Corrected_Final_20231106_Glutamatergic and GABAergic Neurotransmission_Sedatives_Hypnotics.pdf

Transcript

Pharmacology
Iva D. Tzvetanova, Ph.D.
Office Hours: Currently by appointment
Email: [email protected]

Link to Office Hours Booking:
https://outlook.office365.com/owa/calendar/[email protected]/bookings/

Your Attendance is MANDATORY

How did you do in the MD310 Midterm
Exam?

F2023 – Midterm Exam Results

PD Treatment Summary

Simmons Pharmacology: An Illustrated Review;
Katzung’s Basic & Clinical Pharmacology

Levodopa
Levodopa i.e. l-3,4-dihydroxyphenylalanine (l-dopa)
Drug interactions
 Pyridoxine
 Form of vitamin B6 found in multivitamins
 Cofactor for dopa decarboxylase
➔ May enhance the metabolism of l-DOPA
Antipsychotics
 Antagonists of dopamine receptors
➔Contraindicated with l-DOPA
 Reserpine
 Depletes dopamine
➔ Contraindicated
 Monoamine oxidase inhibitors (MAOIs)
 Block dopamine breakdown
➔ May exaggerate effects (hypertensive crisis and hyperpyrexia)
➔ MAOIs should be withdrawn at least 2 weeks prior to l-DOPA
administration
 Anticholinergics - may slow gastric emptying
Lippincott Illustrated Reviews: Pharmacology, 7th Edition

Levodopa
Levodopa i.e. l-3,4-dihydroxyphenylalanine (l-dopa)
Contraindications
Care must be exercised in patients with:
 Heart disease
 Cerebrovascular disease
 Neurological disease

Combination Therapy Aimed at Increasing
Dopamine Synthesis
L-DOPA ➔  dopamine synthesis
BUT
l-DOPA can be degraded in the
periphery by AAAD

➔ co-administer Carbidopa
BBB

- Carbidopa – does NOT cross
BUT inhibits AAAD

➔ more l-DOPA can reach the brain

BUT

Katzung’s Basic & Clinical Pharmacology, 13th edition

Combination Therapy Aimed at Increasing
Dopamine Synthesis
L-DOPA ➔  dopamine synthesis
BUT
l-DOPA can be degraded in the
periphery by AAAD

➔ co-administer Carbidopa
BBB

- Carbidopa – does NOT cross
BUT inhibits AAAD

➔ more l-DOPA can reach the brain
BUT
l-DOPA can be degraded by COMT in
the periphery

Brody’s Human Pharmacology

Summary of Drugs Used for the Treatment of
Parkinson’s Disease

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Drugs Used for the Treatment of
Parkinson’s Disease

Katzung’s Basic & Clinical Pharmacology, 13th edition

We have so many drugs to treat
Parkinson’s
BUT
Why is there still a problem?

Disease Still Progresses

We have so many drugs to treat
Parkinson’s
BUT
Why is there still a problem?

On- off phenomenon with dopamine
supplementation therapy

• Levodopa & dopamine agonists
– improve & control motor symptoms for several years

BUT
• After an initial «honeymoon period» - i.e. when it works well
– patients develop multiple problems:
• such as lack of response, fluctuating response or dyskinesia
• "off” period = decreased mobility
• "on” period = medication is working & symptoms are
controlled
• 40 % of patients will experience motor fluctuations within 46 years of onset,
–  by 10 % per year after that.

On- off phenomenon with dopamine
supplementation therapy

• Goal
–  "off" time as much as possible
– Make “off” time as predictable as possible
– treat it with as little medication as possible (so as to avoid side
effects such as psychosis & dyskinesia)

On- off phenomenon with dopamine
supplementation therapy

• Dopamine supplementation therapy – does not address all symptoms
• Also Side effects
– Sensory symptoms (e.g. pain, fatigue, and motor restlessness)
– Autonomic symptoms (e.g. urinary incontinence & profuse
sweats)
– Psychiatric disorders (e.g. depression, anxiety & psychosis
• It may even aggravate the neuropsychiatric disturbances
• Neurodegeneration persists

Other Movement Disorders
•

Huntington’s disease: an inherited adult-onset neurodegenerative disorder
characterized by dementia & bizarre involuntary movements. Neuronal loss
in projection neurons in the dorsal striatum.

•

Tourette’s syndrome: a neurologic disease of unknown cause that presents
with multiple tics associated with snorting, sniffing, and involuntary
vocalizations (often obscene)

•

Wilson’s disease: an inherited (autosomal recessive) disorder of copper
accumulation in liver, brain, kidneys, and eyes; symptoms include jaundice,
vomiting, tremors, muscle weakness, stiff movements, liver failure, and
dementia

Katzung’s Basic & Clinical Pharmacology, 13th edition

Parkinson’s Disease – the Essentials

See You Tomorrow

Connolly & Lang JAMA 2014

Pharmacology of the Central
Nervous System
Glutamatergic and GABAergic Neurotransmission
+ Sedative & Hypnotic Drugs

GABAergic and Glutamatergic
Neurotransmission
GABA = γ-aminobutyric acid
GABA = 1° inhibitory neurotransmitter in the CNS
Glutamate = 1° excitatory neurotransmitter in the CNS

Simplified View of the Effects of Excitatory
and Inhibitory Neurotransmitters
Excitatory - Glutamate

Note: Both
neurotransmitters bind to
metabotropic receptors as
well

Influx +vely
charged ions

Influx –vely
charged ions

Reduced efflux
of +vely
charged ions

Efflux +vely
charged ions

Depolarize the membrane
K+ channel closed
➔ Membrane resistance
➔responsiveness to excitatory current

Inhibitory - GABA

Hyperpolarize the membrane
Membrane resistance – shunting
➔responsiveness
to excitatory current

STUDY HELP

CNS –
Neurotransmitter
Receptors and
Effectors

Simmons Pharmacology: An
Illustrated Review

A Single Neuron Receives Multiple Inputs

Katzung’s Basic & Clinical Pharmacology, 13th edition

A Single Neuron Receives Multiple Inputs
Long-tract neurons
can participate in
convergent and
divergent signaling

Local circuits consist
of excitatory and
inhibitory neurons
layered in complicated
structural motifs

Single-source
divergent neurons

relay information to a
multitude of brain areas
and hundreds of neurons

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

A Single Neuron Receives Multiple Inputs

E = excitatory
e.g. glutamate
I = inhibitory
e.g. GABA
Katzung’s Basic & Clinical Pharmacology, 13th edition

Let’s Start with γ-aminobutyric acid
(GABA)

Why is GABAergic Neurotransmission
an Important Pharmacological Target?
• Pharmacological modulation of GABAegic neurotransmission affects:
• Arousal and attention
• Memory formation
• Anxiety
• Sleep
• Muscle tone
• Treatment of focal or widespread neuronal hyperactivity
observed in
• Epilepsy

Let’s Start with γ-aminobutyric acid
(GABA)
Well we cannot REALLY

Neuronal Communication – the Basics
Presynaptic action potential arrives
Ca2+ influx into the presynaptic terminal
Neurotransmitter is released into the
synaptic cleft
Neurotransmitter binds to receptor on the
postsynaptic cell
Transduction of the message
+ integration of signals from
multiple inputs
Response

Reconstruction of docked vesicles
Courtesy of Ben Cooper (MPIEM)

Neurotransmitter is
degraded/recycled

➔ Response can be terminated

How is GABA Synthesized?

From Glutamate
GABA and Glutamate Synthesis and Metabolism are
Intertwined

Neuronal Communication – the Basics
Presynaptic action potential arrives
Ca2+ influx into the presynaptic terminal
Neurotransmitter is released into the
synaptic cleft
Neurotransmitter binds to receptor on the
postsynaptic cell
Transduction of the message
+ integration of signals from
multiple inputs
Response

Reconstruction of docked vesicles
Courtesy of Ben Cooper (MPIEM)

Neurotransmitter is
degraded/recycled

➔ Response can be terminated

Neurons Actually Rarely Work Alone

Katzung’s Basic & Clinical Pharmacology, 13th edition

Glutamate Degradation Involves
Astrocytes

Katzung’s Basic & Clinical Pharmacology, 13th edition

Glutamate Degradation Involves Astrocytes – a
Word About the Tripartite Synapse
Glutamate in the cleft

Glial glutamate transporters
take up glutamate

Glial glutamine synthetase
breaks glutamate to glutamine

Glutamine is transferred to
the presynaptic neuron

Glutamate can also be taken up
into the presynaptic neuron
directly

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Astrocytes Supply Glutamine to GABAergic
and Glutamatergic Neurons

Figure is on the next slide

Simmons Pharmacology: An
Illustrated Review

GABA Synthesis and Metabolism

GABA-T
= GABA transaminase
Converts α-ketogluterate to
glutamate

GAD
= Glutamic Acid Decarboxylase
Converts glutamate to GABA in
GABAergic neurons

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

GABA Synthesis and Metabolism

GABA-T
= GABA transaminase (mitochondrial)

Also degrades GABA

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

GABA Synthesis and Metabolism

Simmons Pharmacology: An Illustrated Review

Simmons Pharmacology: An
Illustrated Review

How Do We Terminate the Action of
GABA?
By removing of GABA from the synaptic cleft via uptake
transporters in astrocytes and presynaptic neurons

What are the transporters called?
GABA transporters (GATs)

Pharmacological Agents Regulating GABA
Metabolism and Transport

These drugs are mostly used for experimental purposes, but not only

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Neuronal Communication – the Basics
Presynaptic action potential arrives
Ca2+ influx into the presynaptic terminal
Neurotransmitter is released into the
synaptic cleft
Neurotransmitter binds to receptor on the
postsynaptic cell
Transduction of the message
+ integration of signals from
multiple inputs
Response

Reconstruction of docked vesicles
Courtesy of Ben Cooper (MPIEM)

Neurotransmitter is
degraded/recycled

➔ Response can be terminated

GABA Receptors
Clinically useful drugs target these

STUDY HELP

CNS –
Neurotransmitter
Receptors and
Effectors

Simmons Pharmacology: An
Illustrated Review

STUDY HELP

CNS – Neurotransmitter Receptors and Effectors

Simmons Pharmacology: An Illustrated Review

The other GABAergic Receptor
The GABAB receptor is a G-protein coupled receptor

Activation leads to inhibition of adenylyl cyclase ➔ cAMP
Opening of K+ channels – βγ subunits
Closing of Ca2+ channels – βγ subunits
Clinically usefull drug – baclofen
Agonist ➔ muscle relaxant
Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

GABAA and GABAC Receptors:
The Ionotropic GABA Receptors

The Ionotropic GABA Receptors
GABAA receptor = chloride ion channel
 Complex consists of five or more membranespanning subunits

 Multiple forms of α, β, and γ subunits are
arranged in different pentameric
combinations
➔ GABAA receptors exhibit molecular
heterogeneity

 GABA interacts at two sites between the α
and β subunits

Golan, Armstrong & Armstrong Principles of
Pharmacology: The Pathophysiologic Basis of Drug
Therapy; Katzung’s Basic & Clinical Pharmacology

The Ionotropic GABA Receptors
GABA secreted in the cleft
GABA binds ionotropic receptor

Channel opens
Cl- enters the postsynaptic neuron
Postsynaptic membrane is hyperpolarized
 Responsiveness to excitatory current

Simmons Pharmacology: An Illustrated Review

Binding Sites
of Some
GABAA Receptor
Summary
of GABA
Pharmacotherapeutics
A
Modulators

Brody’s Human Pharmacology

Summary of GABAA Pharmacotherapeutics

BUT increased of GABA receptor activity can lead to:
 Sedation, Hypnosis, Anesthesia, Amnesia (some), Convulsant and Anticonvulsant
effects, Muscle Relaxation, Anxiolytic effects (impaired judgment, euphoria and loss of
self control – at doses used for anxiolytic effects due to disinhibition), Depress respiration (if
patient has pulmonary disease)

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Clinical Uses of Sedative and Hypnotic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

GABAA Modulators = Barbiturates and
Benzodiazepines
the Major Classes of Anxiolytic and Sedative-Hypnotic
Drugs

Binding Sites of Some GABAA Receptor
Modulators

Most drugs that act on GABAA receptors bind allosterically
Barbiturates and benzodiazepines are positive modulators of GABAA receptor
function.

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors
Both enhance GABAA receptor activation
BUT binding sites, potencies and efficacies are different

Midazolam – benzodiazepine
Phenobarbital - barbiturate
Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors
Both enhance GABAA receptor activation
BUT binding sites, potencies and efficacies are different

What is the mechanism of action of these drugs?
Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

GABAA Modulators Vary in their Duration of Action

FIX
Trevor & Katzung’s Pharmacology Examination and Board Review, 9th edition

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors

Benzodiazepines
•
•
•
•

•

Allosteric binding site
Potentiate Cl- flow
Many have active metabolites
Almost exclusively act on the
CNS
• v. high doses – NMJ block
• Some after IV injection
➔coronary vasodilation
ONLY facilitate effects of
endogenous GABA
➔higher therapeutic index
than barbiturates

Brody’s Human Pharmacology

Benzodiazepines

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Benzodiazepines Metabolism and Excretion

* - active metabolite
Brody’s Human Pharmacology

Benzodiazepines – Duration of Action

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Duration of Action Can Predict the Likelihood of
Withdrawal Effects of Benzodiazepines

Short t1/2
Intermediate t1/2
Long t1/2

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Duration of Action and
Clinical Applications of Some
Benzodiazepines

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors

Barbiturates
Allosteric binding site – within channel
Increase the conductance of GABAA to
chloride ions
• ALSO DIRECT GABAlike effects (partial
agonists)
• Inducers of CYP450
• Also affect own metabolism
• Induce the rate-limiting step of heme
biosynthesis
➔ Contraindicated in porphyria patients or
those with family history of porphyria
➔ ALSO DIRECT GABAlike effects (partial
agonists)
➔lower therapeutic index than
benzodiazepines – PROBLEM OVERDOSE
•
•

Brody’s Human Pharmacology

Barbiturates Also Bind to AMPA/Kainate
Glutamatergic Receptors
Do you think that barbiturates
INCREASE or DECREASE AMPA
receptor activity?
Barbiturates INHIBIT AMPA receptors


Inhibit the activation of a major excitatory
receptor


Additional mechanism of suppressed neuronal
excitability

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Duration of Action
and Clinical
Applications of
Some Barbiturates

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Adverse Effects of Barbiturates

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

To Summarize

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors

Benzodiazepines
•
•
•
•

•

Allosteric binding site
Potentiate Cl- flow
Many have active metabolites
Almost exclusively act on the
CNS
• v. high doses – NMJ block
• Some after IV injection
➔coronary vasodilation
ONLY facilitate effects of
endogenous GABA
➔higher therapeutic index
than barbiturates

Barbiturates
Allosteric binding site – within channel
Increase the conductance of GABAA to
chloride ions
• ALSO DIRECT GABAlike effects (partial
agonists)
• Inducers of CYP450
• Also affect own metabolism
• Induce the rate-limiting step of heme
biosynthesis
➔ Contraindicated in porphyria patients or
those with family history of porphyria
➔ ALSO DIRECT GABAlike effects (partial
agonists)
➔lower therapeutic index than
benzodiazepines – PROBLEM OVERDOSE
•
•

GABAA Modulators Vary in their Duration of Action

FIX
Trevor & Katzung’s Pharmacology Examination and Board Review, 9th edition

Clinical Uses of Sedative and Hypnotic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Sedatives and Hypnotic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

Newer Hypnotics – Similar to Benzodiazepines in
Increasing Membrane Hyperpolarization

Katzung’s Basic & Clinical Pharmacology, 13th edition

Drug Overdose is a Problem BUT There is an
Antagonist to Benzodiazepine Action

Flumazenil is NOT a sedative hypnotic

Katzung’s Basic & Clinical Pharmacology, 13th edition

Sedatives and Hypnotics that DO NOT
Act on GABA Receptors

Melatonin Receptor Agonists
Key Points for Role of Melatonin in
Promoting Sleep
• Melatonin synthesis
• Inhibited by light
• Promoted by darkness
• Melatonin binds to melatonin
receptors (MT1, MT2)
• MT receptors
• G-protein coupled (Gi/o)
• Activation ➔  cAMP
• Receptor functions
• MT1 -  neuronal firing ➔
promote sleep
• MT2 – circadian rhythm
control

An Orexin Receptor Antagonist - Sevorexant

•
•
•
•

Key Points for Role of Orexins in Sleep Control
Orexins = neuropeptides
• Secretion is HIGH in states of wakefulness and arousal
Orexins bind to orexin receptors (OX1, OX2)
OX receptors
• G-protein coupled (Gq/11)
• Activation ➔  PLC activity ➔ Ca2+ in cytosol ➔  neuronal activity
Orexin functions
•  arousal, vigilance
BUT also appetite control, reward, addictive behavior (suggested)

Brody’s Human Pharmacology

An Orexin Receptor Antagonist - Sevorexant

•

•
•
•

Key Points for Role of Orexins in Sleep Control
Orexins - neuropeptides
• Inhibited by light
• Promoted by darkness
Orexins bind to orexin receptors (OX1, OX2)
OX receptors
• G-protein coupled (Gq/11)
• Activation ➔  PLC activity ➔ Ca2+ in cytosol ➔  neuronal activity
Orexin functions
•  arousal, vigilance
BUT also appetite control, reward, addictive behavior (suggested)

Katzung’s Basic & Clinical Pharmacology, 13th edition

Sedatives and Hypnotics that DO NOT Act on
GABA Receptors

Katzung’s Basic & Clinical Pharmacology, 13th edition

Preview – Antiepileptic Drugs

Simmons Pharmacology: An Illustrated Review

Break

GABA Receptors
Clinically useful drugs target these

Where do benzodiazepines bind on GABAA and how do
they modulate GABA-induced receptor activity?

Benzodiazepines ➔ Positive Allosteric
Modulation of GABAA Receptors

GABA bound

Channel opens

GABA +
benzodiazepine bound

 Frequency of
channel opening

benzodiazepine
bound

channel not
affected
Stahl’s, 4th Edition

GABAA-Mediated Inhibition is Actually of Two Types
Phasic
= occurs in bursts
triggered by synaptic
increase of GABA release
 synapse
 GABAA – with α + γ
subunits
➔ Benzodiazepines can
bind
Tonic
= receptors capture
GABA that has diffused
away from synapse
 extra synaptic
 GABAA – with α + δ
subunits
➔ Benzodiazepines
CANNOT bind
Stahl’s, 4th Edition

GABA Receptors
Clinically useful drugs target these

Where do barbiturates bind on GABAA and how do they
modulate GABA-induced receptor activity?

Bind allosterically + keep channel open longer

Why is GABAergic Neurotransmission
an Important Pharmacological Target?
• Pharmacological modulation of GABAegic neurotransmission affects:
• Arousal and attention
• Memory formation
• Anxiety
• Sleep
• Muscle tone
• Treatment of focal or widespread neuronal hyperactivity
observed in
• Epilepsy

Effects of Benzodiazepines and Barbiturates
on GABAA Receptors

Benzodiazepines
•
•
•
•

•

Allosteric binding site
Potentiate Cl- flow
Many have active metabolites
Almost exclusively act on the
CNS
• v. high doses – NMJ block
• Some after IV injection
➔coronary vasodilation
ONLY facilitate effects of
endogenous GABA
➔higher therapeutic index
than barbiturates

Barbiturates
Allosteric binding site – within channel
Increase the conductance of GABAA to
chloride ions
• ALSO DIRECT GABAlike effects (partial
agonists)
• Inducers of CYP450
• Also affect own metabolism
• Induce the rate-limiting step of heme
biosynthesis
➔ Contraindicated in porphyria patients or
those with family history of porphyria
➔ ALSO DIRECT GABAlike effects (partial
agonists)
➔lower therapeutic index than
benzodiazepines – PROBLEM OVERDOSE
•
•

Summary of Sedatives and Hypnotic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

End of Small Recap

Pharmacology of the Central
Nervous System
Treatment of Epilepsy

Epilepsy and Seizures
• Cause - often unclear

• Can also develop as a result of brain damage after:
• Stroke
• Trauma

• Infection
• Tumor growth

Epilepsy and Seizures
• Epilepsy
•

•

Group of chronic CNS disorders

Abnormal discharges of CNS neurons
•

Discharge may have NO clinical manifestations

•

Can be focally limited or encompass the whole brain

•

Status epilepticus = prolonged seizures (>30min) or multiple seizures
in succession without recovery of consciousness
•

Medical emergency – can lead to brain damage and even death

•

Treatment
• Maintaining open airway
• Provide oxygen
• Glucose as a bolus
• IV emulsion of diazepam (or rectal)

Misdiagnosis and wrong medication can make seizures
worse

Types of Seizures

Classification is not based on etiology but mostly on clinical manifestations
Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Pathways of Seizure Propagation
Focal seizure
If affected region activity:
 Confined to a cortical region serving a
basic function e.g. motor or sensory
+ No change in the patient’s mental status
➔focal seizure without altered awareness.
BUT
 Serves complex function e.g. cognitive,
linguistic etc
➔ focal seizures with altered awareness

Partial seizures can evolve to to generalized tonic-clonic

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Pathways of Seizure Propagation
Focal seizure
If affected region activity:
 Confined to a cortical region serving a
basic function e.g. motor or sensory
+ No change in the patient’s mental status
➔focal seizure without altered awareness.
BUT
 Serves complex function e.g. cognitive,
linguistic etc
➔ focal seizures with altered awareness

Partial seizures can evolve to to generalized tonic-clonic
Secondary generalized seizure
 Begins in a focus
BUT
 Paroxismal activity spreads to
subcortical areas
➔ Spread of activity to both
hemispheres is synchronized by diffuse
connections from the thalamus
Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Generalized Seizures Can Also be of Primary Origin

Primary generalized seizures (e.g. absence seizures)
 Etiology
 Abnormal synchronization between thalamic and cortical cells
Or
 Abnormal activity in neuronal networks that rapidly involve the bilateral
hemispheres

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Epilepsy = disease of abnormal neuronal
discharges
Rationale behind epileptic drugs
Inhibit abnormal neuronal discharges
➔ Prevent seizures from occurring

How can you inhibit abnormal discharges?
Hint:
GABA = 1° inhibitory neurotransmitter in the CNS
Glutamate = 1° excitatory neurotransmitter in the CNS

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause
Drugs that  GABA-mediated synaptic inhibition
• Positive modulators GABAA Receptors
•

Phenobarbital i.e. barbiturates

•

Benzodiazepines

• GABA mimetics e.g. progabide – GABAA agonist
• Increase GABA synthesis MAYBE
• Gabapentin – chemically related to GABA but not agonist to receptors –
hypothesis is that is promotes synthesis of GABA although it is not a
precursor of GABA

• Inhibit GABA degradation
•

i.e. inhibit GABA-T e.g. vigabatrin

• Inhibit GABA reuptake
•

i.e. inhibit GABA transporters (GATs) e.g. tiagabine

Antiseizure Drugs Acting at Inhibitory GABAergic Synapses

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs Aimed at Increasing
GABA-mediated synaptic inhibition

Simmons Pharmacology: An Illustrated Review

Epilepsy = disease of abnormal neuronal
discharges
Rationale behind epileptic drugs
Inhibit abnormal neuronal discharges
➔ Prevent seizures from occurring

How can you inhibit abnormal discharges?
Hint:

✔GABA = 1° inhibitory neurotransmitter in the CNS

Glutamate = 1° excitatory neurotransmitter in the CNS

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause
Drugs that  Glutamatergic Activity
• Inhibitors of glutamatergic receptors

• Felbamate – inhibits NMDA-type glutamate receptors
• Perampamel – inhibits AMPA-type glutamate receptors

Anticonvulsants Acting at Excitatory Glutamatergic
Synapses

Katzung’s Basic & Clinical Pharmacology, 13th edition

Epilepsy = disease of abnormal neuronal
discharges
Rationale behind epileptic drugs
Inhibit abnormal neuronal discharges
➔ Prevent seizures from occurring

How can you inhibit abnormal discharges?
Hint:

✔ GABA = 1° inhibitory neurotransmitter in the CNS
✔ Glutamate = 1° excitatory neurotransmitter in the CNS
Action potential propagation is dependent on….?

Voltage-gated Sodium Channels are Responsible for the
Upstroke of Action Potentials and thus Action Potential
Propagation

Golan, Armstrong & Armstrong Principles of Pharmacology: The Pathophysiologic Basis of Drug Therapy

Voltage-Gated Sodium Channels are Gated into
Open, Closed and Inactivated States

If we inhibit glutamate release
we will inhibit hyperexcitability
Katzung’s Basic & Clinical Pharmacology, 13th edition

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

Drugs that  excitability
• Inhibition of glutamate release – all about presynaptic Na+ channels
•

Phenobarbital – mechanism debated

•

Phenytoin – voltage-dependent Na+ channels – slows down their rate of
recovery from inactivation

•

Lamotrigine – inhibits voltage-dependent Na+ channels in a voltagedependent and use-dependent manner

Katzung’s Basic & Clinical Pharmacology, 13th edition

Block of Lamotrigine of Voltage-Gated Sodium Channels is
Voltage- and Use-Dependent

Katzung’s Basic & Clinical Pharmacology, 13th edition

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

Drugs that  excitability
• Inhibition of glutamate release – all about presynaptic Na+ channels
•

Phenobarbital – mechanism debated

•

Phenytoin – voltage-dependent Na+ channels – slows down their rate of
recovery from inactivation

•

Lamotrigine – inhibits voltage-dependent Na+ channels in a voltagedependent and use-dependent manner

• Inhibit action potential propagation – postsynaptic voltage-dependent
Na+ channels
• voltage-dependent Na+ channels – slow down their rate of
recovery from inactivation – inhibition of repetitive firing
• Phenytoin + fosphenytoin (prodrug that is quickly converted to
phenytoin in blood)

• Carbamazepine

Summary of Antiepileptic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

The Relationship between Phenytoin Dosage
and Plasma Concentration is NOT Linear

Lippincott Illustrated Reviews: Pharmacology, 7th Edition; Katzung’s Basic & Clinical Pharmacology, 13th edition

The Relationship between Phenytoin and Oral Gabapentin
Dosage and Plasma Concentration is NOT Linear
 Most anticonvulsants - follow linear
kinetics
BUT
 Phenytoin – metabolism gets
saturated with increased doses

➔ shift from 1st to 0 order
 Oral gabapentin – kinetics shift from
1st order to 0
BUT in the opposite direction
because transporter necessary for
absorption getting saturated

Katzung’s Basic & Clinical Pharmacology, 13th edition

Anticonvulsants Acting at Excitatory Glutamatergic
Synapses

Katzung’s Basic & Clinical Pharmacology, 13th edition

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

Drugs that  excitability
• Inhibition of glutamate release
• Limiting Depolarization of the Terminal
•

Inhibition of Ca2+ entry – gabapentin + pregabalin – bind an auxiliary
protein to voltage-gated Ca2+ channels ➔ inhibiting Ca2+ entry

•

Promoting repolarization – retigabine – a voltage-gated potassium
channel OPENER ➔ promotes K+ EXIT

• Inhibiting exocytosis of glutamatergic vesicles
•

Levetiracetam – binds a vesicular protein that promotes exocytosis
(SV2A) ➔ vesicular release is INHIBITED

Anticonvulsants Acting at Excitatory Glutamatergic
Synapses

Katzung’s Basic & Clinical Pharmacology, 13th edition

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

Drugs that  excitability
• Inhibition of T-type Ca2+ channels – i.e. inhibition of post-synaptic
depolarization
•

Ethosuxamide – suspected mode of action (actually unknown)

Summary of Antiepileptic Drugs

Simmons Pharmacology: An Illustrated Review

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

VALPROIC ACID (Divalproex = sodium valproate)
•  voltage-dependent Na+ channels

inactivation

•  GABA-dependent synaptic inhibition by
• blocking GABA-T (i.e. degradation)
• or activating GAD (i.e. synthesis)
• or by inhibiting GABA transporters (i.e. reuptake

• DEBATE
• Inhibits T-type Ca2+ channels
• Inhibits NMDA-receptor activation

Antiepileptic Drugs = Anticonvulsants
= Antiepileptic drugs aim to inhibit the abnormal neuronal discharge
rather than to correct the underlying cause

VALPROIC ACID (Divalproex = sodium valproate)
•  voltage-dependent Na+ channels

inactivation

•  GABA-dependent synaptic inhibition by
• blocking GABA-T (i.e. degradation)
• or activating GAD (i.e. synthesis)
• or by inhibiting GABA transporters (i.e. reuptake

• DEBATE
• Inhibits T-type Ca2+ channels
It is a potent inhibitor of histone deacetylase (HDAC)
➔changes the transcription of many genes
It also inhibits CYP2C9, UDP-glucuronosyltransferase, epoxide hydrolase
➔  Drug-drug interaction risk

In Utero Exposure to Valproate may Lead to
Cognitive Dysfunction

Lippincott Illustrated Reviews: Pharmacology, 7th Edition

Valproic Acid in NOT the Only Broad Spectrum Anticonvulsant

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs Aimed at Increasing
GABA-mediated synaptic inhibition

Simmons Pharmacology: An Illustrated Review

Summary of Antiepileptic Drugs Aimed at
Increasing GABA-Mediated Synaptic Inhibition

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs Aimed at
Increasing GABA-Mediated Synaptic Inhibition

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs Aimed at
Increasing GABA-Mediated Synaptic Inhibition

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs Aimed at
Increasing GABA-Mediated Synaptic Inhibition

Katzung’s Basic & Clinical Pharmacology, 13th edition

Anticonvulsants Acting at Excitatory Glutamatergic
Synapses

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary of Antiepileptic Drugs

Katzung’s Basic & Clinical Pharmacology, 13th edition

Summary
of Antiepileptic
DrugsDrugs
Summary
of Antiepileptic

Simmons Pharmacology: An Illustrated Review

Antiepileptic Drugs –
Metabolized by CYP450

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Adverse Effects of Antiepileptic Drugs

Lippincott Illustrated Reviews: Pharmacology, 6th Edition

Thank you