Neuromuscular Blockers PDF

Summary

This presentation discusses neuromuscular blockers, focusing on their mechanisms, types, and adverse effects. It includes information on depolarizing and non-depolarizing agents, as well as specific examples like succinylcholine and its implications for malignant hyperthermia. The presentation is a professional level resource.

Full Transcript

Neuromuscular
Blockers

Adegoke Adeniji RPh, PhD
Assoc. Professor, Pharm.
Sci.
1
 Objectives
Compare and contrast the mechanism of
action of a depolarizing neuromuscular
blocker (NMB) versus a non-depolarizing
neuromuscular blocker

Describe the role of NM receptors and
calcium in the contraction of muscle

Explain why there is a reversal drug for non-
depolarizing NMBs action but not for
 Neuromuscular Blockers
Used during surgical procedures to induce muscle
paralysis
– Adjuncts to general anesthesia
– Facilitation of intubation

Control of muscle contraction in status
epilepticus
– Continuous seizure lasting longer than 30mins
– Two or more seizure episodes without recovery of
consciousness

Peripherally acting agents
– Do not cross the blood-brain barrier
 History of NMB
16th century
– Curare : an alkaloid obtained from
plants
used as an arrow poison
– Killed animals by skeletal muscle
paralysis
How??
 Mechanism of Action of
NMB
Neuromuscular blockers bind and
modulate the activation of nicotinic
receptors located in the
neuromuscular junction (NM)

Types of NMBs
1. Non-depolarizing blockers
2. Depolarizing blockers
 Nicotinic Receptor
Subtypes
Nicotinic cholinergic receptors (N)
– Autonomic ganglia (NN / NG)
– Neuromuscular junction (NM)
Five subunits that are slightly different in
NN and NM

NM
NN
 N

N

N

N

N

M
 Drug Selectivity for Nicotinic
Receptors
1. Diversity in nicotinic receptor
composition allows for
pharmacological discrimination
between NM and NN

2. Site of action is determined by the
drug’s ability to reach the receptor
site
 The Neuromuscular

Junction
Under resting conditions, spontaneous low level
ACh release at the motor end plate
(neuromuscular jxn) results in:
– Miniature end-plate potential (MEPP)
Low change in membrane voltage
– Inadequate to generate an AP in skeletal muscle
Membrane potential does not reach the threshold potential

Arrival of action potential at the axon terminal
causes the release of large quantities of Ach and
results in large depolarization at the motor end
plate termed:
– End-plate potential (EPP)
 The Neuromuscular

Junction
The EPP is sufficient to generate an action
potential in the muscle cell which
ultimately results in muscle contraction
EPP
MEPP

The MEPP can not generate an action
potential
Neuromuscular
Junction
Activation and
Muscle
Contraction

http://inhome-personaltrainer.com/smooth-muscle-contraction-cascade
 Neuromuscular Blockers
Mechanism of neuromuscular blockade
1. Depolarizing neuromuscular blockers
Act as nicotinic receptor agonists
Activation of the Nm receptor
– Opening of ion channel causing Na+ influx
Longer duration compared to Ach
– Initial muscle contraction followed by widespread fasciculation
(muscle twitching or involuntary contraction) and then flaccid
paralysis

2. Non-depolarizing neuromuscular blockers
Act as nicotinic receptor antagonists
Inhibits muscle contraction
 Depolarizing Neuromuscular
Blocker
Succinylcholine (Anectine)
– Only depolarizing neuromuscular blocker used in
clinical setting (FDA approved 1952)
– Rapid onset of muscle paralysis coupled with an
extremely short duration of action (5-10 minutes)
Resistant to acetylcholinesterase
Hydrolysis by plasma cholinesterases
(butyrylcholinesterase)
– Small amount of drug reaches neuromuscular junction

Effect prolonged in genetic deficiency of
butyrylcholinesterase or patients with a less active
Dibucaine
geneticnumber is a
variant measure of a patient’s ability to metabolize
(rare)
succinylcholine. Used to identify at risk patients
 Mechanism of Action
Binds to nicotinic receptor and opens the ion channel
– Prolonged receptor occupancy keeps membrane
depolarized and unresponsive to further impulses (Phase I
depolarizing blockade)
– Succinylcholine is not degraded in synapse
Prolonged depolarization
– Muscle contraction followed by widespread fasciculation and
then flaccid paralysis
Membrane repolarized but not easily depolarized
(Phase II desensitizing block)
– Usually at higher doses
– Receptor becomes unresponsive to Ach
– Drug may also bind in pore to block channel
– Prolonged muscle paralysis
 Depolarizing
Neuromuscular Blocker
Paralysis occurs for two
reasons:
1. Activated receptor maintains the cell
membrane in a depolarized condition
– Effective inactivation of the sodium
channel
– New action potential cannot be achieved

2. Agonist-bound nicotinic receptor
desensitizes
– No receptor response to additional
Harvey. Lippincott’s Illustrated Review: Pharmacology 5
th
edition
 Succinylcholine Adverse Side
Effects
Muscle pain(myalgia)/ muscle weakness
– Secondary to unsynchronized contractions of
adjacent muscle fibers prior to muscle paralysis

Cardiovascular effects
– Transient bradycardia
– Cardiac arrhythmias
– Possible cardiac arrest
Due to non-specific stimulation of NN and M receptors
Treatment option - anticholinergics
 Succinylcholine Adverse
Side Effects
Acute hyperkalemia
– Patients with burns, nerve damage,
neuromuscular disease, closed head injury, and
other trauma may respond to succinylcholine
by releasing excessive amounts of potassium
into the blood.
Upregulation of the Nm receptor

Raised intraocular pressure
Histamine release
Hypotension and bronchospasm
Pre-treat with antihistamine
 Succinylcholine Adverse
Side Effects
Malignant hyperthermia (MH)
– Dysregulation of body heat
Heat generation far exceeds heat dissipation

– Autosomal dominant genetic disorder
triggered in patients receiving inhalation
anesthetics and succinylcholine

– Characterized by increased body
temperature, tachycardia,
hypertension, and muscle rigidity
 Succinylcholine Adverse
Side Effects
Malignant hyperthermia (MH)

– Drugs induce massive Ca2+ discharge
from the sarcoplasmic reticulum through
a defective muscle cell ryanodine
receptor-type 1 (RyR1)
Hypermetabolism and sustained muscle
contraction

– In the majority of cases, no clinical signs
of the RyR1 mutation are visible in the
 Ryanodine Receptor

(DHP)

Figure 20-40, Lodish 4th edition. Guyton 12th ed., Figure 7-6
 Reversal of Malignant
Hyperthermia
Non pharmacological treatment
– Ice packs

Dantrolene (Dantrium)
– Mechanism of action
Inhibits Ca2+ release from the SR of skeletal
muscle
Blocks the interaction of myosin and actin to
limit muscle contraction
 Dantrolene
Adverse Side Effects:
– Diarrhea, sedation and asthenia
– Black Box Warning:
Hepatotoxicity
– Liver function monitoring
– Cardiac and smooth muscle cells have
RyR2 therefore minimal effect by
dantrolene
 Non-depolarizing Neuromuscular
Blockers
Several non-depolarizing NMB are on the
market
– Isoquinoline derivatives
Tubocurarine
Atracurium (Tracrium)
Cisatracurium (Nimbex)

– Steroid derivatives
Rocuronium (Zemuron),
Vecuronium (Norcuron)
Pancuronium (Pavulon)
 Nicotinic Receptor
Antagonist
Mechanism of action
– Competitive antagonist at NM
– Muscle-cell non-depolarization
– Flaccid paralysis

Duration of action
– Major point of differentiation among
Neuromuscular blockers
– Short-, intermediate-, and long-acting
 Adverse Effects
Adverse effects are mostly due to
non-selective actions at NN and M
receptors and the tendency to induce
histamine release
– Tubocurarine
blockade of NN receptors
– Complex autonomic effects
Effect at NN receptors eliminated with newer
agents
 Agent Duratio Effects Effects Histami Relativ
n of at NN ? at M? ne e
Action Release Potenc
(minute ? y
s)
Tubocurarine > 50 weak none modera 1
block te

Cisatracuriu 25 - 44 none none none 1.5
m
Pancuronium > 35 none moderate none 6
block
Atracurium 20 - 35 none None slight 1.5

Rocuronium 20 - 35 none slight none 0.8
block
Vecuronium 20 - 35 none none none 6

Succinylcholi