postgraduate medical students or professionals.

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Drugs of Abuse
Management
Dr. Simón Q. Rodríguez Lara MD, PHD
Adapted by : Dr. Patricia A. Romero MD, MSc

WE MAKE DOCTORS
Objectives
To identify the clinical presentation of the
intoxication with the US most commonly used
substance of abuse
To identify the clinical presentation of withdrawal
syndrome of substances of abuse
To understand the pathophysiology of each
substance of abuse
To provide accurate treatment based on the
potential substance of abuse.
 Dependence vs addiction

With repetitive exposure, addictive drugs induce adaptive changes such as
tolerance (escalation of dose to maintain effect).

Addiction consists of compulsive, relapsing drug use
despite negative consequences, at times triggered by
cravings that occur in response to contextual cues.

Dependence is presented once the abused
drug is no longer available, signs of withdrawal
become apparent. A combination of such
signs, referred to as the withdrawal
syndrome.
 Dependence vs addiction

“Physical dependence” → Dependence.
“Psychological dependence” → Addiction.

Dependence invariably occurs with chronic exposure, only a small
percentage of subjects develop a habit, lose control, and become addicted.

Compulsive drug seeking and relapse to drug use are considered to be the
hallmarks of addiction.
 Dependence vs addiction

Certain mechanisms seem to be common for many
drugs:
Dopamine (DA) mechanisms are center stage (as a general rule,
all addictive drugs activate the mesolimbic dopamine system)
Activation of the extracellular signal-regulated kinase (ERK)
pathway.
Decrease in Calmodulin-related genes.
Increase transcription of genes related to lipid/cholesterol and
Golgi/endoplasmic reticulum (ER) function.
Glutamate and GABA receptor.
Tolerance & withdrawal
Tolerance
Chronic exposure to addictive drugs, will lead to
the brain adaptation (down-regulation/up-
regulation).

Withdrawal
Adaptive changes become fully apparent
once drug exposure is terminated.
We make Doctors
 Cocaine
Alkaloid ester extracted from the leaves of Erythroxylum coca.
Clinically → local anaesthetic and vasoconstrictor used
particularly in the eye, ear, nose, and throat. It also has powerful
central nervous system effects.

Mechanism of action
Reversibly binds and inactivates sodium channels.
Binds differentially to the dopamine, serotonin, and norepinephrine
transport proteins and directly prevents the re-uptake of dopamine,
serotonin, and norepinephrine into pre-synaptic neurons.
Effect on dopamine levels is most responsible for the addictive
property.
 Cocaine VGSC
Targets

Sodium-dependent dopamine
transporter antagonist. VGCC
Sodium-dependent noradrenaline
transporter antagonist.
Sodium-dependent serotonin SDDT
transporter antagonist. SDNT SDST
Sodium channel protein type 5, 10
and 11 subunit alpha antagonist.
Muscarinic acetylcholine receptor
M1 & M2 antagonist.
M1 M2

We make Doctors
 Cocaine Acute intoxication
management:
Effects - Benzodiazepines (diazepam)
Euphoria (might be replaced by anxiety), hyperactiveness, - Phentolamine
suppression of appetite, local anesthesia, and possible (cardiovascular
sudden death due to cardiac arrest. management).
Locomotor depression rather than stimulation. - Hypertermia → immersion in
Sympathomimetic properties → potent vasoconstrictor of cold water.
blood vessels in the brain (myocardial infarction or ischemic
stroke). - If needed:
- Nitroglycerine (refractory
hypertension)
Toxicity
- Non-selective B-blockers?
Intense agitation, convulsions, hypertension, rhythm
disturbance, coronary insufficiency, hyperthermia, Closely evaluate → risk
rhabdomyolysis, and renal impairment. of/ongoing MI, if yes → avoid
B-blockers
 Amphetamine type.

Similar structure to the catecholamine neurotransmitters → long planar
conformation, an aromatic ring and nitrogen in the aryl side chain.
A compound discovered over 100 years ago, is one of the more restricted
controlled drugs. It was previously used for a large variety of conditions
and this changed until this point where its use is highly restricted.
During World War II, amphetamine was used to promote wakefulness in
the soldiers. This use derived into a large overproduction of
amphetamine and all the surplus after the war finalized end up in the
black market which produced the initiation of the illicit abuse.
Amphetamine (AMPH), methamphetamine (METH), methylphenidate
(MPH) and 3,4-methylenedioxymethamphetamine (MDMA, ecstasy).
 Amphetamine type

Mechanism of action
Is taken into presynaptic nerve terminals by the association with two
sodium ions and one chloride ion. The complex of the amphetamine
with the ions is actively transported by monoamine reuptake
transporters. As amphetamine acts competitively with the
endogenous monoamines, the greater the number of amphetamines
the more internalized amphetamine will be found.
Displaces other monoamines to be stored by VMAT2 which produces
the pumping of the neurotransmitters into the synapse by a process
called retro-transport.
Inhibition of the reuptake and of monoamine oxidase

We make Doctors
 Amphetamine Type
Targets
Synaptic vesicular amine transporter antagonist
Vesicular monoamine transporter 2 (VMAT2) antagonist
Sodium-dependent dopamine transporter modulator
Sodium-dependent noradrenaline transporter modulator
Sodium-dependent serotonin transporter modulator
Monoamine oxidase antagonist
Alpha adrenergic receptor agonist
Beta adrenergic receptor agonist
SET MAO
NAT
Amphetamine Type

Effects
Elevated catecholamine levels → arousal
and reduce sleep,
on the dopamine system → euphoria, may
cause abnormal movements and
precipitate psychotic episodes.
Effects on serotonin transmission→
hallucinogenic and anorexigenic functions
as well as in hyperthermia.
 Amphetamine Type Toxicity

Acute amphetamine overdose → hyperthermia, respiratory
depression, seizures, metabolic acidosis, renal failure,
hepatic injury, and coma.
Neurologic effects → agitation, aggressive behavior,
irritability, headache, and hallucinations.
Cardiovascular → arrhythmia, cardiomyopathy,
myocardial infarction or ischemic stroke.
GI tract → abdominal pain, vomiting, diarrhea, cramps,
anorexia, and GI hemorrhage.
Amphetamines are neurotoxic. Neurotoxicity depends on
the NMDA receptor and affects mainly serotonin and
dopamine neurons.
 Amphetamine Type

We make Doctors
 Amphetamine Type

Metabolism: Liver under the action of the CYP2D6.

Elimination: Urine 40%, 90% is eliminated 72 h after
oral administration. Depends from urine pH; acidic
pH will produce a higher excretion of amphetamine
and basic pH produces a lower excretion.
 Lysergic acid diethylamide (LSD)
Mechanism of action Effects
Activates the serotonin 5-HT2A receptor in Mood alteration, sleep
the prefrontal cortex, enhancing glutamatergic disturbances and anxiety.
transmission onto pyramidal neurons, Tachycardia, increase blood
enhancing the perception. Repeated doses pressure and body temperature,
induce rapidly down regulation. dizziness, decrease appetite, and
Target sweating. The most troubling side
5-hydroxytryptamine receptor 1A, 2B, 6 effect are the lost of judgement
agonist. and impaired reasoning (bad trip).
Marijuana
Cannabis sativa and Cannabis indica →
evidence has demonstrated its potential
usefulness in the management of chronic pain,
spasticity, inflammation, epilepsy, and
chemotherapy-induced nausea and vomiting
among many others.
Contains more than 400 different chemical
compounds, of which 61 are considered
cannabinoids, a class of compounds that act
upon cannabinoid receptors of the body.
Tetrahydrocannabinol (THC) and Cannabidiol
(CBD) types of cannabinoids found naturally in
the resin of the marijuana plant, both interact
with the cannabinoid receptors.
 Marijuana
Mechanism of action
The primary psychoactive component of
Cannabis, delta 9-tetrahydrocannabinol
(Δ9-THC) →weak partial agonist activity at
Cannabinoid-1 (CB1R) and Cannabinoid-2
(CB2R) receptors.
CBD → acts as a negative allosteric
modulator of the cannabinoid CB1 receptor,
the most abundant G-Protein Coupled
Receptor (GPCR) in the body.

Effects
Increased appetite, reduced pain,
and changes in emotional and
cognitive processes.
 Marijuana

Targets
Cannabinoid receptor
1 & 2 modulator
Glycine receptor
subunit alpha-1, -3,
alpha-1/beta.
N-arachidonyl glycine
receptor agonist
 Nicotine
Nicotine is the principal neuroactive alkaloid responsible for
tobacco addiction.
Nicotine is highly toxic alkaloid. It is the prototypical agonist at
nicotinic cholinergic receptors where it dramatically stimulates
neurons and ultimately blocks synaptic transmission.
Nicotine is a highly addictive substance.
 Nicotine

Mechanism of action
Binds stereo-selectively to nicotinic-cholinergic receptors on
autonomic ganglia, the adrenal medulla, neuromuscular junctions
and in the brain.
Nicotine exerts two effects, a stimulant effect exerted at the locus
ceruleus and a reward effect in the limbic system.

Causes release of acetylcholine, norepinephrine,
dopamine, serotonine, vasopressin, beta-endorphin
and ACTH.
 Nicotine
Targets
Neuronal acetylcholine
receptor subunit alpha-
3, -4, -5, -6, -7, -9, -10;
beta-2, -3, -4 agonist
Cytochrome P450 19A1
antagonist
Choline O-
acetyltransferase
antagonist
Nicotine Effects
Nicotine addiction leads to increased risk of
severe adverse health effects caused by
tobacco.
Distribution of nAChRs with different subunit
combinations in various brain regions
contributes to diverse mechanisms of
plasticity.
Mechanisms of nicotine-induced plasticities
include upregulation and downregulation of
nAChRs; interactions with catecholaminergic,
GABAergic, and glutamatergic
neurotransmission; and neurodegenerative
structural changes in fasciculus retroflexus
and cortex.
 Ethanol
A clear, colorless liquid rapidly absorbed from
the gastrointestinal tract and distributed
throughout the body.
It has bactericidal activity and is used often as
a topical disinfectant.
It is widely used as a solvent and preservative
in pharmaceutical preparations as well as
serving as the primary ingredient in alcoholic
beverages.
Is a two-carbon alcohol that directly affects
many different types of neurochemical
systems and signaling cascades and has
rewarding and addictive properties.
Ethanol

The legally allowed blood ethanol concentration
(BEC) for operating a motor vehicle is 80 mg% (80 mg
ethanol per 100 mL blood; 0.08% w/v) in the United
States, which is equivalent to a concentration of 17
mM ethanol in blood.
The consumption of one standard drink (a 12-oz
bottle of beer, a 5-oz glass of wine, or a 1.5-oz shot of
40% liquor) by a 70-kg person would produce a BEC
of about 30 mg%.
 Ethanol

Absorption
absorbed rapidly into the bloodstream from the
stomach and small intestine and distributes
into total body water (~0.65 L/kg body weight).
Peak blood levels occur about 30 min after
ingestion.
First-pass metabolism by gastric and liver ADH
Metabolism
The main enzymes involved in ethanol
metabolism are ADH and ALDH, followed by
catalase and CYP2E1. Epithelial cells of GI tract
and liver.
 Ethanol

Mechanism of action
Affects the brain’s neurons in several ways.
It alters their membranes as well as their ion channels,
enzymes, and receptors. Alcohol also binds directly to the
receptors for acetylcholine, serotonin, GABA, and the NMDA
receptors for glutamate.
The sedative effects of ethanol are mediated through binding
to GABA receptors and glycine receptors (alpha 1 and alpha 2
subunits). It also inhibits NMDA receptor functioning.
In its role as an anti-infective, ethanol acts as an osmolyte or
dehydrating agent that disrupts the osmotic balance across cell
membranes.
Ethanol
Ethanol
Ethanol Teratogeni
Neural
Sexual
c function

Immune Bone

Body
Hematologic
temperatu
al
re

Ethanol effects
Cancer Diuresis

Cardiovascul
Liver
ar system

Digestive
Stroke
system
Skeletal
Lungs
muscle
Ethanol Treatment