Physiology of neuromuscular transmission

The nicotinic receptors are further classified as either N₁ or N₂ receptors.1 The N₁ receptors are located at the presynaptic cleft and influence the release of acetylcholine. The N₂ receptors are situated on the postsynaptic cleft in the neuromuscular junction and, when occupied by acetylcholine, open their channels to allow the flow of ions down the cell membrane resulting in skeletal muscle contraction (Fig. 23.1). The nondepolarizing NMBAs such as pancuronium (Pavulon) produce a block of the N₂ receptor and thus cause an inability of the channel to conduct ions, which results in skeletal muscle paralysis. Extrajunctional nicotinic receptors are located throughout the skeletal muscles. Their activity is typically suppressed by regular neural activity. However, when a patient has prolonged sepsis, inactivity, denervation, or burn trauma in the skeletal muscles, there is a proliferation of these extrajunctional nicotinic receptors. As a result, these patients usually have an exaggerated hyperkalemic response when succinylcholine is administered.¹

Presynaptic cell shows A c C O A converted to C o A. Choline in the presence of C A T converts to A C h, which releases outside the cell. The membrane has presynaptic N 1 receptor on the membrane. Arrows from A C h point toward muscarinic receptor, nicotinic type 2 receptor, acetylcholinesterase (A C h E), choline plus acetate, and presynaptic N 1 receptor through positive charge. A chart below summarizes the details for receptors as follows: • Muscarinic receptor: Agonists: Glaucoma; Antagonists: Dilate pupil, dilate airway, stabilize bladder, reduce gut motility, prevent bradycardia, antiemetic, and antiparkinsonian. • Nicotinic type 2 receptor: Agonists: Depolarizing muscle relaxant, Antagonists: Competitive muscle relaxant. • Acetylcholinesterase: Inhibitors: Glaucoma, dementias.

The muscarinic receptors are also subdivided into five subtypes (M₁-M₅) receptors. M₁ receptors are located in the autonomic ganglia and the central nervous system, and M₂ receptors are located in the heart and salivary glands. Atropine and glycopyrrolate (Robinul) block both the M₁ and the M₂ receptors.²

Acetylcholine is formed in the nerve cell’s body and cytoplasm of the nerve terminal and is stored in the small membrane-enclosed vesicles for subsequent release. A quantum is the amount of acetylcholine stored in each vesicle and represents approximately 10,000 molecules of acetylcholine. The presynaptic membrane contains discrete areas of specialization thought to be transmitter release sites. These presynaptic active zones lie directly opposite the N₂ cholinergic receptors located on the postsynaptic membrane. This alignment ensures that the acetylcholine quickly diffuses directly to the N₂ receptors on the postsynaptic membrane and in a high concentration. The N₂ receptor, which responds to the neurotransmitter acetylcholine, is a glycoprotein that is an integral part of the neuromuscular junction’s postsynaptic membrane (see Fig 23.2). A positive feedback mechanism also exists at the neuromuscular junction. Acetylcholine has a presynaptic action; therefore, acetylcholine receptors are located on the presynaptic membrane. This positive feedback mechanism enhances the mobilization and release of acetylcholine. Finally, the enzyme that hydrolyzes acetylcholine is acetylcholinesterase attached to connective tissue within the neuromuscular junction.³

Myoneural junction at resting state shows associated labels (clockwise) as follows: Axon, myelin sheath, microtubules, mitochondria, vesicles containing acetylcholine, acetylcholine receptor, conducting cleft (junctional fold), motor end plate area, acetylcholinesterase, N 2 cholinergic receptors, synaptic cleft, and synaptic knob (nerve terminal).

The initiation of skeletal muscle contraction occurs as a result of applying a threshold stimulus. An action potential travels down the axon, causing depolarization of the presynaptic membrane. As a result of this depolarization, the membrane permeability for calcium ions increases, and the calcium enters or influxes into the presynaptic membrane. Calcium acts to unite the vesicle to the presynaptic membrane and causes the rupture of that coalesced membrane, thus releasing acetylcholine into the fluid of the synaptic cleft (Fig. 23.3).

Action potential is applied along axon. Synaptic knob has acetylcholine receptor and release sites on the outer membrane. Acetylcholine is released in the gap. Calcium ions move toward synaptic knob. Post-synaptic cell has N 2 cholinergic receptors and acetylcholinesterase on the membrane.

The acetylcholine molecules released from the nerve terminal into the synaptic cleft are subject to two main processes: (1) attachment to N₂ cholinergic receptors located on the postsynaptic membrane, which leads to an opening of calcium channels resulting in the movement of sodium into the region and generating an end-plate potential (EPP), and (2) attachment of the acetylcholine to the presynaptic nicotinic receptor, which enhances the release of more acetylcholine. When enough EPPs are generated, an action potential is propagated and spread throughout the muscle, causing a change in the muscle sarcolemma’s ionic permeability. This process results in the release of calcium from the sarcoplasmic reticulum with a resultant increase in free calcium concentration in the muscle fiber. The flow of calcium results from conformation changes at voltage-sensing dihydropyridine (DHP) receptors that open the ryanodine (RyR) calcium release channels within the sarcoplasmic reticulum. Genetic mutations within the DHP and RyR receptors are thought to contribute to malignant hyperthermia after anesthesia exposure³ (see Chapter 53). The process of excitation-contraction (E-C) coupling then takes place within that skeletal muscle cell. The physiologic outcome of E-C coupling is the contraction of the skeletal muscle. The increased concentration of calcium in the muscle fiber leads to an interaction between troponin-tropomyosin and actin. This interaction causes the active sites on actin to be exposed, interacting with myosin and sliding together, thus resulting in muscle contraction. This sliding of actin and myosin is sometimes called the sliding filament mechanism.³ The muscle fibers’ contraction is terminated when calcium is pumped back into the muscle fibers’ sarcoplasmic reticulum. The calcium is stored in the sarcoplasmic reticulum for use when another action potential is generated.

Regulation and control of skeletal muscle contraction are also based on the enzymatic breakdown of acetylcholine. As previously discussed, the stimulus must be strong enough to release enough acetylcholine to bind to the postsynaptic N₂ cholinergic receptor. This competition process between the postsynaptic N₂ receptor and acetylcholinesterase allows for some degree of regulation of the excitation process and the recovery of the muscle cell membrane. The molecules of acetylcholine either diffuse randomly to the N₂ receptor or are destroyed by acetylcholinesterase located in the presynaptic and postsynaptic membranes. As the concentration gradient begins to decrease because of the destruction of acetylcholine by acetylcholinesterase, the N₂ receptor gives up its acetylcholine, which is then destroyed, and the skeletal muscle relaxes. A small portion of the acetylcholine can escape the acetylcholinesterase in the synaptic cleft and migrate into the extracellular fluid and, from there, into the plasma. Acetylcholine within the plasma is then destroyed by butyrylcholinesterase (also called plasma cholinesterase or pseudocholinesterase), produced in the liver.¹

Pharmacologic overview of commonly used muscle relaxants

With the anatomy and physiology of neuromuscular transmission as background, the nondepolarizing and depolarizing skeletal muscle relaxants’ principal pharmacologic actions are discussed. Table 23.1 presents a pharmacologic overview of the commonly used skeletal muscle relaxants.

The prototypical nondepolarizing skeletal muscle relaxants are pancuronium and vecuronium (Norcuron). Pancuronium is an inhibitor of acetylcholine, is chemically viewed as two acetylcholine-like fragments, and has a bulky inflexible nucleus. This drug attaches to the N₂ cholinergic receptors on the postsynaptic membrane and prevents depolarization. The skeletal muscle relaxant vecuronium has a chemical structure similar to a monoquaternary compound. This drug’s principal pharmacologic action blocks the postsynaptic N₂ cholinergic receptor; thus, it stops acetylcholine from binding to the receptor, which results in a competitive neuromuscular blockade. The nondepolarizing skeletal muscle relaxants block the presynaptic cholinergic receptor, resulting in the acetylcholine binding, preventing activation of the positive feedback mechanism.⁴

The pharmacologic actions of the nondepolarizing skeletal muscle relaxants can be reversed with anticholinesterase drugs such as neostigmine. In effect, these drugs increase acetylcholine quantum at the postsynaptic membrane by preventing the destruction of acetylcholine by acetylcholinesterase. This process promotes a more effective competition by releasing acetylcholine with the nondepolarizing skeletal muscle relaxant occupying the N₂ receptor. Because of the increased availability and mobilization of the acetylcholine, the concentration gradients favor acetylcholine and remove the nondepolarizing agents from the N₂ receptor with the resultant return to normal contraction of the skeletal muscle.

The principal depolarizing skeletal muscle relaxant is succinylcholine (Anectine, Sucostrin). The molecular structure of this drug resembles two back-to-back acetylcholine molecules. Because of this structure, succinylcholine has the same effects as acetylcholine. Like acetylcholine, the succinylcholine molecule has a positively charged quaternary ammonium portion. This positively charged molecule is attracted by electrostatic action to the negatively charged N₂ receptor. When the succinylcholine attaches to the receptor, a brief depolarization period occurs, manifested by transient muscular fasciculations. Succinylcholine also attaches to and activates the presynaptic acetylcholine receptor. This activation has an immediate effect of increased mobilization of acetylcholine in the motor nerve terminals, explaining why fasciculations are commonly observed after administering an intravenous bolus of succinylcholine. After the depolarization of the N₂ receptor takes place, succinylcholine promotes and maintains the receptor in a depolarized state and prevents repolarization. Succinylcholine has a brief duration of action because of its rapid hydrolysis of the succinylcholine by the enzyme pseudocholinesterase, which is contained in the liver and plasma. The succinylcholine actions cannot be pharmacologically reversed and depend on diffusion away from the neuromuscular junction and metabolism by plasma cholinesterase.⁵