Drugs Acting on the Central Nervous System PDF

Summary

This presentation details drugs acting on the central nervous system (CNS) in veterinary medicine. It covers mechanisms of action, therapeutic uses, and adverse effects for various CNS drugs. The document provides a comprehensive overview of drugs used in treating conditions related to the CNS.

Full Transcript

Drugs Acting on the
Central Nervous
System
Mohanad AlBayati
Mohanad AbdulSattar Ali Al-Bayati, BVM&S, MS.
Physiology, PhD.
Assistant Professor of Pharmacology and Toxicology
Department of Physiology and Pharmacology
College of Veterinary Medicine
University of Baghdad
Al-Jaderia, Baghdad
Phone: 0964 7700766550
E. Mail: [email protected]
[email protected]
 INTRODUCTION
Function. Drugs can alter the
function of the central nervous
system (CNS) to provide
1. Anticonvulsant effects
2. Tranquilization (sedation)
3. Analgesia
 Neurotransmitter–receptor
relationship
Neurotransmitters released by a presynaptic
neuron combine with receptors on the
plasma membrane of a postsynaptic neuron,
altering its membrane potential.
1. Neurotransmitters in the CNS include
dopamine,
γ-aminobutyric acid (GABA),
acetylcholine (ACh),
norepinephrine,
serotonin,
histamine,
glutamate,
glycine,
substance P, and many neuropeptides.
Continue
2. Receptors for neurotransmitters are the site of
action for exogenous drugs.
a. The neurotransmitter–receptor complex may
directly alter the permeability of the cell
membrane by opening or closing specific ion
channels.
b. Second messengers. The neurotransmitter-
receptor complex may initiate a sequence of
chemical reactions that alter ion transport across
the membrane, thereby altering the membrane
potential. Specific intracellular signal molecules, or
second messengers, may be generated. The second
messenger system sustains and amplifies the
cellular response to drug–receptor binding. The vast
majority of these neurotransmitters have G protein-
coupled receptors (GPCRs).
 Blood–brain barrier
(BBB)
Circulating drugs must cross BBB in order to gain
access to the neurons of the brain
1. Drugs that are cross BBB most readily
a. lipid soluble,
b. small in molecular size,
c. poorly bound to protein,
d. nonionized at the pH of cerebrospinal fluid (CSF)
2. The BBB tends to increase in permeability in
the presence of inflammation or at the site of tumors.
3. The BBB is poorly developed in neonates;
hence, chemicals can easily gain access to the
neonatal brain.
 ANTICONVULSANT
DRUGS
Only a few of the anticonvulsant drugs
available for human use have been
proven to be clinically useful in dogs
and cats.
a. Some of the drugs are too rapidly
metabolized in dogs to be effective, even
at high dosages.
b. Clinical experience un known in cats.
Cats are generally assumed to
metabolize drugs more slowly and poorly
than dogs.
Mechanism of action

Anticonvulsant drugs stabilize
neuronal membranes
a. They may act directly on ion channels, resulting
in hyperpolarization of the neuronal membrane.
b. They activate GABA-gated Cl− channels
increasing the frequency of Cl− channel opening
produced by GABA, thereby evoking
hyperpolarization of the neurons.
Therapeutic uses
Anticonvulsant drugs reduce the
1. Incidence,
2. Severity,
3. Duration of seizures

Adverse effects:
4. seizures, or status epilepticus may follow
rapid cessation of administration of these
drugs
5. Enzyme induction
6. Hepatotoxicity
 Barbiturates
Henobarbital
Chemistry. Phenobarbital is an
oxybarbiturate.
Mechanism of action. Barbiturates
activate GABA-gated Cl− channels,
thereby evoking hyperpolarization of
the neurons.
Pharmacologic effects
(1) Phenobarbital limits the spread of action potentials and
thus elevates the seizure threshold.
(2) Most barbiturates have anticonvulsant effects, but
phenobarbital is unique in that it usually produces this effect at
lower doses than those necessary to cause pronounced CNS
depression (sedation).

Therapeutic uses. Phenobarbital is used for the long-term
control of seizures.
Phenobarbital is usually administered orally
It is not useful for terminating an ongoing seizure because the
time span from administration until the onset of effect is too
long (∼20 minutes).
When given orally, its GI absorption is practically complete in
all animals. Peak levels occur in 4–8 hours after oral dosing in
dogs.
Adverse effects

Sedation, polydipsia, polyuria, and
polyphagia are common side effects.
Dogs develop a tolerance to the
sedative effects after 1–2 weeks,
 Primidone
Primidone is a deoxybarbiturate (an analog of
phenobarbital).
Primidone is slowly absorbed after oral
administration in dogs
In cats, the metabolism to phenobarbital is
slower
Adverse effects. Prolonged use of
primidone in dogs may lead to decreased
serum albumin and elevated serum
concentrations of liver enzymes.
Occasionally, serious liver damage occurs.
Pentobarbital
Pentobarbital is an oxybarbiturate
Therapeutic uses. Pentobarbital will terminate
seizures at a dose that produces anesthesia. This
dose usually results in significant
cardiopulmonary depression
but may be the only way to control status
epilepticus
It has a rapid onset (5 minutes or
recurrent seizures between
They can be used as a maintenance
anticonvulsant in cats.
a very limited use as a maintenance
anticonvulsant in dogs, because the development
of tolerance occurs rapidly in this species due to
drug metabolism into inactive metabolites.
because the development of tolerance occurs
rapidly in this species due to drug metabolism
into inactive metabolites.
Diazepam
Mechanism of action. Benzodiazepines activate
GABA-gated Cl− channels to potentiate the channel
opening activity of GABA, thereby evoking
hyperpolarization of the neurons.
Therapeutics uses
In cats, it is administered orally for seizure control
developing tolerance make diazepam
In dogs, it is administered IV for the control of status
epilepticus and cluster seizures.
in dogs as a maintenance anticonvulsant because it
has a short t 1/2 of 2–4 hours
Adverse effects
(1) Changes in behavior (irritability,
depression, and aberrant demeanor)
may occur after receiving diazepam.
(2) Cats may develop acute fatal
hepatic necrosis
Midazolam

Therapeutic uses. Midazolam is used as an
anticonvulsant for status epilepticus, muscle
relaxant, tranquilizer, and appetite stimulant
the same way as diazepam
Pharmacokinetics. Midazolam has a shorter
elimination t 1/2 of 77 minutes in dogs, which is
shorter than diazepam (∼3 hours). Readily
crosses BBB
Adverse effects. Midazolam may cause mild
respiratory depression, vomiting, restless
behavior, agitation, and local irritation.
Clonazepam

Therapeutic uses. The uses are the same as
diazepam without distinct advantages over
diazepam. Clonazepam alone has very limited
value as a maintenance anticonvulsant
because of the rapid development of drug
tolerance.
Adverse effects. Tolerance to the
anticonvulsant effects in dogs, GI
disturbances, including vomiting, hyper-
salivation, and diarrhea/ constipation may
occur.
Lorazepam
Mechanism of action
a. It is hypothesized that Br− enters neurons via
Cl− channels, resulting in hyperpolarization of the
neuronal membrane.
b. Barbiturates and benzodiazepines, which
enhance Cl− conductance, may act in synergy with
KBr to hyperpolarize neurons, thus raising the
seizure threshold.
Therapeutic uses
a. KBr is administered orally to treat refractory
seizures in dogs. The use in cats is not
recommended, since it evokes severe asthma in
this species.
b. It is used in combination with phenobarbital to
terminate refractory generalized tonic-clonic
Adverse effects
a. Transient sedation at the beginning of therapy
may occur.
b. GI effects. Stomach irritation can produce
nausea and vomiting. Vomiting, anorexia, and
constipation are indications of toxicity.
c. Polydipsia, polyuria, polyphagia, lethargy,
irritability, and aimless walking are additional
adverse effects of Br−.
d. Pancreatitis may be precipitated by Br−.
e. Severe asthma can be seen in Br−-treated cats.
Valproic acid and sodium valproate

Valproic acid is a derivative of carboxylic acid. It
is structurally unrelated to other anticonvulsant
drugs.
Therapeutic uses
a. In dogs, valproic acid is effective in controlling
seizures when given orally, but its short t 1/2
makes it impractical for long-term use. It is a
second to fourth-line anticonvulsant that may be
useful as an adjunctive treatment in some dogs.
b. Its clinical usefulness in cats has not been
evaluated.
 Adverse effects
a. GI disturbances and hepatotoxicity. Vomiting,
anorexia, and diarrhea, which may be diminished
by administration with food. Hepatotoxicity,
including liver failure, is a potential adverse effect
in dogs.
b. CNS effects (sedation, ataxia, behavioral
changes, etc.),
c. Dermatologic effects (alopecia, rash, etc.),
hematologic effects (thrombocytopenia, reduced
platelet aggregation, leukopenia, anemia, etc.),
pancreatitis, and edema.
 Gabapentin. It is a synthetic GABA analog that
can cross BBB to exert its anticonvulsant effect.
Mechanism of action. GABA content in neurons
is increased by gabapentin. However, the main
effect of gabapentin is due to its inhibition of
voltage dependent Ca2+ channels to decrease
neuronal Ca2+ levels, thereby inhibiting excitatory
neurotransmitter release (e.g., glutamate).
Therapeutic uses. Gabapentin may be useful as
adjunctive therapy for refractory or complex
partial seizures, or in the treatment of chronic
pain in dogs or cats. It is administered orally.
Adverse effects. Sedation, ataxia, and mild
polyphagia are noticeable side effects. Abrupt
discontinuation of gabapentin may cause
seizures.
 Levetiracetam. It is used orally as an adjunctive
therapy for refractory canine epilepsy. It is well
tolerated in dogs and an initial prospective trial in
cats was favorable
Mechanism of action. Levetiracetam inhibits
hypersynchronization of epileptiform burst firing
and propagation of seizure activity.
It binds synaptic vesicle protein 2A
in the neuron; the interaction with this neuronal
vesicular protein may account for levetiracetam’s
anticonvulsant effect.
Adverse effects. It has little side effects, which
include changes in behavior, drowsiness, and GI
disturbances (vomiting and anorexia). Withdrawal
of this drug should be slow in order to prevent
“withdrawal” seizures.
 Felbamate is a dicarbamate drug and is used orally in
dogs to treat refractory epilepsy as an adjunctive therapy
or a sole anticonvulsant agent for patients with focal and
generalized
seizures.
At clinical doses, felbamate does not induce sedation
and thus is particularly useful in the control of
obtunded mental status due to brain tumor or cerebral
infarct.
Mechanism of action
a. Blockade of NMDA receptor-mediated neuronal excitation.
b. Potentiation of GABA-mediated neuronal inhibition.
c. Inhibition of voltage-dependent Na+ and Ca2+ channels.
Adverse effects.
a. liver dysfunction. it should not be given to dogs with a
liver disease hepatotoxicity,
b. Reversible bone marrow depression is rarely seen in dogs.
These dogs may have thrombocytopenia and leucopenia.
c. Keratoconjunctivitis sicca and generalized tremor are rarely
seen side effects of felbamate in dogs.
Zonisamide is a sulfonamide-based
anticonvulsant drug or an adjunctive
therapy to control refractory epilepsy in
dogs with minimal adverse effects. It is
administered orally twice a day.
the cost could be a problem for using this
drug in dogs. The drug has not been studied
sufficiently in cats to be recommended for
this species.
Mechanism of action. Zonisamide
inhibits voltage-dependent Na+ and Ca2+
channels of neurons to induce
hyperpolarization and decreased Ca2+
influx
Adverse effects. Zonisamide has high
 CNS STIMULANTS
Doxapram is (ANALEPTICS)
used most frequently in veterinary medicine as
a CNS stimulant.
1. Mechanism of action. Doxapram stimulates respiration,
which is a result of direct stimulation of the medullary
respiratory centers and probably via activation of carotid and
aortic chemoreceptors.
2. Therapeutic uses
a. Doxapram is used to arouse animals from inhalant and
parenteral anesthesia or anesthetic overdose. The depth of
anesthesia is reduced, but the effect could be transient.
b. Doxapram is not effective in reviving a severely depressed
neonate and is not a good substitute for endotracheal
intubation and ventilation.
3. Adverse effects.
High doses of doxapram may induce seizures.
Hypertension, arrhythmias, seizures, and hyperventilation
leading to respiratory alkalosis can happen.
 TRANQUILIZERS, ATARACTICS,
NEUROLEPTICS, AND SEDATIVES
These terms are used interchangeably in veterinary
medicine to refer the drugs that calm the animal
and promote sleep but do not necessarily induce
sleep, even at high doses. Ataractic means
“undisturbed”; neuroleptic means “to take hold of
nerves.” tranquilized
animals are usually calm and easy to handle,
but they may be aroused by and respond to
stimuli in a normal fashion (e.g., biting,
scratching, kicking). When used
as pre-anesthetic medications, these drugs enable
the use of less general anesthetic.
 Phenothiazine derivatives include
acepromazine, promethazine, chlorpromazine,
fluphenazine, prochlorperazine, and
trimeprazine.
Mechanism of action.
Phenothiazine derivatives affect the
CNS at the basal ganglia,
hypothalamus, limbic system, brain
stem, and reticular activating
system. They block dopamine, α1-
adrenergic and serotonergic
receptors
Pharmacologic effects

CNS effects
(1) The tranquilizing effects( depression of the brain stem via
blockade of dopamine and 5-HT receptors.
(2) All phenothiazines decrease spontaneous motor activity.
Cardiovascular effects
1. Hypotension (α1-adrenergic receptor blockade
and a decrease in the sympathetic tone)
2. Reflex sinus
3. Antiarrhythmic effects
4. Inotropic effect.
Respiratory effects :Respiratory depression
GI effects 1. Motility is inhibited 2. Emesis is suppressed
Effects on blood. Packed cell volume decreases
Metabolic effects
1. Hypothermia/hyperthermia
2. Hyperglycemia
3. Hyperprolactinemia.
Therapeutic uses
a. tranquilization.
b. antiemetics.
c. prior to use of inhalant anesthetics can
reduce
the incidence of arrhythmias sensitization to
catecholamines.
d. Promethazine and trimeprazine are used to
control allergy, because they block H1-
receptors.
Adverse effects. There is no reversal agent for this
class of drugs.
a. Accidental intracarotid administration in horses results in
the immediate onset of seizure activity and, sometimes,
death.
b. They inhibit cholinesterase (ChE) and may worsen the
clinical signs of anti-ChE poisoning. They should not be given
to animals within 1 month of treatment with an
organophosphate compound.
c. The H1-antagonistic effect makes phenothiazines an
undesirable drug for sedation of animals prior to allergy
testing.
d. Paraphimosis may occur in stallions, which is due to
relaxation of retractive
penis muscles via α1-receptor blockade. Thus, phenothiazines
should be used
cautiously or avoided altogether in breeding stallions.
Contraindications
a. Anti-ChE poisoning or suspected treatment with anti-ChE
 α2-Adrenergic agonists These drugs
activate α2-adrenergic receptors in the
CNS, thereby causing analgesia, sedation,
and skeletal muscle relaxation.
Mechanism of action. α2-Agonists activate
α2-receptors that are Gi/o-coupled receptors;
Gi/o mediates many inhibitory effects on the
nervous systems and endocrine glands
High doses of xylazine, detomidine, and
romifidine also activate α1-receptors.
Pharmacological effects

Analgesia.
(1) α2-Receptors are located on the dorsal
horn neurons of the spinal cord, they can
inhibit the release of nociceptive
neurotransmitters, substance P and
calcitonin gene-related peptide (CGRP).
(2) α2-Adrenergic mechanisms do not
work through opioidergic mechanisms,
because cross-tolerance is not usually
present. α2-Agonist-mediated analgesia is
not reversed by opioid antagonists.
 Sedation.
1. Ruminants are most sensitive to α2-agonists, followed by cats, dogs,
and horses. Pigs are least sensitive to α2-agonists in domestic animals.
2. High doses of α2-agonists may induce CNS excitation, which is
attributable to activation of α1-receptors
Skeletal muscle relaxation
α2-Agonists produce skeletal muscle relaxation by inhibiting
intraneuronal transmission of impulses in the CNS.
Emesis. It is induced in carnivores and omnivores, and is commonly
seen in the cat, and less frequently in the dog.
Cardiovascular effects
1. Bradycardia,
2. hypertension is due to activation of the postsynaptic α2-receptors of
vascular smooth muscle.
3. hypotension is caused by reduced norepinephrine release by the
sympathetic nerve at the vascular smooth muscle
4. Bradycardia (with or without sinus arrhythmia) is due to decreased
norepinephrine release to the myocardium, particularly the SA node. An
increase in baroreceptor reflex during hypertension
Renal effects. α2-Agonists induce diuresis through inhibiting
vasopressin release
Respiratory effects. α2-Agonists cause hypoxemia
 Neuroendocrine effects. α2-Agonists inhibit
sympathoadrenal outflow and decrease
the release of norepinephrine and epinephrine.
(1) α2-Agonists inhibit insulin release; this effect
is very pronounced in ruminants,
which results in a moderate to severe
hyperglycemia lasting up to
24 hours.
(2) α2-Agonists increase growth hormone release
by inhibiting somatostatin release from the
hypothalamus and stimulating growth hormone—
stimulating hormone release from the median
eminence. The α2-agonist-induced growth
hormone release is not sustained; consecutive
daily drug administration can only maintain
increased secretion for