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Nursing Pharmacology Chapter 20: Neuromuscular Blockers
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Neuromuscular blocking drug pharmacodynamic characteristics determined by measuring:
Speed of onset
Duration of neuromuscular blockade
Clinical method of determining neuromuscular-blockade properties:
Determine skeletal muscle response evoked by supramaximal electrical stimulation using a peripheral nerve stimulator
Typically: single twitch response to 1Hz {adductor pollicis muscle -- ulnar nerve stimulation)
Potency determination comparing neuromuscular-blocking drugs:
Dose required to suppress 95% of the single twitch response (ED95)
Potency determined in the presence of nitrous oxide-barbiturate-opioid anesthesia
Volatile anesthetics will significantly decreased ED95.
Neuromuscular blocking drugs: sequence of muscles affected:
Small, rapidly moving muscles (fingers, eyes) before diaphragm
Recovery in reverse order
IV neuromuscular blocker injection (nondepolarizing) to an awake patient:
Initial difficulty in focusing and weakness in mandibular muscles
Then ptosis, diplopia and dysphagia
Consciousness and sensorium: unaffected, even with complete neuromuscular block
Blockade onset
More rapid, less intense effect at laryngeal muscles (vocal cords) then at adductor pollicis (peripheral muscle example)
More rapid laryngeal muscle onset is probably due to a more rapid drug plasma: drug muscle equilibration
Reduced initial intensity of effect at laryngeal muscle (fast fibers) follows from the requirement for more complete receptor blockade for effect then for muscles mainly composed of slow fibers, e.g. adductor pollicis.
Neuromuscular diaphragm blockade
Requires 2 times the dose required for adductor pollicis muscle blockade
Adductor pollicis monitoring: poor indicator of cricothyroid muscle (laryngeal) relaxation
Facial nerve stimulation with orbicularis oculi muscle response monitoring is a better reflection of neuromuscular diaphragm blockade onset
Orbicularis oculi muscle monitoring is preferable to monitoring adductor pollicis as indicator of laryngeal muscle blockade
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Primary uses of neuromuscular-blocking drugs:
Skeletal muscle relaxation facilitating tracheal intubation
Skeletal muscle relaxation to improve intraoperative surgical conditions
Dose guidelines:
Facilitation of tracheal intubation -- 2 x ED95 dose of nondepolarizing muscle relaxant
Laryngospasm: effectively treated with succinylcholine (Anectine)
Optimal intraoperative conditions -- 95% single twitch response suppression
Neuromuscular-blocking drugs:
no CNS depression
no analgesia therefore they do not substitute for anesthetic agents
Other clinical uses:
In managing patients requiring mechanical ventilation (intensive care environment)
Adult respiratory distress syndrome
Tetanus
Suppression of spontaneous respiration
Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449. Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219. White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Rationale for Monitoring Neuromuscular Blockade:
NMJ blocking drugs are dangerous in that they interfere with respiration.
Depression of ventilation is a significant cause of anesthesia-related morbidity/mortality--an important factor is the extent of residual neuromuscular blockade.
Narrow drug safety margin (corresponds to a narrow range of receptor occupancy)
Significant patient-to-patient response variabilty to the same dosage
Interactions between NMJ blocking drugs with other agents
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