SKM Relaxants PDF

Summary

This document describes neuromuscular blockers and skeletal muscle relaxants, including their uses and mechanisms of action. It details different types of drugs and their classifications, along with specifics on their effects and uses.

Full Transcript

Neuromuscular blockers
SKELETAL MUSCLE
RELAXANTS

Learning Objectives
•

Explain Neuromuscular junction: NMJ

•

Describe Two types of skeletal muscle relaxants and
their subtypes:

–
•
•

Neuromuscular blockers
Non-depolarizing (Competitive) blockers
Depolarizing blockers

–

Spasmolytic Drugs

•
•

Centrally Acting
Directly-Acting

•

Enumerate Drugs for Acute Muscle Spasm

Two Types of Drugs
•
–
–

•
–
–
–

Neuromuscular blockers:
Interfere with transmission at the neuromuscular end
plate
Uses: surgical procedures, ICU, GA - tracheal
intubation

Spasmolytics:
Traditionally called “centrally acting” muscle
relaxants
reduces spasticity in a variety of painful conditions
Uses: chronic back pain, painful fibromyalgias

Neuromuscular junction

Nicotinic Ach receptor: nAChR

Skeletal muscle relaxation and paralysis
•

By interruption at several sites: the pathway
from the central nervous system (CNS) to:

–
–
–
–
–
–

myelinated somatic nerves
unmyelinated motor nerve terminals
nicotinic acetylcholine receptors
motor end plate
muscle membrane and
intracellular muscular contractile apparatus

NMJ blockade
•
•
–

Blockade of end plate function: by two basic
mechanismsPharmacologic blockade:

–

Antagonist or NM blocking drugs: nondepolarizing
NM blocking drugs
Prototype of this class is d-tubocurarine

•

The second type of blockade: Depolarizing type

–
–

An excess of a depolarizing agonist: such as
acetylcholine
Prototype of this class is succinylcholine

NM blocking agents: Classification
•

Non-depolarizing (Competitive) blockers:

•

Depolarizing blockers:

–
–
–
–

Long acting: d-Tubocurarine, Pancuronium
Intermediate acting: Atracurium, Rocuronium
Short acting: Mivacurium
Succinylcholine, Decamethonium

0

NM blockers: end plate channel

Depolarizing Blocker
•
–

•
–
•

–
•

Neuromuscular block by over stimulation:
so that the end plate is unable to respond to further
stimulation

Two sequential events:
Phase 1(depolarization block):
Maintained depolarization produces Na channel
inactivation(so no repolarisation of next generation of
action potentials)

Phase 2 (desensitization block):
Block is due to desensitization of Ach Receptors

Depolarizing Blocker_2
•

–
–
–
–

–

Succinylcholine:

More effect on NMJ and
less on autonomic ganglia

Releases histamine from mast cells
Anticholinesterase: do not reverse the paralysis

in Phase I
may prolong the block

Depolarizing Blocker_3
•

Order of paralysis:

•
•

Used for short term procedures
ADRs:

–

–
–
–

Neck, limbs
respiratory

face, jaws, eyes

Respiratory paralysis
Hyperkalemia
Malignant hyperthermia

pharynx

trunk

Nondepolarizing Blockers
•

Mechanism of Action

•

Block can be reversed by anti-AChE agents

•

Order of paralysis:

–
–

–
–

Reversible competitive antagonists
these compounds have two charged heads (e.g., quaternary
ammonium) separated by a “thick” organic moiety (e.g.,
steroid nucleus)

Neostigmine, pyridostigmine
fingers, eyes

limbs

neck

face

trunk

respiratory

0

Nondepolarizing Blockers_2
•
•
•
•
–
–

•
•

Hypokalemia: potentiate their effects
New born are sensitive to these drugs
Myasthenia patients are also sensitive to paralysis
Adverse effects:
Bronchospasm
Hypotension

Inhalational anesthetics: Potentiation
Antibiotics: Aminoglycosides, tetracycline- enhances

Nondepolarizing Blockers_3
•

Pancuronium:

•

Atracurium:

•

Rocuronium:

•

Mivacurium:

–
–
–
–
–

5 times potent than d- tubocurarine.
Long onset - 2.9 min and DOA- 110 min

DOA – 45 min, good tolerable in kidney and liver
diseases
rapid onset- 1min and DOA - 55 min
onset 1.8 minutes, DOA - 20 minutes

Uses of Neuromuscular Blocking Drugs
•

Surgical Relaxation

•

Tracheal Intubation

•

Control of Ventilation

•

Treatment of Convulsions

Spasticity: Stretch Reflex Arc
Spinal injury
Cerebral palsy
Multiple
sclerosis
Stroke

Spasmolytic agents: MOA

Spasmolytic Drugs: Centrally Acting
•

Baclofen: Oral, intrathecal

–

GABAB agonist:

•

–

MOA: causes membrane hyper-polarization via increased
K+ conductance (cause presynaptic inhibition by reducing
calcium influx and reduces the release of excitatory
transmitter in both brain and spinal cord)

Decreases release:

•

–

Glutamate, substance P

Uses:

•

–
•

Severe spasticity-cerebral palsy, multiple sclerosis, stroke

S/E:
Sedation, muscleweakness

Spasmolytic Drugs: Centrally Acting_2
•

Diazepam:

–

MOA:

•
•

–
•
•

Facilitates GABAergic transmission in central nervous
system - central sedation
Increases interneuron inhibition of primary motor
afferents in spinal cord

Uses:
Chronic spasm due to cerebral palsy, stroke, spinal cord
injury
acute spasm due to muscle injury

Spasmolytic Drugs: Centrally Acting_3
•
–
•

–
•

–
•

Tizanidine
MOA: α2-Adrenoceptor agonist in the spinal cord
Re-inforces both presynaptic and postsynaptic inhibition of
reflex motor output

Uses:
Spasm due to multiple sclerosis, stroke, amyotrophic lateral
sclerosis

S/E:
Weakness, sedation, hypotension

Spasmolytic Drugs: Directly-Acting
•

Dantrolene:

–

MOA:

•
•

–
•
•

–

Blocks RyR1 Ca2+ release channels in the sarcoplasmic
reticulum of skeletal muscle
Reduces actin-myosin interaction - weakens in skeletal
muscle contraction

Uses:
IV: Malignant hyperthermia
Oral: Spasm due to cerebral palsy, spinal cord injury,
multiple sclerosis

S/E: Muscle weakness

Drugs for Acute Muscle Spasm
•
–
•
•

–
•

–
•

•

Cyclobenzaprine: by oral route
MOA:
act in the brain stem, possibly by interfering with
polysynaptic reflexes that maintain skeletal muscle tone
has marked sedative and antimuscarinic actions

S/E:
Confusion, visual hallucinations

Uses:
Acute spasm due to muscle injury, inflammation

Other drugs : Chlorphenesin

Notes