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Basic and Clinical Pharmacology > Chapter
22. Sedative-Hypnotic Drugs >
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Case Study
At her annual physical
examination, a 53-year-old middle school teacher complains that she has
been having difficulty falling asleep and after falling asleep she
awakens several times during the night. These episodes now occur almost
nightly and are interfering with her ability to teach. She has tried
various over-the-counter sleep remedies, but they were of little help and
she experienced "hangover" effects on the day following their
use. Her general health is good, she is not overweight, and she takes no
prescription drugs. She drinks decaffeinated coffee but only one cup in
the morning; however, she drinks as many as 6 cans per day of diet cola.
She drinks a glass of wine with her evening meal but does not like
stronger spirits. What other aspects of this patient's history would you
like to know? What therapeutic measures are appropriate for this patient?
What drug, or drugs, (if any) would you prescribe?
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Sedative-Hypnotic Drugs: Introduction
Assignment of a drug to the
sedative-hypnotic class indicates that it is able to cause sedation (with
concomitant relief of anxiety) or to encourage sleep. Because there is
considerable chemical variation within the group, this drug
classification is based on clinical uses rather than on similarities in
chemical structure. Anxiety states and sleep disorders are common
problems, and sedative-hypnotics are widely prescribed drugs worldwide.
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Basic Pharmacology of Sedative-Hypnotics
An effective sedative
(anxiolytic) agent should reduce anxiety and exert a calming effect. The
degree of central nervous system depression caused by a sedative should
be the minimum consistent with therapeutic efficacy. A hypnotic
drug should produce drowsiness and encourage the onset and maintenance of
a state of sleep. Hypnotic effects involve more pronounced depression of
the central nervous system than sedation, and this can be achieved with
many drugs in this class simply by increasing the dose. Graded
dose-dependent depression of central nervous system function is a
characteristic of most sedative-hypnotics. However, individual drugs
differ in the relationship between the dose and the degree of central
nervous system depression. Two examples of such dose-response
relationships are shown in Figure 22–1. The linear slope for drug A is
typical of many of the older sedative-hypnotics, including the
barbiturates and alcohols. With such drugs, an increase in dose higher
than that needed for hypnosis may lead to a state of general anesthesia.
At still higher doses, these sedative-hypnotics may depress respiratory
and vasomotor centers in the medulla, leading to coma and death. Deviations
from a linear dose-response relationship, as shown for drug B, require
proportionately greater dosage increments to achieve central nervous
system depression more profound than hypnosis. This appears to be the
case for benzodiazepines and for certain newer hypnotics that have a
similar mechanism of action.
Chemical Classification
The benzodiazepines are
widely used sedative-hypnotics. All of the structures shown in Figure
22–2 are 1,4-benzodiazepines, and most contain a carboxamide group in the
7-membered heterocyclic ring structure. A substituent in the 7 position,
such as a halogen or a nitro group, is required for sedative-hypnotic
activity. The structures of triazolam and alprazolam include the addition
of a triazole ring at the 1,2-position.
The chemical structures of some older and less
commonly used sedative-hypnotics, including several barbiturates,
are shown in Figure 22–3. Glutethimide and meprobamate are of distinctive
chemical structure but are practically equivalent to barbiturates in their
pharmacologic effects. They are rarely used. The sedative-hypnotic class
also includes compounds of simpler chemical structure, including ethanol
(see Chapter 23) and chloral hydrate.
Several drugs with novel chemical structures have
been introduced more recently for use in sleep disorders. Zolpidem ,
an imidazopyridine, zaleplon , a pyrazolopyrimidine, and eszopiclone ,
a cyclopyrrolone (Figure 22–4), although structurally unrelated to
benzodiazepines, share a similar mechanism of action, as described below.
Eszopiclone is the (S) enantiomer of zopiclone, a hypnotic
drug that has been available outside the United States since 1989. Ramelteon,
a melatonin receptor agonist, is a new hypnotic drug (see Ramelteon). Buspirone
is a slow-onset anxiolytic agent whose actions are quite different from
those of conventional sedative-hypnotics (see Buspirone).
Other classes of drugs that
exert sedative effects include antipsychotics (see Chapter 29), and many
antidepressant drugs (see Chapter 30). The latter are currently used
widely in management of chronic anxiety disorders. Certain antihistaminic
agents including hydroxyzine and promethazine (see Chapter 16) are also
sedating. These agents commonly also exert marked effects on the
peripheral autonomic nervous system. Certain antihistaminic drugs with
sedative effects are available in over-the-counter sleep aids.
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Ramelteon
Melatonin receptors are
thought to be involved in maintaining circadian rhythms underlying the
sleep-wake cycle (see Chapter 16). Ramelteon, a novel hypnotic drug
prescribed specifically for patients who have difficulty in falling
asleep, is an agonist at MT1 and MT2 melatonin
receptors located in the suprachiasmatic nuclei of the brain. The drug
has no direct effects on GABAergic neurotransmission in the central
nervous system. In polysomnography studies of patients with chronic
insomnia, ramelteon reduced the latency of persistent sleep with no
effects on sleep architecture and no rebound insomnia or significant
withdrawal symptoms. The drug is rapidly absorbed after oral
administration and undergoes extensive first-pass metabolism, forming
an active metabolite with longer half-life (2–5 hours) than the parent
drug. The CYP1A2 isoform of cytochrome P450 is mainly responsible for
the metabolism of ramelteon, but the CYP2C9 isoform is also involved.
The drug should not be used in combination with inhibitors of CYP1A2
(eg, ciprofloxacin, fluvoxamine, tacrine, zileuton) or CYP2C9 (eg,
fluconazole) and should be used with caution in patients with liver
dysfunction. The CYP inducer rifampin markedly reduces the plasma
levels of both ramelteon and its active metabolite. Adverse effects of
ramelteon include dizziness, somnolence, fatigue, and endocrine changes
as well as decreases in testosterone and increases in prolactin.
Ramelteon is not a controlled substance.
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Buspirone
Buspirone has selective
anxiolytic effects, and its pharmacologic characteristics are different
from those of other drugs described in this chapter. Buspirone relieves
anxiety without causing marked sedative, hypnotic, or euphoric effects.
Unlike benzodiazepines, the drug has no anticonvulsant or muscle
relaxant properties. Buspirone does not interact directly with
GABAergic systems. It may exert its anxiolytic effects by acting as a
partial agonist at brain 5-HT1A receptors, but it also has
affinity for brain dopamine D2 receptors. Buspirone-treated
patients show no rebound anxiety or withdrawal signs on abrupt
discontinuance. The drug is not effective in blocking the acute
withdrawal syndrome resulting from abrupt cessation of use of
benzodiazepines or other sedative-hypnotics. Buspirone has minimal
abuse liability. In marked contrast to the benzodiazepines, the
anxiolytic effects of buspirone may take more than a week to become
established, making the drug unsuitable for management of acute anxiety
states. The drug is used in generalized anxiety states but is less
effective in panic disorders.
Buspirone is rapidly absorbed
orally but undergoes extensive first-pass metabolism via hydroxylation
and dealkylation reactions to form several active metabolites. The
major metabolite is 1-(2-pyrimidyl)-piperazine (1-PP), which has  2-adrenoceptor-blocking
actions and which enters the central nervous system to reach higher
levels than the parent drug. It is not known what role (if any) 1-PP
plays in the central actions of buspirone. The elimination half-life of
buspirone is 2–4 hours, and liver dysfunction may slow its clearance.
Rifampin, an inducer of cytochrome P450, decreases the half-life of
buspirone; inhibitors of CYP3A4 (eg, erythromycin, ketoconazole,
grapefruit juice, nefazodone) can markedly increase its plasma levels.
Buspirone causes less
psychomotor impairment than benzodiazepines and does not affect driving
skills. The drug does not potentiate effects of conventional
sedative-hypnotic drugs, ethanol, or tricyclic antidepressants, and
elderly patients do not appear to be more sensitive to its actions.
Nonspecific chest pain, tachycardia, palpitations, dizziness,
nervousness, tinnitus, gastrointestinal distress, and paresthesias and
a dose-dependent pupillary constriction may occur. Blood pressure may
be significantly elevated in patients receiving MAO inhibitors.
Buspirone is an FDA category B drug in terms of its use in pregnancy.
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Pharmacokinetics
Absorption and Distribution
The rates of oral absorption of
sedative-hypnotics differ depending on a number of factors, including
lipophilicity. For example, the absorption of triazolam is extremely
rapid, and that of diazepam and the active metabolite of clorazepate is
more rapid than other commonly used benzodiazepines. Clorazepate, a
prodrug, is converted to its active form, desmethyldiazepam
(nordiazepam), by acid hydrolysis in the stomach. Most of the
barbiturates and other older sedative-hypnotics, as well as the newer
hypnotics (eszopiclone, zaleplon, zolpidem), are absorbed rapidly into
the blood following oral administration.
Lipid solubility plays a major
role in determining the rate at which a particular sedative-hypnotic
enters the central nervous system. This property is responsible for the
rapid onset of central nervous system effects of triazolam, thiopental
(see Chapter 25), and the newer hypnotics.
All sedative-hypnotics cross the
placental barrier during pregnancy. If sedative-hypnotics are given
during the predelivery period, they may contribute to the depression of
neonatal vital functions. Sedative-hypnotics are also detectable in
breast milk and may exert depressant effects in the nursing infant.
Biotransformation
Metabolic transformation to more
water-soluble metabolites is necessary for clearance of
sedative-hypnotics from the body. The microsomal drug-metabolizing enzyme
systems of the liver are most important in this regard, so elimination
half-life of these drugs depends mainly on the rate of their metabolic
transformation.
Benzodiazepines
Hepatic metabolism accounts for
the clearance of all benzodiazepines. The patterns and rates of
metabolism depend on the individual drugs. Most benzodiazepines undergo
microsomal oxidation (phase I reactions), including N-dealkylation
and aliphatic hydroxylation catalyzed by cytochrome P450 isozymes, especially
CYP3A4. The metabolites are subsequently conjugated (phase II reactions)
to form glucuronides that are excreted in the urine. However, many phase
I metabolites of benzodiazepines are pharmacologically active, some with
long half-lives (Figure 22–5). For example, desmethyldiazepam, which has
an elimination half-life of more than 40 hours, is an active metabolite
of chlordiazepoxide, diazepam, prazepam, and clorazepate. Alprazolam and
triazolam undergo -hydroxylation, and the resulting
metabolites appear to exert short-lived pharmacologic effects because
they are rapidly conjugated to form inactive glucuronides. The short
elimination half-life of triazolam (2–3 hours) favors its use as a
hypnotic rather than as a sedative drug.
The formation of active
metabolites has complicated studies on the pharmacokinetics of the benzodiazepines
in humans because the elimination half-life of the parent drug may have
little relation to the time course of pharmacologic effects.
Benzodiazepines for which the parent drug or active metabolites have long
half-lives are more likely to cause cumulative effects with multiple
doses. Cumulative and residual effects such as excessive drowsiness
appear to be less of a problem with such drugs as estazolam, oxazepam,
and lorazepam, which have relatively short half-lives and are metabolized
directly to inactive glucuronides. Some pharmacokinetic properties of
selected benzodiazepines are listed in Table 22–1. The metabolism of
several commonly used benzodiazepines including diazepam, midazolam, and
triazolam is affected by inhibitors and inducers of hepatic P450 isozymes
(see Chapter 4).
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Table 22–1 Pharmacokinetic
Properties of Some Benzodiazepines and Newer Hypnotics in Humans.
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Drug
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Tmax1
(hours)
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t1/22 (hours)
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Comments
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Alprazolam
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1–2
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12–15
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Rapid oral
absorption
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Chlordiazepoxide
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2–4
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15–40
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Active
metabolites; erratic bioavailability from IM injection
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Clorazepate
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1–2
(nordiazepam)
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50–100
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Prodrug;
hydrolyzed to active form in stomach
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Diazepam
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1–2
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20–80
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Active
metabolites; erratic bioavailability from IM injection
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Eszopiclone
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1
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6
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Minor
active metabolites
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Flurazepam
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1–2
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40–100
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Active
metabolites with long half-lives
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Lorazepam
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1–6
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10–20
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No active
metabolites
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Oxazepam
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2–4
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10–20
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No active
metabolites
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Temazepam
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2–3
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10–40
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Slow oral
absorption
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Triazolam
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1
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2–3
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Rapid
onset; short duration of action
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Zaleplon
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< 1
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1–2
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Metabolized
via aldehyde dehydrogenase
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Zolpidem
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1–3
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1.5–3.5
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No active
metabolites
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1Time to peak blood level.
2Includes half-lives of major metabolites.
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Barbiturates
With the exception of
phenobarbital, only insignificant quantities of the barbiturates are
excreted unchanged. The major metabolic pathways involve oxidation by hepatic
enzymes to form alcohols, acids, and ketones, which appear in the urine
as glucuronide conjugates. The overall rate of hepatic metabolism in
humans depends on the individual drug but (with the exception of the
thiobarbiturates) is usually slow. The elimination half-lives of
secobarbital and pentobarbital range from 18 to 48 hours in different
individuals. The elimination half-life of phenobarbital in humans is 4–5
days. Multiple dosing with these agents can lead to cumulative effects.
Newer Hypnotics
After oral administration of the
standard formulation, zolpidem reaches peak plasma levels in 1.6 hours. A
biphasic release formulation extends plasma levels by approximately 2
hours. Zolpidem is rapidly metabolized to inactive metabolites via
oxidation and hydroxylation by hepatic cytochromes P450 including the
CYP3A4 isozyme. The elimination half-life of the drug is 1.5–3.5 hours,
with clearance decreased in elderly patients. Zaleplon is metabolized to
inactive metabolites mainly by hepatic aldehyde oxidase and partly by the
cytochrome P450 isoform CYP3A4. The half-life of the drug is about 1
hour. Dosage should be reduced in patients with hepatic impairment and in
the elderly. Cimetidine, which inhibits both aldehyde dehydrogenase and
CYP3A4, markedly increases the peak plasma level of zaleplon. Eszopiclone
is metabolized by hepatic cytochromes P450 (especially CYP3A4) to form
the inactive N-oxide derivative and weakly active
desmethyleszopiclone. The elimination half-life of eszopiclone is
approximately 6 hours and is prolonged in the elderly and in the presence
of inhibitors of CYP3A4 (eg, ketoconazole). Inducers of CYP3A4 (eg,
rifampin) increase the hepatic metabolism of eszopiclone.
Excretion
The water-soluble metabolites of
sedative-hypnotics, mostly formed via the conjugation of phase I
metabolites, are excreted mainly via the kidney. In most cases, changes
in renal function do not have a marked effect on the elimination of
parent drugs. Phenobarbital is excreted unchanged in the urine to a
certain extent (20–30% in humans), and its elimination rate can be
increased significantly by alkalinization of the urine. This is partly
due to increased ionization at alkaline pH, since phenobarbital is a weak
acid with a pKa of 7.4.
Factors Affecting Biodisposition
The biodisposition of
sedative-hypnotics can be influenced by several factors, particularly
alterations in hepatic function resulting from disease or drug-induced
increases or decreases in microsomal enzyme activities (see Chapter 4).
In very old patients and in
patients with severe liver disease, the elimination half-lives of these
drugs are often increased significantly. In such cases, multiple normal
doses of these sedative-hypnotics can result in excessive central nervous
system effects.
The activity of hepatic
microsomal drug-metabolizing enzymes may be increased in patients exposed
to certain older sedative-hypnotics on a long-term basis (enzyme
induction; see Chapter 4). Barbiturates (especially phenobarbital) and
meprobamate are most likely to cause this effect, which may result in an
increase in their hepatic metabolism as well as that of other drugs.
Increased biotransformation of other pharmacologic agents as a result of
enzyme induction by barbiturates is a potential mechanism underlying drug
interactions (see Chapter 66). In contrast, benzodiazepines and the newer
hypnotics do not change hepatic drug-metabolizing enzyme activity with
continuous use.
Pharmacodynamics of
Benzodiazepines, Barbiturates, & Newer Hypnotics
Molecular Pharmacology of the
GABAa Receptor
The benzodiazepines, the
barbiturates, zolpidem, zaleplon, eszopiclone, and many other drugs bind
to molecular components of the GABAA receptor in neuronal
membranes in the central nervous system. This receptor, which functions
as a chloride ion channel, is activated by the inhibitory
neurotransmitter GABA (see Chapter 21).
The GABAA receptor
has a pentameric structure assembled from five subunits (each with four
membrane-spanning domains) selected from multiple polypeptide classes (,  ,  ,  ,   ,  ,  , etc). Multiple subunits of several of
these classes have been characterized, eg, six different , four , and three . A model of the GABAA
receptor-chloride ion channel macromolecular complex is shown in Figure
22–6.
A major isoform of the GABAA
receptor that is found in many regions of the brain consists of two 1 subunits, two 2 subunits, and one 2 subunit. In this isoform,
the two binding sites for GABA are located between adjacent 1 and 2 subunits, and the binding
pocket for benzodiazepines (the BZ site of the GABAA
receptor) is between an 1 and the 2 subunit. However, GABAA
receptors in different areas of the central nervous system consist of
various combinations of the essential subunits, and the benzodiazepines
bind to many of these, including receptor isoforms containing 2, 3, and 5 subunits. Barbiturates
also bind to multiple isoforms of the GABAA receptor but at
different sites from those with which benzodiazepines interact. In
contrast to benzodiazepines, zolpidem, zaleplon, and eszopiclone bind
more selectively because these drugs interact only with GABAA-receptor
isoforms that contain 1 subunits. The
heterogeneity of GABAA receptors may constitute the molecular
basis for the varied pharmacologic actions of benzodiazepines and related
drugs (see GABA Receptor Heterogeneity & Pharmacologic Selectivity).
In contrast to GABA itself,
benzodiazepines and other sedative-hypnotics have a low affinity for GABAB
receptors, which are activated by the spasmolytic drug baclofen
(see Chapters 21 and 27).
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GABA Receptor Heterogeneity & Pharmacologic
Selectivity
Studies involving genetically engineered
("knockout") rodents have demonstrated that the specific
pharmacologic actions elicited by benzodiazepines and other drugs that
modulate GABA actions are influenced by the composition of the subunits
assembled to form the GABAA receptor. Benzodiazepines
interact primarily with brain GABAA receptors in which the subunits (1, 2, 3, and 5) have a
conserved histidine residue in the N-terminal domain. Strains of mice,
in which a point mutation has been inserted converting histidine to
arginine in the 1 subunit, show resistance
to both the sedative and amnestic effects of benzodiazepines, but
anxiolytic and muscle-relaxing effects are largely unchanged. These
animals are also unresponsive to the hypnotic actions of zolpidem and
zaleplon, drugs that bind selectively to GABAA receptors
containing 1 subunits. In contrast,
mice with selective histidine-arginine mutations in the 2 or 3 subunits of GABAA
receptors show selective resistance to the antianxiety effects of benzodiazepines.
Based on studies of this type, it has been suggested that 1 subunits in GABAA
receptors mediate sedation, amnesia, and ataxic effects of
benzodiazepines, whereas 2 and 3 subunits are involved in
their anxiolytic and muscle-relaxing actions. Other mutation studies
have led to suggestions that an 5 subtype is involved in
at least some of the memory impairment caused by benzodiazepines. It
should be emphasized that these studies involving genetic manipulations
of the GABAA receptor utilize rodent models of the
anxiolytic and amnestic actions of drugs.
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Neuropharmacology
GABA (-aminobutyric acid) is a major
inhibitory neurotransmitter in the central nervous system (see Chapter
21). Electrophysiologic studies have shown that benzodiazepines
potentiate GABAergic inhibition at all levels of the neuraxis, including
the spinal cord, hypothalamus, hippocampus, substantia nigra, cerebellar
cortex, and cerebral cortex. Benzodiazepines appear to increase the
efficiency of GABAergic synaptic inhibition. The benzodiazepines do not
substitute for GABA but appear to enhance GABA's effects allosterically
without directly activating GABAA receptors or opening the
associated chloride channels. The enhancement in chloride ion conductance
induced by the interaction of benzodiazepines with GABA takes the form of
an increase in the frequency of channel-opening events.
Barbiturates also facilitate the
actions of GABA at multiple sites in the central nervous system, but—in
contrast to benzodiazepines—they appear to increase the duration
of the GABA-gated chloride channel openings. At high concentrations, the
barbiturates may also be GABA-mimetic, directly activating chloride
channels. These effects involve a binding site or sites distinct from the
benzodiazepine binding sites. Barbiturates are less selective in their
actions than benzodiazepines, because they also depress the actions of
the excitatory neurotransmitter glutamic acid via binding to the AMPA
receptor. Barbiturates also exert nonsynaptic membrane effects in
parallel with their effects on GABA and glutamate neurotransmission. This
multiplicity of sites of action of barbiturates may be the basis for
their ability to induce full surgical anesthesia (see Chapter 25) and for
their more pronounced central depressant effects (which result in their
low margin of safety) compared with benzodiazepines and the newer
hypnotics.
Benzodiazepine Binding Site
Ligands
The components of the GABAA
receptor-chloride ion channel macromolecule that function as
benzodiazepine binding sites exhibit heterogeneity (see The Versatility
of the Chloride Channel GABA Receptor Complex). Three types of
ligand-benzodiazepine receptor interactions have been reported: (1)
Agonists facilitate GABA actions, and this occurs at multiple
BZ binding sites in the case of the benzodiazepines. As noted above, the
nonbenzodiazepines zolpidem, zaleplon, and eszopiclone are selective
agonists at the BZ sites that contain an 1 subunit. Endogenous
agonist ligands for the BZ binding sites have been proposed, because
benzodiazepine-like chemicals have been isolated from brain tissue of
animals never exposed to these drugs. Nonbenzodiazepine molecules that
have affinity for BZ sites on the GABAA receptor have also
been detected in human brain. (2) Antagonists are typified
by the synthetic benzodiazepine derivative flumazenil, which
blocks the actions of benzodiazepines, eszopiclone, zaleplon, and
zolpidem but does not antagonize the actions of barbiturates,
meprobamate, or ethanol. Certain endogenous neuropeptides are also
capable of blocking the interaction of benzodiazepines with BZ binding
sites. (3) Inverse agonists act as negative allosteric
modulators of GABA-receptor function (see Chapter 1). Their interaction
with BZ sites on the GABAA receptor can produce anxiety
and seizures, an action that has been demonstrated for several compounds,
especially the -carbolines, eg, n-butyl--carboline-3-carboxylate (-CCB). In addition to their direct
actions, these molecules can block the effects of benzodiazepines.
The physiologic significance of
endogenous modulators of the functions of GABA in the central nervous
system remains unclear. To date, it has not been established that the
putative endogenous ligands of BZ binding sites play a role in the
control of states of anxiety, sleep patterns, or any other characteristic
behavioral expression of central nervous system function.
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The Versatility of the Chloride Channel GABA
Receptor Complex
The GABAA-chloride
channel macromolecular complex is one of the most versatile
drug-responsive machines in the body. In addition to the
benzodiazepines, barbiturates, and the newer hypnotics (eg, zolpidem),
many other drugs with central nervous system effects can modify the
function of this important ionotropic receptor. These include alcohol
and certain intravenous anesthetics (etomidate, propofol) in addition
to thiopental. For example, etomidate and propofol (see Chapter 25)
appear to act selectively at GABAA receptors that contain 2 and 3 subunits, the latter
suggested to be the most important with respect to the hypnotic and
muscle-relaxing actions of these anesthetic agents. The anesthetic
steroid alphaxalone is thought to interact with GABAA
receptors, and they may also be targets for some of the actions of
volatile anesthetics (eg, halothane). Most of these agents facilitate
or mimic the action of GABA. However, it has not been shown that all
these drugs act exclusively by this mechanism. Other drugs used in the
management of seizure disorders indirectly influence the activity of
the GABAA-chloride channel macromolecular complex by
inhibiting GABA metabolism (eg, vigabatrin) or the reuptake of the
transmitter (eg, tiagabine). Central nervous system excitatory agents
that act on the chloride channel include picrotoxin and bicuculline.
These convulsant drugs block the channel directly (picrotoxin) or
interfere with GABA binding (bicuculline).
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Organ Level Effects
Sedation
Benzodiazepines, barbiturates,
and most older sedative-hypnotic drugs exert calming effects with
concomitant reduction of anxiety at relatively low doses. In most cases,
however, the anxiolytic actions of sedative-hypnotics are accompanied by
some depressant effects on psychomotor and cognitive functions. In
experimental animal models, benzodiazepines and older sedative-hypnotic
drugs are able to disinhibit punishment-suppressed behavior. This
disinhibition has been equated with antianxiety effects of
sedative-hypnotics, and it is not a characteristic of all drugs that have
sedative effects, eg, the tricyclic antidepressants and antihistamines.
However, the disinhibition of previously suppressed behavior may be more
related to behavioral disinhibitory effects of sedative-hypnotics,
including euphoria, impaired judgment, and loss of self-control, which
can occur at dosages in the range of those used for management of
anxiety. The benzodiazepines also exert dose-dependent anterograde
amnesic effects (inability to remember events occurring during the drug's
duration of action).
Hypnosis
By definition, all of the
sedative-hypnotics induce sleep if high enough doses are given. The
effects of sedative-hypnotics on the stages of sleep depend on several
factors, including the specific drug, the dose, and the frequency of its
administration. The general effects of benzodiazepines and older
sedative-hypnotics on patterns of normal sleep are as follows: (1) the
latency of sleep onset is decreased (time to fall asleep); (2) the
duration of stage 2 NREM (nonrapid eye movement) sleep is increased; (3)
the duration of REM (rapid eye movement) sleep is decreased; and (4) the
duration of stage 4 NREM slow-wave sleep is decreased. The newer
hypnotics all decrease the latency to persistent sleep. Zolpidem
decreases REM sleep but has minimal effect on slow-wave sleep. Zaleplon
decreases the latency of sleep onset with little effect on total sleep
time, NREM, or REM sleep. Eszopiclone increases total sleep time, mainly
via increases in stage 2 NREM sleep, and at low doses has little effect
on sleep patterns. At the highest recommended dose, eszopiclone decreases
REM sleep.
More rapid onset of sleep and
prolongation of stage 2 are presumably clinically useful effects.
However, the significance of sedative-hypnotic drug effects on REM and
slow-wave sleep is not clear. Deliberate interruption of REM sleep causes
anxiety and irritability followed by a rebound increase in REM sleep at
the end of the experiment. A similar pattern of "REM rebound"
can be detected following abrupt cessation of drug treatment with older
sedative-hypnotics, especially when drugs with short durations of action
(eg, triazolam) are used at high doses. With respect to zolpidem and the
other newer hypnotics, there is little evidence of REM rebound when these
drugs are discontinued after use of recommended doses. However, rebound
insomnia occurs with both zolpidem and zaleplon if used at higher doses.
Despite possible reductions in slow-wave sleep, there are no reports of
disturbances in the secretion of pituitary or adrenal hormones when
either barbiturates or benzodiazepines are used as hypnotics. The use of
sedative-hypnotics for more than 1–2 weeks leads to some tolerance to
their effects on sleep patterns.
Anesthesia
As shown in Figure 22–1, high
doses of certain sedative-hypnotics depress the central nervous system to
the point known as stage III of general anesthesia (see Chapter 25).
However, the suitability of a particular agent as an adjunct in
anesthesia depends mainly on the physicochemical properties that
determine its rapidity of onset and duration of effect. Among the
barbiturates, thiopental and methohexital are very lipid-soluble,
penetrating brain tissue rapidly following intravenous administration, a
characteristic favoring their use for the induction of anesthesia. Rapid
tissue redistribution (not rapid elimination) accounts for the short
duration of action of these drugs, a feature useful in recovery from
anesthesia.
Benzodiazepines—including
diazepam, lorazepam, and midazolam—are used intravenously in anesthesia
(see Chapter 25), often in combination with other agents. Not
surprisingly, benzodiazepines given in large doses as adjuncts to general
anesthetics may contribute to a persistent postanesthetic respiratory
depression. This is probably related to their relatively long half-lives
and the formation of active metabolites. However, such depressant actions
of the benzodiazepines are usually reversible with flumazenil.
Anticonvulsant Effects
Many sedative-hypnotics are
capable of inhibiting the development and spread of epileptiform
electrical activity in the central nervous system. Some selectivity
exists in that some members of the group can exert anticonvulsant effects
without marked central nervous system depression (although psychomotor
function may be impaired). Several benzodiazepines—including clonazepam,
nitrazepam, lorazepam, and diazepam—are sufficiently selective to be
clinically useful in the management of seizures (see Chapter 24). Of the
barbiturates, phenobarbital and metharbital (converted to phenobarbital
in the body) are effective in the treatment of generalized tonic-clonic
seizures, though not the drugs of first choice. Zolpidem, zaleplon, and
eszopiclone lack anticonvulsant activity, presumably because of their
more selective binding than that of benzodiazepines to GABAA
receptor isoforms.
Muscle Relaxation
Some sedative-hypnotics,
particularly members of the carbamate (eg, meprobamate) and
benzodiazepine groups, exert inhibitory effects on polysynaptic reflexes
and internuncial transmission and at high doses may also depress
transmission at the skeletal neuromuscular junction. Somewhat selective
actions of this type that lead to muscle relaxation can be readily
demonstrated in animals and have led to claims of usefulness for relaxing
contracted voluntary muscle in muscle spasm (see Clinical Pharmacology).
Muscle relaxation is not a characteristic action of zolpidem, zaleplon,
and eszopiclone.
Effects on Respiration and
Cardiovascular Function
At hypnotic doses in healthy
patients, the effects of sedative-hypnotics on respiration are comparable
to changes during natural sleep. However, even at therapeutic doses,
sedative-hypnotics can produce significant respiratory depression in
patients with pulmonary disease. Effects on respiration are dose-related,
and depression of the medullary respiratory center is the usual cause of
death due to overdose of sedative-hypnotics.
At doses up to those causing
hypnosis, no significant effects on the cardiovascular system are
observed in healthy patients. However, in hypovolemic states, heart
failure, and other diseases that impair cardiovascular function, normal
doses of sedative-hypnotics may cause cardiovascular depression, probably
as a result of actions on the medullary vasomotor centers. At toxic
doses, myocardial contractility and vascular tone may both be depressed
by central and peripheral effects, leading to circulatory collapse.
Respiratory and cardiovascular effects are more marked when
sedative-hypnotics are given intravenously.
Tolerance; Psychologic &
Physiologic Dependence
Tolerance—decreased
responsiveness to a drug following repeated exposure—is a common feature
of sedative-hypnotic use. It may result in the need for an increase in
the dose required to maintain symptomatic improvement or to promote
sleep. It is important to recognize that partial cross-tolerance occurs
between the sedative-hypnotics described here and also with ethanol (see
Chapter 23)—a feature of some clinical importance, as explained below.
The mechanisms responsible for tolerance to sedative-hypnotics are not
well understood. An increase in the rate of drug metabolism (metabolic
tolerance) may be partly responsible in the case of chronic
administration of barbiturates, but changes in responsiveness of the
central nervous system (pharmacodynamic tolerance) are of greater
importance for most sedative-hypnotics. In the case of benzodiazepines,
the development of tolerance in animals has been associated with
down-regulation of brain benzodiazepine receptors. Tolerance has been
reported to occur with the extended use of zolpidem. Minimal tolerance
was observed with the use of zaleplon over a 5-week period and
eszopiclone over a 6-month period.
The perceived desirable
properties of relief of anxiety, euphoria, disinhibition, and promotion
of sleep have led to the compulsive misuse of virtually all
sedative-hypnotics. (See Chapter 32 for a detailed discussion.) For this
reason, most sedative-hypnotic drugs are classified as Schedule III or
Schedule IV drugs for prescribing purposes. The consequences of abuse of
these agents can be defined in both psychologic and physiologic terms.
The psychologic component may initially parallel simple neurotic behavior
patterns difficult to differentiate from those of the inveterate coffee
drinker or cigarette smoker. When the pattern of sedative-hypnotic use
becomes compulsive, more serious complications develop, including
physiologic dependence and tolerance.
Physiologic dependence can be
described as an altered physiologic state that requires continuous drug
administration to prevent an abstinence or withdrawal syndrome. In the
case of sedative-hypnotics, this syndrome is characterized by states of
increased anxiety, insomnia, and central nervous system excitability that
may progress to convulsions. Most sedative-hypnotics—including
benzodiazepines—are capable of causing physiologic dependence when used
on a long-term basis. However, the severity of withdrawal symptoms
differs among individual drugs and depends also on the magnitude of the
dose used immediately before cessation of use. When higher doses of
sedative-hypnotics are used, abrupt withdrawal leads to more serious withdrawal
signs. Differences in the severity of withdrawal symptoms resulting from
individual sedative-hypnotics relate in part to half-life, since drugs
with long half-lives are eliminated slowly enough to accomplish gradual
withdrawal with few physical symptoms. The use of drugs with very short
half-lives for hypnotic effects may lead to signs of withdrawal even
between doses. For example, triazolam, a benzodiazepine with a half-life
of about 4 hours, has been reported to cause daytime anxiety when used to
treat sleep disorders. The abrupt cessation of zolpidem, zaleplon, or
eszopiclone may also result in withdrawal symptoms, though usually of
less intensity than those seen with benzodiazepines.
Benzodiazepine Antagonists:
Flumazenil
Flumazenil is one of several
1,4-benzodiazepine derivatives with a high affinity for the
benzodiazepine binding site on the GABAA receptor that act as
competitive antagonists. It blocks many of the actions of
benzodiazepines, zolpidem, zaleplon, and eszopiclone, but does not antagonize
the central nervous system effects of other sedative-hypnotics, ethanol,
opioids, or general anesthetics. Flumazenil is approved for use in
reversing the central nervous system depressant effects of benzodiazepine
overdose and to hasten recovery following use of these drugs in
anesthetic and diagnostic procedures. Although the drug reverses the
sedative effects of benzodiazepines, antagonism of benzodiazepine-induced
respiratory depression is less predictable. When given intravenously,
flumazenil acts rapidly but has a short half-life (0.7–1.3 hours) due to
rapid hepatic clearance. Because all benzodiazepines have a longer
duration of action than flumazenil, sedation commonly recurs, requiring
repeated administration of the antagonist.
Adverse effects of flumazenil
include agitation, confusion, dizziness, and nausea. Flumazenil may cause
a severe precipitated abstinence syndrome in patients who have developed
physiologic benzodiazepine dependence. In patients who have ingested
benzodiazepines with tricyclic antidepressants, seizures and cardiac
arrhythmias may follow flumazenil administration.
|
|
Clinical Pharmacology of Sedative-Hypnotics
Treatment of Anxiety States
The psychologic, behavioral, and
physiologic responses that characterize anxiety can take many forms.
Typically, the psychic awareness of anxiety is accompanied by enhanced
vigilance, motor tension, and autonomic hyperactivity. Anxiety is often
secondary to organic disease states—acute myocardial infarction, angina
pectoris, gastrointestinal ulcers, etc—which themselves require specific
therapy. Another class of secondary anxiety states (situational anxiety)
results from circumstances that may have to be dealt with only once or a
few times, including anticipation of frightening medical or dental
procedures and family illness or other stressful event. Even though
situational anxiety tends to be self-limiting, the short-term use of
sedative-hypnotics may be appropriate for the treatment of this and
certain disease-associated anxiety states. Similarly, the use of a
sedative-hypnotic as premedication prior to surgery or some unpleasant
medical procedure is rational and proper (Table 22–2).
|
Table 22–2 Clinical Uses of
Sedative-Hypnotics.
|
|
|
For relief
of anxiety
|
|
For
insomnia
|
|
For
sedation and amnesia before and during medical and surgical
procedures
|
|
For
treatment of epilepsy and seizure states
|
|
As a
component of balanced anesthesia (intravenous administration)
|
|
For control
of ethanol or other sedative-hypnotic withdrawal states
|
|
For muscle
relaxation in specific neuromuscular disorders
|
|
As
diagnostic aids or for treatment in psychiatry
|
|
|
|
Excessive or unreasonable
anxiety about life circumstances (generalized anxiety disorder, GAD),
panic disorders, and agoraphobia are also amenable to drug therapy,
sometimes in conjunction with psychotherapy. The benzodiazepines continue
to be widely used for the management of acute anxiety states and for
rapid control of panic attacks. They are also used, though less commonly,
in the long-term management of GAD and panic disorders. Anxiety symptoms
may be relieved by many benzodiazepines, but it is not always easy to
demonstrate the superiority of one drug over another. Alprazolam has been
used in the treatment of panic disorders and agoraphobia and appears to
be more selective in these conditions than other benzodiazepines. The
choice of benzodiazepines for anxiety is based on several sound pharmacologic
principles: (1) a rapid onset of action; (2) a relatively high
therapeutic index (see drug B in Figure 22–1), plus availability of
flumazenil for treatment of overdose; (3) a low risk of drug interactions
based on liver enzyme induction; (4) minimal effects on cardiovascular or
autonomic functions.
Disadvantages of the
benzodiazepines include the risk of dependence, depression of central
nervous system functions, and amnestic effects. In addition, the
benzodiazepines exert additive central nervous system depression when
administered with other drugs, including ethanol. The patient should be
warned of this possibility to avoid impairment of performance of any task
requiring mental alertness and motor coordination. In the treatment of
generalized anxiety disorders and certain phobias, newer antidepressants,
including selective serotonin reuptake inhibitors (SSRIs) and
serotonin-norepinephrine reuptake inhibitors (SNRIs), are now considered
by many authorities to be drugs of first choice (see Chapter 30).
However, these agents have a slow onset of action and thus minimal
effectiveness in acute anxiety states.
Sedative-hypnotics should be
used with appropriate caution so as to minimize adverse effects. A dose
should be prescribed that does not impair mentation or motor functions
during waking hours. Some patients may tolerate the drug better if most
of the daily dose is given at bedtime, with smaller doses during the day.
Prescriptions should be written for short periods, since there is little
justification for long-term therapy (defined as use of therapeutic doses
for 2 months or longer). The physician should make an effort to assess
the efficacy of therapy from the patient's subjective responses.
Combinations of antianxiety agents should be avoided, and people taking
sedatives should be cautioned about the consumption of alcohol and the
concurrent use of over-the-counter medications containing antihistaminic
or anticholinergic drugs (see Chapter 63).
Treatment of Sleep Problems
Sleep disorders are common and
often result from inadequate treatment of underlying medical conditions
or psychiatric illness. True primary insomnia is rare. Nonpharmacologic
therapies that are useful for sleep problems include proper diet and
exercise, avoiding stimulants before retiring, ensuring a comfortable
sleeping environment, and retiring at a regular time each night. In some
cases, however, the patient will need and should be given a
sedative-hypnotic for a limited period. It should be noted that the
abrupt discontinuance of many drugs in this class can lead to rebound
insomnia.
Benzodiazepines can cause a
dose-dependent decrease in both REM and slow-wave sleep, though to a
lesser extent than the barbiturates. The newer hypnotics zolpidem,
zaleplon, and eszopiclone are less likely than the benzodiazepines to
change sleep patterns. However, so little is known about the clinical
impact of these effects that statements about the desirability of a
particular drug based on its effects on sleep architecture have more
theoretical than practical significance. Clinical criteria of efficacy in
alleviating a particular sleeping problem are more useful. The drug
selected should be one that provides sleep of fairly rapid onset
(decreased sleep latency) and sufficient duration, with minimal "hangover"
effects such as drowsiness, dysphoria, and mental or motor depression the
following day. Older drugs such as chloral hydrate, secobarbital, and
pentobarbital continue to be used, but benzodiazepines, zolpidem,
zaleplon, or eszopiclone are generally preferred. Daytime sedation is
more common with benzodiazepines that have slow elimination rates (eg,
lorazepam) and those that are biotransformed to active metabolites (eg,
flurazepam, quazepam). If benzodiazepines are used nightly, tolerance can
occur, which may lead to dose increases by the patient to produce the
desired effect. Anterograde amnesia occurs to some degree with all
benzodiazepines used for hypnosis.
Eszopiclone, zaleplon, and
zolpidem have efficacies similar to those of the hypnotic benzodiazepines
in the management of sleep disorders. Favorable clinical features of
zolpidem and the other newer hypnotics include rapid onset of activity
and modest day-after psychomotor depression with few amnestic effects.
Zolpidem, one of the most frequently prescribed hypnotic drugs in the
United States, is available in a biphasic release formulation that
provides sustained drug levels for sleep maintenance. Zaleplon acts
rapidly, and because of its short half-life, the drug appears to have
value in the management of patients who awaken early in the sleep cycle.
At recommended doses, zaleplon and eszopiclone (despite its relatively
long half-life) appear to cause less amnesia or day-after somnolence than
zolpidem or benzodiazepines. The drugs in this class commonly used for
sedation and hypnosis are listed in Table 22–3 together with recommended
doses. Note: The failure of insomnia to remit after 7–10 days of
treatment may indicate the presence of a primary psychiatric or medical
illness that should be evaluated. Long-term use of hypnotics is an
irrational and dangerous medical practice.
|
Table 22–3 Dosages of Drugs
Used Commonly for Sedation and Hypnosis.
|
|
|
Sedation
|
Hypnosis
|
|
Drug
|
Dosage
|
Drug
|
Dosage (at
Bedtime)
|
|
Alprazolam
|
0.25–0.5 mg
2–3 times daily
|
Chloral
hydrate
|
500–1000 mg
|
|
Buspirone
|
5–10 mg 2–3
times daily
|
Estazolam
|
0.5–2 mg
|
|
Chlordiazepoxide
|
10–20 mg
2–3 times daily
|
Eszopiclone
|
1–3 mg
|
|
Clorazepate
|
5–7.5 mg
twice daily
|
Lorazepam
|
2–4 mg
|
|
Diazepam
|
5 mg twice
daily
|
Quazepam
|
7.5–15 mg
|
|
Halazepam
|
20–40 mg
3–4 times daily
|
Secobarbital
|
100–200 mg
|
|
Lorazepam
|
1–2 mg once
or twice daily
|
Temazepam
|
7.5–30 mg
|
|
Oxazepam
|
15–30 mg
3–4 times daily
|
Triazolam
|
0.125–0.5
mg
|
|
Phenobarbital
|
15–30 mg
2–3 times daily
|
Zaleplon
|
5–20 mg
|
|
|
|
Zolpidem
|
5–10 mg
|
|
|
|
Other Therapeutic Uses
Table 22–2 summarizes several
other important clinical uses of drugs in the sedative-hypnotic class.
Drugs used in the management of seizure disorders and as intravenous
agents in anesthesia are discussed in Chapters 24 and 25.
For sedative and possible
amnestic effects during medical or surgical procedures such as endoscopy
and bronchoscopy—as well as for premedication prior to anesthesia—oral
formulations of shorter-acting drugs are preferred.
Long-acting drugs such as
chlordiazepoxide and diazepam and, to a lesser extent, phenobarbital are
administered in progressively decreasing doses to patients during
withdrawal from physiologic dependence on ethanol or other
sedative-hypnotics. Parenteral lorazepam is used to suppress the symptoms
of delirium tremens.
Meprobamate and the
benzodiazepines have frequently been used as central muscle relaxants, though
evidence for general efficacy without accompanying sedation is lacking. A
possible exception is diazepam, which has useful relaxant effects in
skeletal muscle spasticity of central origin (see Chapter 27).
Psychiatric uses of
benzodiazepines other than treatment of anxiety states include the
initial management of mania and the control of drug-induced
hyperexcitability states (eg, phencyclidineintoxication).
Sedative-hypnotics are also used occasionally as diagnostic aids in
neurology and psychiatry.
Clinical Toxicology of
Sedative-Hypnotics
Direct Toxic Actions
Many of the common adverse
effects of sedative-hypnotics result from dose-related depression of the
central nervous system. Relatively low doses may lead to drowsiness,
impaired judgment, and diminished motor skills, sometimes with a
significant impact on driving ability, job performance, and personal
relationships. Sleep driving and other somnambulistic behavior with no
memory of the event has occurred with the sedative-hypnotic drugs used in
sleep disorders, prompting the FDA in 2007 to issue warnings of this
potential hazard. Benzodiazepines may cause a significant dose-related
anterograde amnesia; they can significantly impair ability to learn new
information, particularly that involving effortful cognitive processes,
while leaving the retrieval of previously learned information intact.
This effect is utilized for uncomfortable clinical procedures, eg,
endoscopy, because the patient is able to cooperate during the procedure
but amnesic regarding it afterward. The criminal use of benzodiazepines
in cases of "date rape" is based on their dose-dependent
amnestic effects. Hangover effects are not uncommon following use of
hypnotic drugs with long elimination half-lives. Because elderly patients
are more sensitive to the effects of sedative-hypnotics, doses
approximately half of those used in younger adults are safer and usually
as effective. The most common reversible cause of confusional states
in the elderly is overuse of sedative-hypnotics. At higher doses,
toxicity may present as lethargy or a state of exhaustion or,
alternatively, as gross symptoms equivalent to those of
ethanolintoxication. The physician should be aware of variability among
patients in terms of doses causing adverse effects. An increased
sensitivity to sedative-hypnotics is more common in patients with
cardiovascular disease, respiratory disease, or hepatic impairment and in
older patients. Sedative-hypnotics can exacerbate breathing problems in
patients with chronic pulmonary disease and in those with symptomatic
sleep apnea.
Sedative-hypnotics are the drugs
most frequently involved in deliberate overdoses, in part because of
their general availability as very commonly prescribed pharmacologic
agents. The benzodiazepines are considered to be safer drugs in this
respect, since they have flatter dose-response curves. Epidemiologic
studies on the incidence of drug-related deaths support this general
assumption—eg, 0.3 deaths per million tablets of diazepam prescribed
versus 11.6 deaths per million capsules of secobarbital in one study.
Alprazolam is purportedly more toxic in overdose than other
benzodiazepines. Of course, many factors other than the specific
sedative-hypnotic could influence such data—particularly the presence of
other central nervous system depressants, including ethanol. In fact,
most serious cases of drug overdosage, intentional or accidental, do
involve polypharmacy; and when combinations of agents are taken, the
practical safety of benzodiazepines may be less than the foregoing would
imply.
The lethal dose of any
sedative-hypnotic varies with the patient and the circumstances (see
Chapter 58). If discovery of the ingestion is made early and a
conservative treatment regimen is started, the outcome is rarely fatal,
even following very high doses. On the other hand, for most
sedative-hypnotics—with the exception of benzodiazepines and possibly the
newer hypnotic drugs that have a similar mechanism of action—a dose as
low as ten times the hypnotic dose may be fatal if the patient is not
discovered or does not seek help in time. With severe toxicity, the
respiratory depression from central actions of the drug may be
complicated by aspiration of gastric contents in the unattended
patient—an even more likely occurrence if ethanol is present.
Cardiovascular depression further complicates successful resuscitation.
In such patients, treatment consists of ensuring a patent airway, with
mechanical ventilation if needed, and maintenance of plasma volume, renal
output, and cardiac function. Use of a positive inotropic drug such as
dopamine, which preserves renal blood flow, is sometimes indicated.
Hemodialysis or hemoperfusion may be used to hasten elimination of some
of these drugs.
Flumazenil reverses the sedative
actions of benzodiazepines, and those of eszopiclone, zaleplon, and
zolpidem, although experience with its use in overdose of the newer
hypnotics is limited. However, its duration of action is short, its
antagonism of respiratory depression is unpredictable, and there is a
risk of precipitation of withdrawal symptoms in long-term users of
benzodiazepines. Consequently, the use of flumazenil in benzodiazepine
overdose remains controversial and must be accompanied by adequate
monitoring and support of respiratory function. The extensive clinical
use of triazolam has led to reports of serious central nervous system
effects including behavioral disinhibition, delirium, aggression, and
violence. However, behavioral disinhibition may occur with any
sedative-hypnotic drug, and it does not appear to be more prevalent with
triazolam than with other benzodiazepines. Disinhibitory reactions during
benzodiazepine treatment are more clearly associated with the use of very
high doses and the pretreatment level of patient hostility.
Adverse effects of the
sedative-hypnotics that are not referable to their central nervous system
actions occur infrequently. Hypersensitivity reactions, including skin
rashes, occur only occasionally with most drugs of this class. Reports of
teratogenicity leading to fetal deformation following use of certain
benzodiazepines have resulted in FDA assignment of individual
benzodiazepines to either category D or X in terms of pregnancy risk.
Most barbiturates are FDA pregnancy category D. Eszopiclone, ramelteon,
zaleplon, and zolpidem are category C, while buspirone is a category B
drug in terms of use in pregnancy. Because barbiturates enhance porphyrin
synthesis, they are absolutely contraindicated in patients with a
history of acute intermittent porphyria, variegate porphyria, hereditary
coproporphyria, or symptomatic porphyria.
Alterations in Drug Response
Depending on the dosage and the
duration of use, tolerance occurs in varying degrees to many of the
pharmacologic effects of sedative-hypnotics. However, it should not be
assumed that the degree of tolerance achieved is identical for all
pharmacologic effects. There is evidence that the lethal dose range is
not altered significantly by the long-term use of sedative-hypnotics.
Cross-tolerance between the different sedative-hypnotics, including
ethanol, can lead to an unsatisfactory therapeutic response when standard
doses of a drug are used in a patient with a recent history of excessive
use of these agents. However, there have been very few reports of
tolerance development when eszopiclone, zolpidem, or zaleplon was used
for less than 4 weeks.
With the long-term use of
sedative-hypnotics, especially if doses are increased, a state of
physiologic dependence can occur. This may develop to a degree
unparalleled by any other drug group, including the opioids. Withdrawal
from a sedative-hypnotic can have severe and life-threatening
manifestations. Withdrawal symptoms range from restlessness, anxiety,
weakness, and orthostatic hypotension to hyperactive reflexes and generalized
seizures. Symptoms of withdrawal are usually more severe following
discontinuance of sedative-hypnotics with shorter half-lives. However,
eszopiclone, zolpidem, and zaleplon appear to be exceptions to this,
because withdrawal symptoms are minimal following abrupt discontinuance
of these newer short-acting agents. Symptoms are less pronounced with
longer-acting drugs, which may partly accomplish their own
"tapered" withdrawal by virtue of their slow elimination.
Cross-dependence, defined as the ability of one drug to suppress
abstinence symptoms from discontinuance of another drug, is quite marked
among sedative-hypnotics. This provides the rationale for therapeutic
regimens in the management of withdrawal states: Longer-acting drugs such
as chlordiazepoxide, diazepam, and phenobarbital can be used to alleviate
withdrawal symptoms of shorter-acting drugs, including ethanol.
Drug Interactions
The most common drug
interactions involving sedative-hypnotics are interactions with other
central nervous system depressant drugs, leading to additive effects.
These interactions have some therapeutic usefulness when these drugs are
used as adjuvants in anesthesia practice. However, if not anticipated,
such interactions can lead to serious consequences, including enhanced
depression with concomitant use of many other drugs. Additive effects can
be predicted with concomitant use of alcoholic beverages, opioid
analgesics, anticonvulsants, and phenothiazines. Less obvious but just as
important is enhanced central nervous system depression with a variety of
antihistamines, antihypertensive agents, and antidepressant drugs of the
tricyclic class.
Interactions involving changes
in the activity of hepatic drug-metabolizing enzyme systems have been
discussed (see also Chapters 4 and 66).
|
|
Summary: Sedative-Hypnotics
|
|
|
Subclass and
Examples
|
Mechanism of
Action
|
Effects
|
Clinical
Applications
|
Pharmacokinetics,
Toxicities, Interactions
|
|
Benzodiazepines
|
|
Alprazolam
|
Bind to
specific GABAA receptor subunits at central nervous system
(CNS) neuronal synapses facilitating GABA-mediated chloride ion
channel opening  enhance membrane hyperpolarization
|
Dose-dependent
depressant effects on the CNS including sedation and relief of
anxiety, amnesia, hypnosis, anesthesia, coma and respiratory
depression
|
Acute
anxiety states panic attacks generalized anxiety disorder insomnia and other sleep disorders relaxation of skeletal muscle anesthesia (adjunctive) seizure
disorders
|
Half-lives
from 2–40 h oral activity Hepatic metabolism—some active
metabolites Toxicity: Extensions of CNS
depressant effects dependence liability Interactions: Additive CNS
depression with ethanol and many other drugs
|
|
Chlordiazepoxide
|
|
Clorazepate
|
|
Clonazepam
|
|
Diazepam
|
|
Estazolam
|
|
Flurazepam
|
|
Lorazepam
|
|
Midazolam
|
|
Oxazepam
|
|
Quazepam
|
|
Temazepam
|
|
Triazolam
|
|
Benzodiazepine
antagonist
|
|
Flumazenil
|
Antagonist
at benzodiazepine binding sites on the GABAA receptor
|
Blocks
actions of benzodiazepines and zolpidem but not other
sedative-hypnotic drugs
|
Management
of benzodiazepine overdose
|
IV, short
half-life Toxicity: Agitation,
confusion possible withdrawal symptoms in
benzodiazepine dependence
|
|
Barbiturates
|
|
Amobarbital
|
Bind to
specific GABAA receptor subunits at CNS neuronal synapses
facilitating GABA-mediated chloride ion channel opening enhance membrane hyperpolarization
|
Dose-dependent
depressant effects on the CNS including sedation and relief of
anxiety amnesia hypnosis anesthesia coma and respiratory depression steeper dose-response relationship
than benzodiazepines
|
Anesthesia
(thiopental) insomnia (secobarbital) seizure disorders (phenobarbital)
|
Half-lives
from 4–60 h oral activity hepatic metabolism—phenobarbital 20%
renal elimination Toxicity: Extensions of CNS depressant
effects dependence liability > benzodiazepines Interactions:
Additive CNS depression with ethanol and many other drugs induction
of hepatic drug-metabolizing enzymes
|
|
Butabarbital
|
|
Mephobarbital
|
|
Pentobarbital
|
|
Phenobarbital
|
|
Secobarbital
|
|
Newer
hypnotics
|
|
Eszopiclone
|
Bind
selectively to a subgroup of GABAA receptors, acting like
benzodiazepines to enhance membrane hyperpolarization
|
Rapid onset
of hypnosis with few amnestic effects or day-after psychomotor depression
or somnolence
|
Sleep
disorders, especially those characterized by difficulty in falling
asleep
|
Oral
activity short half-lives CYP substrates Toxicity: Extensions of CNS
depressant effects dependence liability Interactions: Additive CNS
depression with ethanol and many other drugs
|
|
Zaleplon
|
|
Zolpidem
|
|
Melatonin
receptor agonist
|
|
Ramelteon
|
Activates
MT1 and MT2 receptors in suprachiasmatic nuclei
in the CNS
|
Rapid onset
of sleep with minimal rebound insomnia or withdrawal symptoms
|
Sleep
disorders, especially those characterized by difficulty in falling
asleep not a controlled substance
|
Oral activity
forms active metabolite via CYP1A2 Toxicity: Dizziness fatigue endocrine changes Interactions: Fluvoxamine
inhibits metabolism
|
|
5-HT-receptor
agonist
|
|
Buspirone
|
Mechanism
uncertain: Partial agonist at 5-HT receptors but affinity for D2
receptors also possible
|
Slow onset
(1–2 weeks) of anxiolytic effects minimal psychomotor impairment—no
additive CNS depression with sedative-hypnotic drugs
|
Generalized
anxiety states
|
Oral
activity forms active metabolite short half-life Toxicity: Tachycardia paresthesias gastrointestinal distress Interactions: CYP3A4 inducers
and inhibitors
|
|
|
|
|
|
Preparations Available
Benzodiazepines
|
|
|
|
Alprazolam (generic, Xanax)
|
|
Oral:
0.25, 0.5, 1, 2 mg tablets, extended-release tablets, and orally disintegrating
tablets; 1.0 mg/mL solution
|
|
|
|
Chlordiazepoxide (generic, Librium)
|
|
Oral:
5, 10, 25 mg capsules
Parenteral:
100 mg powder for injection
|
|
|
|
Clorazepate (generic, Tranxene)
|
|
Oral:
3.75, 7.5, 15 mg tablets and capsules
Oral
extended-release: 11.25, 22.5 mg tablets
|
|
|
|
Clonazepam (generic, Klonopin)
|
|
Oral:
0.5, 1, 2 mg tablets; 0.125, 0.25, 0.5, 1, 2 mg orally
disintegrating tablets
|
|
|
|
Diazepam (generic, Valium)
|
|
Oral:
2, 5, 10 mg tablets; 1, 5 mg/mL solutions
Rectal:
2.5, 10, 20 mg gel
Parenteral:
5 mg/mL for injection
|
|
|
|
Estazolam (generic, ProSom)
|
|
|
Flurazepam (generic, Dalmane)
|
|
|
Lorazepam (generic, Ativan)
|
|
Oral:
0.5, 1, 2 mg tablets; 2 mg/mL solutionParenteral: 2, 4 mg/mL for
injection
|
|
|
|
Midazolam (Versed)
|
|
Oral:
2 mg/mL syrup
Parenteral:
1, 5 mg/mL in 1, 2, 5, 10 mL vials for injection
|
|
|
|
Oxazepam (generic, Serax)
|
|
Oral:
10, 15, 30 mg capsules; 15 mg tablets
|
|
|
|
Temazepam (generic, Restoril)
|
|
Oral:
7.5, 15, 22.5, 30 mg capsules
|
|
|
|
Triazolam (generic, Halcion)
|
|
Oral:
0.125, 0.25 mg tablets
|
|
|
Benzodiazepine Antagonist
|
|
|
|
Flumazenil (generic, Romazicon)
|
|
Parenteral:
0.1 mg/mL for IV injection
|
|
|
Barbiturates
|
|
|
|
Amobarbital
(Amytal)
|
|
Parenteral:
powder in 250, 500 mg vials to reconstitute for injection
|
|
|
|
Mephobarbital
(Mebaral)
|
|
Oral:
32, 50, 100 mg tablets
|
|
|
|
Pentobarbital
(generic, Nembutal Sodium)
|
|
Oral:
50, 100 mg capsules; 4 mg/mL elixir
Rectal:
30, 60, 120, 200 mg suppositories
Parenteral:
50 mg/mL for injection
|
|
|
|
Phenobarbital
(generic, Luminal Sodium)
|
|
Oral:
15, 16, 30, 60, 90, 100 mg tablets; 16 mg capsules; 15, 20 mg/5 mL
elixirs
Parenteral:
30, 60, 65, 130 mg/mL for injection
|
|
|
|
Secobarbital
(generic, Seconal)
|
|
Miscellaneous Drugs
|
|
|
|
Buspirone (generic, BuSpar)
|
|
Oral:
5, 7.5, 10, 15, 30 mg tablets
|
|
|
|
Chloral
hydrate (generic, Aquachloral
Supprettes)
|
|
Oral:
500 mg capsules; 250, 500 mg/5 mL syrups
Rectal:
324, 648 mg suppositories
|
|
|
|
Hydroxyzine
(generic, Atarax, Vistaril)
|
|
Oral:
10, 25, 50, 100 mg tablets; 25, 50, 100 mg capsules; 10 mg/5 mL
syrup; 25 mg/5 mL suspension
Parenteral:
25, 50 mg/mL for injection
|
|
|
|
Meprobamate
(generic, Equanil, Miltown)
|
|
Oral:
200, 400 mg tablets
|
|
|
|
Paraldehyde
(generic)
|
|
Oral,
rectal liquids: 1 g/mL
|
|
|
|
Zolpidem (generic, Ambien, Ambien-CR)
|
|
Oral:
5, 10 mg tablets; 6.25, 12.5 mg extended-release tablets
|
|
|
|
|
Case Study
As described in this chapter,
nonpharmacologic factors are very important in the management of sleep
problems: proper diet (and avoidance of snacks before bedtime), exercise,
and a regular time and place for sleep. Avoidance of stimulants is very
important, and the large intake of diet
colas reported by the patient
should be reduced, especially in the latter half of the day. If problems
persist after these measures are implemented, one of the newer hypnotics
(eszopiclone, zaleplon, or zolpidem) may be tried on a short-term basis.
|
|
References
|
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Long-term use of sedative hypnotics in older patients with insomnia.
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Bateson AN: The benzodiazepine
site of the GABA A receptor: An old target with new potential? Sleep
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Clayton T, et al: An updated
unified pharmacophore model of the benzodiazepine binding site on
gamma-aminobutyric acid(a) receptors: Correlation with comparative
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|
Da Settimo F et al: GABA A/Bz
receptor subtypes as targets for selective drugs. Curr Med Chem
2007;14:2680.
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|
Drover DR: Comparative
pharmacokinetics and pharmacodynamics of short-acting hypnosedatives:
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Erman M et al: An efficacy,
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