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ANESTHETIC PHARMACOLOGY

The Potency of New Muscle Relaxants on Recombinant Muscle-Type Acetylcholine Receptors

Matthias Paul, MD DEAA^*, Christoph H. Kindler, MD DEAA, Ralf M. Fokt^*, Mark J. Dresser, PhD, Natalie C. J. Dipp, and C. Spencer Yost, MD^*

*Department of Anesthesia and Perioperative Care, University of California, San Francisco; Department of Anesthesia, Kantonsspital, Basel, Switzerland; Department of Biopharmaceutical Sciences, University of California, San Francisco; and Department of Anesthesia, University of Cologne, Germany

Address correspondence and reprint requests to C. Spencer Yost, MD, Department of Anesthesia and Perioperative Care, University of California, 513 Parnassus Ave., Box 0542, San Francisco, CA 94143-0542. Address e-mail to spyost{at}itsa.ucsf.edu

	Abstract

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We studied the inhibition of fetal (-nAChR) and adult (-nAChR) muscle-type nicotinic acetylcholine receptors by the two new nondepolarizing muscle relaxants (NDMRs) rocuronium and rapacuronium, the metabolite 3-desacetyl rapacuronium (Org 9488), and five other, longer-used NDMRs (pancuronium, vecuronium, mivacurium, d-tubocurarine, and gallamine). Receptors were expressed in Xenopus laevis oocytes by cytoplasmic injection of subunit complementary RNAs. Functional channels were activated with 10 µM acetylcholine, alone or in combination with various concentrations of the NDMRs. Currents were recorded with a whole-cell two-electrode voltage clamp technique. All NDMRs reversibly inhibited acetylcholine-activated currents in a dose-dependent fashion. Potencies of rapacuronium and Org 9488 were not statistically different at either -nAChR (half-maximal response = 58.2 and 36.5 nM, respectively) or -nAChR (half-maximal response = 80.3 and 97.7 nM, respectively). The rank order of potencies at the -nAChR (pancuronium > vecuronium mivacurium > rocuronium d-tubocurarine > rapacuronium Org 9488 > gallamine) correlated highly with the clinical doses needed to produce 50% twitch depression at the adductor pollicis muscle in adults. Neuromuscular blockade by rapacuronium may be enhanced by its metabolite Org 9488. Different drug-receptor affinities of the tested NDMRs contribute to the differences in clinical dose requirements of these drugs needed to achieve appropriate muscle relaxation.

IMPLICATIONS: Potencies of nondepolarizing muscle relaxants, studied at muscle nicotinic acetylcholine receptors expressed in a recombinant expression system, correlate highly with the clinical doses needed in adults to produce 50% twitch depression at the adductor pollicis muscle.

	Introduction

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Rapacuronium (recently withdrawn from the market after an unacceptably frequent incidence of bronchospasm) and rocuronium are nondepolarizing muscle relaxants (NDMRs) characterized by a fast onset of muscle relaxation and a short to intermediate duration of action (Fig. 1) (1,2). Approximately 7% of rapacuronium is metabolized to the 3-desacetyl metabolite, Org 9488, which also exerts neuromuscular blocking activity, but little is known about its potency (3,4). Org 9488 may accumulate after prolonged administration of rapacuronium, especially in patients with impaired renal function (5).

View larger version (11K): [in this window] [in a new window]   Figure 1. Structures of rocuronium, rapacuronium, and rapacuronium’s 3-desacetyl metabolite Org 9488.

The clinical determination of NDMR potency in humans is typically studied by measuring the twitch response of the adductor pollicis muscle after stimulation of the ulnar nerve (12). Because the stimulation of the ulnar nerve is not well tolerated while individuals are awake (13), they are usually anesthetized for these determinations. However, the types of anesthesia administered, e.g., volatile anesthetics or propofol, have their own effects on the neuromuscular junction and therefore may interfere with potency determinations (14). Furthermore, initial twitch depression occurs only when more than approximately 75% of nAChRs are blocked by NDMRs at one binding site (15). These observations suggest that twitch monitoring, although very important for the clinical use of muscle relaxants, does not necessarily reflect molecular interactions at the receptor level.

The aim of our study was to determine directly the potencies of the two muscle relaxants, rocuronium and rapacuronium, and the active metabolite of rapacuronium, Org 9488, in blocking the function of the nAChR expressed heterologously in Xenopus laevis oocytes. Furthermore, we wanted to compare these results with those obtained with other, longer-used muscle relaxants—vecuronium, pancuronium, mivacurium, d-tubocurarine, and gallamine—of which some have been studied previously (16–18). To assess developmental differences in drug action on the neuromuscular junction, both -nAChR and -nAChR subtypes were studied (17).

	Methods

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All experimental procedures involving the South African clawed frog (X. laevis) were approved by the Committee on Animal Research of the University of California, San Francisco, and are similar to those previously described (19).

Adult female frogs (Nasco, Fort Atkinson, WI) were maintained in freshwater holding tanks at 19°C–22°C, with a 12-h light/dark cycle. For the removal of unfertilized oocytes, frogs were anesthetized by immersion in a 0.3% solution of 3-aminobenzoic acid ethyl ester (Sigma Chemical Co., St. Louis, MO) at 4°C. Anesthetized frogs were placed supine on ice, and the ovary on one side was removed through a small incision in one quadrant of the lower abdominal wall. The wound was closed as one layer, and after recovery from anesthesia, frogs were returned to their tanks. After removal, ovaries were teased apart with forceps and washed twice in a calcium-free high-magnesium-containing lactated Ringer’s solution (composition, in mM: 82 NaCl, 2 KCl, 5 HEPES, and 20 MgCl₂, pH 7.4) followed by collagenase (type D; Boehringer Mannheim, Indianapolis, IN) treatment (2 mg/mL) for 1–2 h at room temperature with constant agitation to remove the follicular cell layer. Oocytes were washed again and transferred into modified Barth’s solution with HEPES (MBSH) [composition, in mM: 88 NaCl, 1 KCl, 10 HEPES, 7 NaHCO₃, 1 CaCl₂, and 1 Ca(NO₃)₂, pH 7.0]. Only mature oocytes (Stage V and VI) were selected for injection by visual inspection under the microscope. Within 16 h after removal, oocytes were injected with either diluted mixtures (ß or ß) of complementary RNA (cRNA) transcribed from the plasmids or water as control. Aliquots of each cRNA synthesized from plasmids encoding the , ß, , and subunits were diluted 1:1000 in ribonuclease-free water and mixed in the ratio of 2:1:1:1, respectively. For the subunit, a dilution of 1:20 was mixed with 1:1000 dilutions of , ß, and subunits to achieve similar levels of functional receptor expression.

Expression plasmids pSP1, pGEMß, pSP, and pSP, encoding complementary DNA coding sequences for mouse muscle nAChR subunits , ß, , and , respectively, were provided by Drs. John Forsayeth and Zach Hall (Department of Physiology, University of California, San Francisco, CA), and expression plasmid pSP was provided by Dr. Paul Gardner (Department of Biochemistry, Dartmouth Medical School, Hanover, NH). These plasmids contain an SP6 promoter 5' to the translation start codon that allows in vitrosynthesis of the RNA that directs the translation of each subunit. After cytoplasmic injections of cRNA, oocytes were maintained before the study in MBSH to which 50 mg/mL gentamycin, 2.5 mM sodium pyruvate, 5% heat-inactivated horse serum, and 5 mM theophylline were added.

Electrophysiological experiments were performed 2–5 days after oocyte injection at room temperature (20°C–22°C). Oocytes were placed in a recording chamber with an approximate volume of 25 µl and continuously superfused at 3–5 mL/min with MBSH containing 0.5 µM atropine sulfate. They were impaled with two glass electrodes filled with 3 M KCl (resistance of 0.4–2.5 M). Acetylcholine (Ach)-mediated currents were recorded with a two-electrode voltage clamp with the holding potential set at -60mV (Axoclamp 2A; Axon Instruments, Foster City, CA). Signals were filtered by using an eight-pole low-pass Bessel filter (Frequency Devices, Haverhill, MA) set at a 40-Hz cutoff before sampling at 100 Hz. Resulting signals were digitized and stored on a Power Macintosh 7100 (Apple Computer, Cupertino, CA) by using data acquisition software (MacLab; ADInstruments, Milford, MA).

ACh, atropine, and gallamine were purchased from Sigma. Muscle relaxants were obtained in preparations for clinical use: rocuronium and rapacuronium (Organon Inc., West Orange, NJ), pancuronium (Elkins-Sinn Inc., Cherry Hill, NJ), vecuronium (Baxter Healthcare Corp., Deerfield, IL), and mivacurium and d-tubocurarine (Abbott Laboratories, Chicago, IL). Org 9488 was a gift from Organon Teknika (Boxtel, The Netherlands). All drugs were dissolved in MBSH. Solutions and their dilutions to the experimental concentrations were prepared immediately before the experiments.

Initially, concentration-response curves for ACh were determined for each subtype of the nAChR. For all subsequent experiments, agonist concentration was set at 10 µM ACh. Test solutions containing either ACh alone or in combination with various concentrations of muscle relaxant were applied for 20 s, and the peak current was determined. The control response to ACh alone was repeated after each application of antagonist. The mean value of these two ACh applications was taken as the average control current, to which the antagonist response was compared (percentage inhibition of average control current) by use of the following equation:

equation

To minimize the amount of desensitization during the course of the experiment, a washout of at least 60 s was applied between each drug application. Data were obtained from five to eight oocytes taken from at least two different batches of oocytes.

The concentration-response relations for each muscle relaxant were fitted by nonlinear regression analysis to the four-parameter logistic equation by using GraphPad Prism software 3.0a for Macintosh (GraphPad Software, San Diego, CA), and the inhibitor concentrations for half-maximal response (IC₅₀) and Hill slopes were determined. Drug potencies at each receptor subtype were tested for significant differences by one-way analysis of variance (ANOVA) followed by Tukey’s test; potency differences between receptor subtypes were compared for each drug by using unpaired two-tailed Student’s t-tests with the same software package. P < 0.05 was considered significant. Results are represented as mean ± SD.

	Results

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Varying concentrations of ACh (0.1–1000 µM) were applied for 20 s to oocytes expressing either the fetal (₂ß) or adult (₂ß) subtype of the muscle nAChR. ACh-elicited concentration-dependent inward currents were observed. Peak currents were determined and the concentration-response data fitted to a logistic equation. The estimated ACh concentrations achieving 50% of the maximal effect (EC₅₀) were similar for both receptor subtypes, with an EC₅₀ of 12 µM for the fetal and 18 µM for the adult receptor (data not shown). In all subsequent experiments, a concentration of 10 µM ACh was used to activate the nAChRs because this concentration produced large and robust signals without significant desensitization after repeated exposures.

Rapacuronium and Org 9488 reversibly inhibited ACh-induced inward currents in a concentration-dependent fashion (Fig. 2). Both drugs had a similar (P > 0.05) concentration-response relationship at the fetal- and adult-type nAChR (Fig. 3), with IC₅₀ values in the nanomolar range. However, both drugs inhibited the fetal subtype of nAChR more potently (P < 0.05) than the adult subtype (Table 1).

View larger version (19K): [in this window] [in a new window]   Figure 2. Concentration-dependent effects of rapacuronium (RAP) (A) and its metabolite Org 9488 (ORG) (B) on the adult-type nicotinic acetylcholine receptors (-nAChR) expressed in Xenopus oocytes. Tracings represent raw currents observed during the application of acetylcholine (ACh) 10 µM for 20 s, either alone (as control) or in combination with various concentrations of rapacuronium or Org 9488, as indicated. Current tracings from a single oocyte for each drug are superimposed.

View larger version (15K): [in this window] [in a new window]   Figure 3. Concentration-response effects of rapacuronium and Org 9488 for inhibition of acetylcholine-induced current in oocytes expressing fetal-type (-nAChR) (A) and adult-type (-nAChR) (B) nicotinic acetylcholine receptors. Data points are mean ± SD (error bars) of five to eight oocytes. Error bars not visible are smaller than symbols. NDMR = nondepolarizing muscle relaxant.

View this table: [in this window] [in a new window]   Table 1.  Potencies of Nondepolarizing Muscle Relaxants at the Adult and Fetal Forms of the Muscle Nicotinic Acetylcholine Receptor (-nAChR and -nAChR, Respectively)

View larger version (22K): [in this window] [in a new window]   Figure 4. Concentration-response effects of pancuronium (A), vecuronium (B), mivacurium (C), rocuronium (D), d-tubocurarine (E), and gallamine (F) for inhibition of acetylcholine-induced currents in oocytes expressing fetal-type (-nAChR) (•) and adult-type (-nAChR) () nicotinic acetylcholine receptors. Data points are mean ± SD (error bars) of five to eight oocytes. Error bars not visible are smaller than symbols.

View larger version (16K): [in this window] [in a new window]   Figure 5. Correlation of half-maximal response (IC50) values at the adult muscle-type nicotinic acetylcholine receptor (-nAChR) (Table 1) and published doses needed to produce 50% twitch height decrease in the force of contraction of the adductor pollicis muscle with ulnar nerve stimulation (20). EC50 = 50% of the maximal effect.

	Discussion

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With the oocyte expression system, large numbers of functional receptors are assembled and inserted into the oocyte membrane. This receptor population can be exposed rapidly to various concentrations of specific agonists or antagonists. We had previously established ACh concentration-response relations, demonstrating that the EC₅₀ values did not differ between the adult and fetal nAChR subtypes (22). We used a holding voltage of -60 mV because the antagonistic effects of NDMRs are independent of holding voltages ranging from -100 to -40 mV (16,17). During the course of these experiments, we used an ACh concentration of 10 µM as a standard test concentration. This concentration was close to the EC₅₀ concentration for both receptor subtypes, ensured robust baseline responses, and minimized receptor desensitization due to repetitive ACh application. The use of mouse receptors is justified because of the close sequence homology and functional similarity with human nAChR; however, there could be species differences in response to NDMRs. Although the concentration of agonist used here (ACh 10 µM) may be smaller than the estimated peak concentrations within the neuromuscular junction, our experiments are probably more physiologically meaningful than pure binding assays using desensitized forms of the nAChR. Desensitized nAChRs show different affinities for modulating agents compared with functional receptors (23).

This is the first report of potency determinations for the muscle relaxants rocuronium, rapacuronium, and Org 9488 using a heterologous receptor expression method. We found that rapacuronium and Org 9488 have similar potency in inhibiting each nAChR subtype. This confirms that Org 9488 has muscle-blocking properties, as reported in an earlier clinical study in adults; however, the modeled drug concentrations at the effector site in that study estimated Org 9488 to be approximately 2 to 3 times more potent than the parent compound (3). Pharmacokinetic/pharmacodynamic modeling is based on several assumptions, which might be responsible for the higher estimate of Org 9488 potency. Given that Org 9488 has a similar, or even higher, potency than rapacuronium and an even longer half-life, Org 9488 may be responsible for unexpected enhancement of neuromuscular blockade, especially if rapacuronium is administered over a prolonged period (3,5). This risk of enhanced muscle block is increased in patients with renal failure because the clearance of Org 9488 is reduced by 85% in these patients compared with healthy volunteers (4).

The aminosteroids rocuronium, rapacuronium, Org 9488, and pancuronium, but not vecuronium, showed greater potency on the fetal subtype compared with the adult subtype of nAChR. The higher potency of pancuronium at the -AChR confirms our previously reported findings with dimethylphenyl piperazinium as an agonist (18); however, Garland et al. (17) found pancuronium to be more potent at the -nAChR. The equipotent effects of vecuronium on both receptor subtypes is in close agreement with earlier studies (17,22). The receptor affinities of the benzoisoquinolines mivacurium and d-tubocurarine were also affected by the developmental switch of subunit composition; mivacurium was more potent at the fetal subtype, but d-tubocurarine was more potent at the adult subtype of the nAChR. Given that NDMRs are generally more potent in neonates than in adults, our findings with d-tubocurarine suggest that it exerts additional effects on the intact neonatal neuromuscular junction to enhance its potency.

Although most NDMRs showed a higher affinity to the fetal subtype in our study, the differences in drug-receptor affinity between the receptor subtypes are not entirely consistent for all compounds. Although we have no experimental data from these studies to explain this finding, we suggest that this reflects a subtle difference in the binding of the molecular structures within the competitive inhibition site in the two receptor subtypes. At the molecular level, the two agonist binding sites for Ach, as well as the antagonist binding sites for NDMRs, are nonequivalent, with one being formed by contributing portions of and subunits and the other by the subunit and either the or subunit (24). The two sites have different binding affinities for agonist and must both be occupied by agonist to open the channel. However, only one site needs to be occupied by an antagonist to produce receptor blockade (25). Again, differences in binding affinity may explain the differences in Hill coefficients that we observed between agonist and antagonist.

The findings of Fletcher and Steinbach (16), who used nAChR expressed in quail fibroblasts, established a rank order of affinities for pancuronium, metocurine, and gallamine for both fetal- and adult-type receptors very similar to those reported here. They reported a 100-fold difference in potency between pancuronium and gallamine for -AChR, which is in agreement with our findings of a 200-fold difference (IC_50(-AChR) for pancuronium = 5.5 nM and for gallamine = 995 nM).

Adequate muscle relaxation for clinical purposes, with the structurally different NDMRs tested in this study, requires that they be given in very different doses spanning a range of approximately 2 orders of magnitude (20). The relative potencies of NDMRs on the -nAChR expressed in oocytes presented here correlate closely with the ED₅₀ concentrations of these drugs needed for clinical muscle relaxation in humans (20). This rank order of relative potency also reflects the clinical doses necessary for intubation. This finding provides further validation of the oocyte expression system for pharmacodynamic studies of NDMRs on nAChR subtypes. Our data suggest that the differences in drug dosages needed to achieve clinically appropriate muscle relaxation may be largely attributed to the different drug-receptor affinities rather than to other factors, such as drug binding to plasma proteins or membrane permeability.

	Acknowledgments

 
Supported by National Institutes of Health Grant GM-58149 (CSY).

The authors thank Beth Sampson and Frank Chen for excellent technical assistance and Charles E. McCulloch (Professor of Biostatistics, Department of Epidemiology and Biostatistics, University of California, San Francisco) for statistical advice. Org 9488 was kindly provided by Organon Teknika, The Netherlands.

	Footnotes

 
Presented in part at the annual meeting of the American Society of Anesthesiologists, San Francisco, CA, October 14–18, 2000.

	References

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a colleague Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via ISI Web of Science (9) Citing Articles via Google Scholar Google Scholar Articles by Paul, M. Articles by Yost, C. S. Search for Related Content PubMed PubMed Citation Articles by Paul, M. Articles by Yost, C. S. Related Collections Pharmacology

Anesthesia & Analgesia® is published for the International Anesthesia Research Society® by Lippincott Williams & Wilkins with the assistance of Stanford University Libraries' HighWire Press®. Copyright 2006 by the International Anesthesia Research Society. Online ISSN: 1526-7598   Print ISSN: 0003-2999