Muscle Relaxants BPS 337 PDF

Summary

This is a presentation of muscle relaxants, from BPS 337, 12/04/2023. It covers different types of muscle relaxants, their mechanisms of action, and clinical uses. It includes detailed information on both depolarizing and non-depolarizing agents, along with examples, chemical structures, and specific applications.

Full Transcript

Muscle Relaxants
BPS 337
12/04/2023
Richard T. Clements
Muscle Relaxants

Drugs that affect skeletal muscle
function fall into two groups:
(a) Neuromuscular blockers (NMJ)- used
in intensive care units to cause
paralysis and as an adjunctive to
anesthesia

(b) Spasmolytics- used to reduce
spasticity in a variety of neurologic
disorders
Neuro-
muscular
Junction
(NMJ)
The nicotinic receptor in
muscle tissue is different
from the neuronal nicotinic
receptor
NMJ Nicotinic receptor
 NMJ Nicotinic receptor

The difference in subunit composition between the
NMJ nicotinic receptor and the neuronal nicotinic
receptor provides for differential specificity to
agonists and antagonist when compared to the
neuronal nicotinic receptor.
NMJ nicotinic agonists include acetylcholine and
succinylcholine.
NMJ nicotinic antagonists include α-bungarotoxin
and d-tubocurarine.
Stimulation of the receptor causes an excitatory
postsynaptic potential (EPSP) which involves
opening the AchR receptor channel to Na+ and Ca+
+ ions
NMJ Blockers
They are used for:

relax skeletal
muscles during
surgery
reduce the intensity
of muscle spasms in
electrically-induced
convulsions
manage patients who
are fighting
mechanical
ventilation
 NMJ Blockers

Nondepolarizing agents- curare alkaloids such as
tubocurarine, pancuronium bromide,
pipecuronium, and vecuronium.
Block neurotransmitter action of acetylcholine.
Anesthesia is induced before neuromuscular
blockade is started.

Depolarizing agents (succinylcholine)
cause excessive depolarization which desensitizes
muscles and renders them unresponsive

Neither cross the blood–brain barrier and have
no action on the CNS.
The first NMJ blocking agent was D-
Tubocurarine
Uses of Neuromuscular Blocking
Agents
 Facilitate intubation
 Surgery
 Enhanced ventilator synchrony
 Reduce intracranial pressure (ICP)
 Reduce oxygen consumption
 Terminate status epilepticus and tetanus
 Neuromuscular Blocking Agents
(NMBA’s)
Depolarizing Non-depolarizing
Competitive antagonists of ACh at the
Depolarizes the nicotinic
postsynaptic nicotinic receptors on
receptor of the skeletal the skeletal muscle fibers
muscle fiber similar to
Acetylcholine (2) groups:
Succinylcholine Benzylisoquinoloniums:
The only depolarizing Atracurium
agent being used in clinical Cisatracurium
practice Mivacurium
Rapid onset, rapid
elimination Aminosteroidals:
Malignant hyperthermia Pancuronium
trigger, hyperkalemia, Vecuronium
increase in ICP Rocuronium
Depolarizing NMJ blocker

Succinylcholine consists of two molecules of joined Ach.
Short half life-metabolized by plasma cholinesterase.
Hyperkalemia is an issue.- K+ is lost from skeletal
muscle into the blood.
For this reason, succinylcholine is considered
contraindicated in the routine management of children
and adolescents because of the risk of hyperkalemia,
rhabdomyolysis, and cardiac arrest in children with
undiagnosed myopathies.
 Phases of Depolarizing NMBA’s

Phase I: Membrane is
depolarized by opening
the ACh channels causing
a brief period of
fasciculation (brief
spontaneous muscle
contraction)
Phase II: End plate
eventually repolarizes,
however succinylcholine
is not metabolized like
ACh, it continues to
occupy the ACh receptor
to “desensitize” the end
plate
Non-depolarizing NMJ Blockers

Competitive antagonists of AchR on skeletal muscle.
These have longer half-lives than succinylcholine and
take longer for their onset of action.
Rocuronium (0.9-1.2 mg/kg) has an onset of action that
approaches succinylcholine (60-90 s), making it a
suitable alternative for rapid-sequence inductions
Metabolism and excretion can be an issue with some
compounds leading to longer half-life
Effects can be reversed by administration of Ach
cholinesterase inhibitors…
Structures of various NMBA’s
Types of Neuromuscular
Blocking Agents
Duration of Action
 Non-depolarizing drugs PK

Must be given parenterally
Metabolized in the liver and excreted by
the kidneys
Mivacurium is metabolized by pseudo
cholinesterase
Atracurium is broken down spontaneously
by a Hoffman elimination reaction
 atracurium may be used in organ failure
Drug that potentiate non-
depolarizing neuromuscular
blocking agents
Corticosteroids
Aminoglycoside antibiotics
Tetracycline
Calcium channel blockers
Class IA antiarrhythmic drugs
Furosemide
Cholinesterases
degrade Ach
 Reversal of NMJ
Blockade

With succinylcholine just wait- rapidly
metabolized

Non-depolarizing NMBs may be partially
reversed with cholinesterase inhibitors such as
neostigmine, physostigmine, pyridostigmine,
and edrophonium

Sugammadex is an alternative: a cyclodextrin
that chelates the aminosteroidals
Sugamaddex mechanism continued
 Summary / Things to know

Understand the difference in action of
depolarizing and non-depolarizing agents:
Non-depolarizing are competitive blockers of nAchR
Depolarizing (succinylcholine) is a potent activator of
Ach
Understand how this blocks Ach signals at the NMJ
NMJ structure and mechanism of signal
transmission
How Sugammadex reverses NMJ blockade by
specific non-depolarizing NMBA
How nAchR differs from other nAchR
Presence of gamma and delta subunits
 Spasticity
 Increase in tonic stretch reflexes
 Increased flexor muscle spasm
 Muscle weakness
 Reflex arc involvement
 Higher center involvement
("upper motor neuron disease")
affects descending pathways
leading to alpha motor neurons
hyper-excitability
 Spasmolytics- these are
skeletal muscle relaxing agents
that relieve acute
musculoskeletal pain, spasm or
spasticity
Centrally active
“Spasmolytic” agents
These include carisoprodol, diazepam
and baclofen

Diazepam (a benzodiazepine)- is
effective for both acute spasms and
chronic spasticity.
Anti-spasmolytic effect in part due to
action in the spinal cord {effective in
patients with cord transection}
Also causes sedation
Diazepam
Diazepam (a benzodiazepine)- is effective
for both acute spasms and chronic
spasticity.
Anti-spasmolytic effect in part due to
action in the spinal cord {effective in
patients with cord transection}
Also causes sedation
 Mechanism of action of
diazepam
Diazepam
/benzodiazepines

1.GABA activates Cl-
channels on post-
synaptic neurons
2.This inhibits
depolarization and
nerve transmission
3.Benzodiazepines
increase the Cl-
conductance through
these channels
4.Limits nerve
transmission to muscle
Benzodiazepines’ indications

Benzodiazepines possess psycholeptic,
sedative, hypnotic, anxiolytic,
anticonvulsant, muscle relaxant, and
amnesic actions, which are useful in a
variety of indications including:
Anxiety disorders
Seizures
Muscle spasms
Sedation
Carisoprodol
 Carisoprodol (Soma)- alters interneuron
activity in the spinal cord and of the
descending reticular formation, located in
the brain.

 It is a GABAergic drug which is rapidly converted
to meprobamate which is a sedative-hypnotic.

 This stimulates GABA receptors on neurons
 GABA receptors are inhibitory and blocks
neurotransmission
 Schedule IV controlled substance and can have
abuse/dependence
 Exact mechanism of GABA receptor stimulation unclear
 Baclofen
Orally active GABA mimetic which acts
as a GABA agonist at GABA-B
receptors
GABA-B receptors are G-protein
coupled receptors which hyperpolarize
neurons by decreasing calcium
conductance (inhibitory)
Baclofen works at the spinal level to
reduce reflexes
Activation of GABA-B receptors in the
brain by Baclofen results in
hyperpolarization of neurons in the
brain and cord to decrease the release
of excitatory neurotransmitters
Decreases the frequency and degree
of muscle spasms and reduces muscle
tone
Baclofen

It is the drug of choice because it produces less
sedation than diazepam and less peripheral
muscle weakness than dantrolene.
Used for paraplegic or quadraplegic patients
with spinal cord lesions caused by either
multiple sclerosis or trauma.
Intrathecal Baclofen use for management of
severe spasticity/pain when nonresponsive to
medication by other routes of administration
Spasmolytics (Peripheral)
Dantrolene- has similar effects to other central drugs but it works directly on the
muscle by inhibiting calcium release.

Lessens excitation-contraction coupling in muscle cells.

Most effective for spasticity with cerebral origin (multiple sclerosis, cerebral
palsy).

Also used in malignant hyperthermia and NMS (neuroleptic malignant syndrome).
Excitation- Contraction coupling in
Skeletal Muscle
Calcium-induced calcium release (CICR)
is a biological process where calcium is able
to activate calcium release from intracellular
Ca2+ stores (sarcoplasmic reticulum)
Depolarization initiates calcium influx by
voltage dependent calcium channels (VDCC)
also known as dihydropyridine receptors in
SkM
This initiates CICR via the ryanodine
receptors(RyR1, heart is RyR2) which are
voltage gated calcium channels on the
sarcoplasmic reticulum membrane.
Dantrolene- A ryanodine receptor
antagonist used in malignant
hyperthermia and spastic
disorders
Malignant hyperthermia
 Summary: Things to know.

Mechanism of action of
Diazapam: Blocks muscle stimulation by
increasing Cl- influx of GABA receptors. (not an
agonist)
Clarisoprodol: promotes GABA activity in
neurons.
Baclofen: is a GABA agonist.
Dantrolene: inhibits Ca++ release of RyR1
(skeletal muscle) to inhibit contraction
Mechanism of skeletal muscle Ca++ release:
Very similar to heart – but RyR1 and different
Ca++ channels with very similar mechanism