Caffeine- or halothane-induced contractures of masseter muscle are similar to those of vastus muscle in normal humans

BACKGROUND: Skinned fibers from normal human masseter muscle have greater caffeine and calcium sensitivity than skinned fibers from vastus muscle. We examined sensitivity to caffeine and halothane in fresh, cut muscle bundles (non-skinned) from human masseter muscle. METHODS: Masseter bundles (caffeine, n=25, halothane, n=19) excised from 10 humans under general anesthesia had tension measured in 37 degrees C baths during the addition of caffeine (0.5, 1, 2, 4, 8, 32 mM) or 3% halothane. Results were compared to those of our previous studies (1989, 1997, 25 patients) of vastus bundles (caffeine, n=71, halothane, n=63) using the same protocol, technicians, and equipment. RESULTS: Baseline force in the caffeine test was 2.10+/-1.57 for masseter, and 2.02+/-1.68 and 1.82+/-1.29 respectively for vastus muscle. Force at 32 mM caffeine concentration was 11.2+/-9.9 g for masseter, 11.0+/-5.4 and 13.5+/-7.5 g for vastus. Concentration-response curves were virtually identical. In the halothane group, neither baseline values (masseter 1.47+/-1.30, vastus 1.91+/-1.32 and 2.15+/-1.71) nor contractures in response to 3% halothane were different. Most bundles had no contracture in response to 3% halothane; 3 masseter bundles and 2 vastus bundles (1989) developed contractures of less than 0.05 g. Three vastus bundles (1997) developed contractures >0.2 g. CONCLUSION: Contracture responses of intact cut masseter and vastus bundles (non-skinned) do not differ with respect to caffeine and halothane. Responses of skinned fibers might demonstrate greater sensitivity under certain conditions, but they do not reflect those of intact cut bundles.     

Malignant hyperthermia in humans--standardization of contracture testing protocol

Malignant hyperthermia (MH) diagnostic biopsy centers across North America have not previously been standardized in regard to protocols and specific muscles. Recent standardization criteria prompted this study of the vastus and rectus abdominis muscles. This study evaluated changes in contracture tension after electrical stimulation of 271 bundles taken from the vastus (n = 16) and rectus abdominus (n = 19) muscle biopsies of normal individuals when exposed to tissue baths in the absence of and in the presence of caffeine (0.5, 1.0, 2.0, 4.0, 8.0, and 32.0 mM) alone, halothane (1% or 3%) alone, or the combination of halothane (1%) plus caffeine (0.25, 0.5, 1.0, 2.0, 4.0, and 32.0). Caffeine threshold concentration was that concentration of caffeine that produced a 7% increase in tension. Caffeine specific concentration (CSC) and halothane caffeine specific concentration (HCSC) were those concentrations of caffeine alone or of halothane plus caffeine that produced a 1 g increase in tension. The concentration of caffeine alone that increased the contracture tension by 7% averaged 6.7 +/- 0.3 mM for vastus, significantly greater than 4.1 +/- 0.2 mM for the rectus muscle biopsies. Caffeine specific concentration was significantly greater for vastus muscle (7.7 +/- 0.7 mM) than it was for rectus muscle (4.9 +/- 0.4 mM). Three percent halothane alone showed contractures in 3/41 vastus (all less than 0.5 g) and 18/54 rectus muscle bundles (8 greater than 0.5 g). Mean HCSC was statistically significantly greater for vastus muscle (1.9 +/- 0.2 mM) than for rectus muscle (1.2 +/- 0.2 mM).(ABSTRACT TRUNCATED AT 250 WORDS)     

Caffeine skinned fiber tension test: application to the diagnosis of susceptibility to malignant hyperthermia]

OBJECTIVE: To assess the reactivity of sarcoplasmic reticulum to caffeine, using the skinned muscle fibre tension test and to compare it with the reference in vitro contracture test in the diagnosis of malignant hyperthermia (HM) susceptibility. STUDY DESIGN: Laboratory investigation. MATERIAL: Muscle biopsies from 63 patients, including 29 classified as susceptible to MH (MHS) and 34 classified as non-susceptible (MHN) according to criteria of the European and the North American MH groups. METHOD: The reactivity to caffeine and halothane of skinned muscle fibres was compared, according to the type of fibres, with the data of the in vitro contracture test. The type of fibres (type I: oxidative, slow; type II: glycolytic, fast) were determined with strontium dose-response curves. RESULTS: The reactivity to caffeine was significantly lower in the MHS group, for both type I and type II skinned fibres. However, in comparison with the data of the in vitro contracture tests, using the ROC curve analysis, the best sensitivity-specificity compromise was 90%-71% and 74%-84% for type I and type II skinned fibres respectively. CONCLUSION: The skinned muscle fibre tension test cannot be used instead of the in vitro contracture test for the diagnostic of MHS. However, it may strengthen the data of the latter.     

Isoform-dependent Effects of Halothane in Human Skinned Striated Fibers

Background: Reports of the effects of halothane on isoform contractile proteins of striated muscles are conflicting. To determine whether halothane affects cardiac and skeletal contractile proteins differently, the authors examined the effects of two doses of halothane (0.44 and 1.26 mM, equivalent to 0.75 and 2.25 vol%, respectively) on the Calcium sup ++ sensitivity and maximal force in human skinned cardiac, type I (slow twitch), and type II (fast twitch) skeletal muscle fibers.

Methods: Left ventricular muscle strips and skeletal muscle biopsy specimens were obtained from eight and ten patients undergoing cardiac and orthopedic surgery, respectively. Sarcolemma and sarcoplasmic reticulum were destroyed with ethylene glycol bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid plus Brij 58. Calcium sup ++ sensitivity was studied by observing the isometric tension developed by skinned fibers challenged with increasing concentrations of Calcium sup ++. Muscle fiber type was determined in each skeletal fiber by the difference in strontium-induced tension measurements.

Results: Halothane shifted the Calcium sup ++ tension curves toward higher Calcium sup ++ concentrations and increased the Calcium sup ++ concentration for half-maximal activation in both cardiac and type I skeletal muscle fibers (from 1.96 micro Meter and 1.06 micro Meter under control conditions to 2.92 micro Meter and 1.71 micro Meter in presence of 0.75 vol% halothane, respectively) without changing the slope of this relationship (Hill coefficient). In contrast, no significant effect was observed in type II fibers. Halothane also decreased the maximal activated tension in the three groups of fibers with a lesser effect in type II fibers.     

Halothane Induces Calcium Release from Human Skinned Masseter Muscle Fibers

Background: An increase in masseter muscle tone in response to halothane or succinylcholine anesthesia (or both) can be observed in healthy persons. Thus the authors compared the fiber-type halothane and succinylcholine sensitivities in human masseter and vastus lateralis muscles.

Methods: Masseter and vastus lateralis muscle segments were obtained from 13 and 9 healthy persons, respectively. After chemical skinning of a single fiber and loading the sarcoplasmic reticulum with Ca++ 0.16 [micro sign]M solution, halothane (0.5-4 vol% bubbled in the incubating solution), succinylcholine (0.1 [micro sign]M to 10 mM), or both sensitivities were defined as the concentration inducing more than 10% of the maximum tension obtained by application of 16 [micro sign]M Ca++ solution. The myofilament response to Ca++ was studied with and without halothane by observing the isometric tension of skinned masseter fibers challenged with increasing concentrations of Ca++. Muscle fiber type was determined by the difference in strontium-induced tension measurements.

Results: A significant difference in halothane sensitivity was found between type 1 masseter fibers (0.6 +/- 0.2 vol%; mean +/- SD) versus type 1 (2.7 +/- 0.6 vol%) and type 2 vastus lateralis muscle (2.5 +/- 0.4 vol%). Succinylcholine did not induce Ca++ release by the sarcoplasmic reticulum. In the masseter muscle, 0.75 vol% halothane decreased the maximal activated tension by 40% but did not change the Ca++ concentration that yields 50% of the maximal tension.     

Halothane induces calcium release from human skinned masseter muscle fibers

BACKGROUND: An increase in masseter muscle tone in response to halothane or succinylcholine anesthesia (or both) can be observed in healthy persons. Thus the authors compared the fiber-type halothane and succinylcholine sensitivities in human masseter and vastus lateralis muscles. METHODS: Masseter and vastus lateralis muscle segments were obtained from 13 and 9 healthy persons, respectively. After chemical skinning of a single fiber and loading the sarcoplasmic reticulum with Ca++ 0.16 microM solution, halothane (0.5-4 vol% bubbled in the incubating solution), succinylcholine (0.1 microM to 10 mM), or both sensitivities were defined as the concentration inducing more than 10% of the maximum tension obtained by application of 16 microM Ca++ solution. The myofilament response to Ca++ was studied with and without halothane by observing the isometric tension of skinned masseter fibers challenged with increasing concentrations of Ca++. Muscle fiber type was determined by the difference in strontium-induced tension measurements. RESULTS: A significant difference in halothane sensitivity was found between type 1 masseter fibers (0.6+/-0.2 vol%; mean +/- SD) versus type 1 (2.7+/-0.6 vol%) and type 2 vastus lateralis muscle (2.5+/-0.4 vol%). Succinylcholine did not induce Ca++ release by the sarcoplasmic reticulum. In the masseter muscle, 0.75 vol% halothane decreased the maximal activated tension by 40% but did not change the Ca++ concentration that yields 50% of the maximal tension. CONCLUSIONS: The very low halothane threshold for Ca++ release from the masseter muscle usually could be counteracted by a direct negative inotropic effect on contractile proteins. However, halothane may increase the sensitivity of the sarcoplasmic reticulum Ca++ release to succinylcholine-induced depolarization, leading to an increase in masseter muscle tone.     

Is resting membrane potential a possible indicator of viability of muscle bundles used in the in vitro caffeine contracture test?

In 22 patients susceptible to and 34 patients not susceptible to malignant hyperthermia, we examined which muscle conditions may influence the degree of sensitivity of skeletal muscle to the in vitro caffeine contracture test: predrug resting membrane potential, predrug twitch tension, and maximum contracture induced by 32 mM caffeine in two caffeine tests performed respectively at 30 and 75 min after biopsy. No differences in the measured variables were observed between the first and the second caffeine tests in the 34 patients susceptible to malignant hyperthermia. The first caffeine test was found to be positive in all of the 22 patients susceptible to malignant hyperthermia. However, in eight patients, the second caffeine test was negative and the muscle fibers were found to be significantly depolarized. Resting membrane potential was -73.4 +/- 7.9 mV before the first caffeine test and -65.8 +/- 8.8 mV before the second test. We suggest that when time-induced partial depolarization of malignant hyperthermia-susceptible fibers occurs, fibers may become less sensitive to caffeine.     

Hypersensitivity of malignant hyperthermia-susceptible swine skeletal muscle to caffeine is mediated by high resting myoplasmic [Ca2+

BACKGROUND: Malignant hyperthermia (MH) is an inherited pharmacogenetic syndrome that is triggered by halogenated anesthetics and/or depolarizing muscle relaxants. MH-susceptible (MHS) skeletal muscle has been shown to be more sensitive to caffeine-induced contracture than muscle from nonsusceptible (MHN) subjects and is the basis for the most commonly used clinical diagnostic test to determine MH susceptibility. METHODS: We studied the effects of caffeine on myoplasmic free calcium concentration ([Ca2+]i) in MHN and MHS swine muscle fibers by means of Ca2+-selective microelectrodes before and after K+-induced partial depolarization. RESULTS: [Ca2+]i in untreated MHN fibers was 123 +/- 8 nm versus 342 +/- 33 nm in MHS fibers. Caffeine (2 mm) caused an increase in [Ca2+]i in both groups (296 +/- 41 nm MHN vs. 1,159 +/- 235 nm MHS) with no change in resting membrane potential. When either MHN or MHS, muscle fibers were incubated in 10 mm K+ [Ca2+]i transiently increased to 272 +/- 22 nm in MHN and 967 +/- 38 nm in MHS for 6-8 min. Exposure of MHN fibers to 2 mm caffeine while resting [Ca2+]i was elevated induced an increment in [Ca2+]i to 940 +/- 37 nm. After 6-8 min of exposure to 10 mm K+, [Ca2+]i returned to control levels in all fibers, and the effect of 2 mm caffeine on resting [Ca2+]i returned to control, despite continued partial membrane depolarization. CONCLUSIONS: These results suggest that the increased "sensitivity" to caffeine of MHS swine muscle fibers is a nonspecific response related, at least in part, to the high resting [Ca2+]i and not an increased caffeine sensitivity of the sarcoplasmic reticulum Ca2+ release channel per se.     

The in-vitro caffeine contracture test: Influence of the muscle histochemical profile on test results

In vitro caffeine contracture tests were carried out on whole rat muscle composed primarily of either histochemical type I or type II fibers. Muscles composed primarily of type I fibers developed contractures at lower concentrations of caffeine and had lower caffeine specific concentrations than muscles composed primarily of type II fibers. These findings indicate that the histochemical profile of a muscle can influence the results of the in-vitro caffeine contracture test.     

Malignant hyperthermia; two cases of MH in the presence of general anesthesia and performing caffeine contracture test

In the present report we described two cases of malignant hyperthermia under halothane anesthesia. Case 1; A 54-year-old, 58 kg-male was scheduled for the operation of giant arterio-venous malformation. Anesthesia was induced with thiamylal, fentanyl and pancuronium, and maintained with oxygen, nitrous oxide and halothane. The patient was subjected to halothane inhalation for 26 hours prior to the development of the malignant hyperthermia. Although body temperature rose to 41 degrees C, it returned to normal with the administration of 280 mg of dantrolene and systemic cooling. Case 2; A 31-year-old, 68 kg-female was scheduled for tonsillectomy. Anesthesia was induced with thiamylal, oxygen, nitrous oxide and halothane. After the administration of 70 mg of SCC, marked muscular rigidity occurred and endotracheal intubation was impossible. The operation was postponed. Two months after the first anesthesia, operation was successfully performed under NLA with droperidol and fentanyl. Caffeine contracture test was performed in each case by skinned fiber method and the result showed that the sensitivity to caffeine increased in the isolated skeletal muscle fiber bundles from these patients. Thresholds of caffeine contracture of these skinned fiber bundles were all lower than 5mM caffeine.     

Study of the intracellular contractile mechanism of the urinary bladder smooth muscle using skinned fiber technique

The intracellular contractile mechanism of the urinary bladder smooth muscle was studied using the saponin-treated skinned fiber in which cell membrane was chemically removed. The chemically skinned bladder muscle showed a tension development which was dependent on Ca2(+)-concentration. The minimal Ca2(+)-concentration for the tension development was 2 X 10(-7) M Ca2+. The maximal tension was induced at 10(-5) M. This maximal tension was approximately the same as the K(+)-induced tension development observed in the intact muscle. In addition, SDS-polyacrylamide gel electrophoresis showed that the contractile proteins were still preserved in the saponin-treated bladder smooth muscle. The Ca2(+)-concentration-tension response curve shifted to the left with an increase in MgATP concentration (from 3 mM to 7 mM), indicating that the sensitivity of the skinned muscle was affected by MgATP. Mg2+ above 6 mM caused a slow tension development by itself in the absence of Ca2+. Ca2(+)-induced tension development was blocked by the addition of W-7 (calmodulin antagonist). This result suggested that calmodulin (Ca2(+)-binding protein) regulates the actin-myosin interaction in the urinary bladder smooth muscle. Caffeine solution (25 mM) caused a rapid tension development in the skinned bladder smooth muscle which was loaded with Ca2(+)-concentration, however, this tension development decreased when the loaded Ca2(+)-concentration exceeded 10(-6) M. It seems from this result that "Ca-induced-Ca release mechanism" also exists in the urinary bladder smooth muscle.     

Comparison of the effects of halothane on skinned myocardial fibers from newborn and adult rabbit: II. Effects on sarcoplasmic reticulum

The effect of halothane on Ca2+ uptake or release by the sarcoplasmic reticulum (SR) was compared in the newborn and adult rabbit myocardium. The sarcolemma of right ventricular myocardium was disrupted (skinned) by homogenization. Fiber bundles were dissected from the homogenate, mounted on tension transducers, and immersed sequentially in five solutions that loaded Ca2+ into the SR, then in solutions containing either 2 or 25 mM caffeine to release SR-stored Ca2+, resulting in transient tension development. Experimental solutions were saturated with halothane in N2 gas during Ca2+ uptake by SR, Ca2+ release by SR, or during both SR Ca2+ uptake and release. Halothane (0.5-1.7%) resulted in dose-dependent depression of SR Ca2+ uptake in both newborn and adult skinned fibers. Less tension transient depression resulted in newborn (35%) than adult skinned fibers (49.5%, P less than 0.05) with 0.5% halothane exposure during SR Ca2+ uptake. Similar depression resulted in newborn (53.7% and 73.4%) and adult fibers (65.2% and 77.9%) with 1.0% and 1.7% halothane. Halothane had little effect on SR Ca2+ release by 25 mM caffeine but enhanced submaximal SR Ca2+ release by 2 mM caffeine more in newborn than adult myocardium. Increased Ca2+ efflux from newborn SR may contribute to the greater sensitivity of intact newborn cardiac muscle to exposure to halothane.     

Hypersensitivity of Malignant Hyperthermia-susceptible Swine Skeletal Muscle to Caffeine Is Mediated by High Resting Myoplasmic [Ca2+]

Background: Malignant hyperthermia (MH) is an inherited pharmacogenetic syndrome that is triggered by halogenated anesthetics and/or depolarizing muscle relaxants. MH-susceptible (MHS) skeletal muscle has been shown to be more sensitive to caffeine-induced contracture than muscle from nonsusceptible (MHN) subjects and is the basis for the most commonly used clinical diagnostic test to determine MH susceptibility.

Methods: We studied the effects of caffeine on myoplasmic free calcium concentration ([Ca2+]i) in MHN and MHS swine muscle fibers by means of Ca2+-selective microelectrodes before and after K+-induced partial depolarization.

Results: [Ca2+]i in untreated MHN fibers was 123 +/- 8 nm versus 342 +/- 33 nm in MHS fibers. Caffeine (2 mm) caused an increase in [Ca2+]i in both groups (296 +/- 41 nm MHN vs. 1,159 +/- 235 nm MHS) with no change in resting membrane potential. When either MHN or MHS, muscle fibers were incubated in 10 mm K+ [Ca2+]i transiently increased to 272 +/- 22 nm in MHN and 967 +/- 38 nm in MHS for 6-8 min. Exposure of MHN fibers to 2 mm caffeine while resting [Ca2+]i was elevated induced an increment in [Ca2+]i to 940 +/- 37 nm. After 6-8 min of exposure to 10 mm K+, [Ca2+]i returned to control levels in all fibers, and the effect of 2 mm caffeine on resting [Ca2+]i returned to control, despite continued partial membrane depolarization.     

No relationship between fiber type and halothane contracture test results in malignant hyperthermia

Previous studies in cat, rat, and swine have implicated fiber type as influencing the halothane and caffeine contracture test used to diagnose malignant hyperthermia (MH). The authors performed fiber type analysis using myosin ATPase stains on 31 fascicles of skeletal muscle from nine patients following contracture testing. There was no significant difference in fiber type composition between fascicles from MH negative (n = 5) and MH positive (n = 4) patients. Furthermore, examining each of the 31 fascicles, the authors found no correlation (P greater than .05) of contracture magnitude with percentage of either Type I or Type II fibers using the Pearson Product-Moment correlation calculation. The authors conclude that fiber type composition does not influence contracture test results in human biopsies.     

Desflurane induces only minor Ca2+ release from the sarcoplasmic reticulum of mammalian skeletal muscle

BACKGROUND: Desflurane is a weaker trigger of malignant hyperthermia than is halothane. There are very few data of the pathophysiologic background of this observation. Therefore, the authors' aim was to investigate the direct effect of desflurane on calcium release in skinned skeletal muscle fibers. METHODS: For the measurements, single saponin-skinned muscle fiber preparations of BALB/c mice were used. For Ca2+ release experiments, liquid desflurane at 0.6 and 3.5 mm was applied to weakly calcium-buffered solutions with no added Ca2+. Desflurane was diluted in strongly Ca2+-buffered solutions, with [Ca2+] between 3.0 and 24.9 micrometer for [Ca2+]-force relations. Force transients were transformed into Ca2+ transients based on the individual [Ca2+]-force relations. As controls, 30 mm caffeine and equimolar sevoflurane were investigated in the same muscle fibers. RESULTS: At 3.5 mm, desflurane induced peak force transients of 8 +/- 4% (mean +/- SD) of maximal Ca2+-activated force (Tmax). These peak values were significantly smaller than those in the presence of 3.5 mm sevoflurane (24 +/- 10% of Tmax, P < 0.05), and 4 or 5 times smaller than previously reported Ca2+-release-induced force transients by equimolar halothane. Calculated peak Ca2+ transients derived from force transients and induced by 3.5 and 0.6 mm desflurane were significantly smaller than those induced by 30 mm caffeine. The [Ca2+]-force relation was shifted by desflurane, resulting in a Ca2+-sensitizing effect. The maximal Ca2+-activated force was significantly increased by 0.6 mm desflurane in comparison with the control, with no added substance (P 相似文献   

Caffeine and halothane contracture testing in swine using the recommendations of the North American Malignant Hyperthermia Group

Caffeine and halothane contracture testing is widely used to detect malignant hyperthermia (MH) susceptibility. The accuracy and reliability of the 3% halothane test and the incremental caffeine test, as recommended by the North American MH Group, were assessed in 11 swine (five MHS, six control). Nine swine were tested twice, 4-6 weeks apart. Accuracy of the in vitro diagnosis was also assessed by in vivo anesthetic challenge. Of all muscle bundles from MH-susceptible swine, 65% reacted positively to 3% halothane and 70% to 2 mM caffeine. Only 35% had a positive caffeine-specific concentration, and 25% developed an increase in baseline tension greater than or equal to 7% at 2 mM caffeine. However, when only the most positive response to 3% halothane or to 2 mM caffeine was used (a minimum of three fresh muscle strips is recommended), these two tests were highly sensitive and specific. In control swine one of 30 muscle bundles reacted positively to 3% halothane. A positive caffeine-specific concentration developed in one of 25 control muscle bundles exposed to caffeine. The variability in the results of these tests mandated that at least three muscle bundles be used for each test. Nonviable muscle bundles could not be relied upon to provide accurate results. In this porcine model, MH susceptibility could be detected by performing the Caffeine Halothane Contracture Test (CHCT) according to the guidelines of the North American MH Group. However, only the 3% halothane test and the response to 2 mM caffeine produced adequate diagnostic results in this breed of swine.     

Phosphorylase ratio and susceptibility to malignant hyperthermia

The ratio of muscle phosphorylase a to total phosphorylase, expressed as a percent, was determined in vastus lateralis muscle of 26 patients to examine the efficacy of this parameter as a method for screening for susceptibility to malignant hyperthermia (MH). As standard screening, all patients also had muscle contracture responses determined to 2% halothane and 0.25-32 mM caffeine at 37 degrees C. Each drug was given separately and not combined. Nine patients were susceptible to MH, based upon caffeine threshold of 2 mM or less (seven patients) or a rapidly developing contracture tension to halothane of more than 400 mg (seven patients, including five with positive caffeine responses). Mean phosphorylase ratio in these nine patients was 14.5 +/- 2.0% (mean, SEM). In the 17 nonsusceptible patients mean phosphorylase ratio (12.4 +/- 1.9%) was not significantly different. The range of phosphorylase ratios in susceptible patients was 6.5-26% while 13 nonsusceptible patients had ratios greater than 6% and up to 29%. The unacceptably high number of false-positive responses in nonsusceptible patients precludes the use of phosphorylase ratio as a definitive diagnostic test.     

Desflurane Induces Only Minor Ca2+ Release from the Sarcoplasmic Reticulum of Mammalian Skeletal Muscle

Background: Desflurane is a weaker trigger of malignant hyperthermia than is halothane. There are very few data of the pathophysiologic background of this observation. Therefore, the authors' aim was to investigate the direct effect of desflurane on calcium release in skinned skeletal muscle fibers.

Methods: For the measurements, single saponin-skinned muscle fiber preparations of BALB/c mice were used. For Ca2+ release experiments, liquid desflurane at 0.6 and 3.5 mm was applied to weakly calcium-buffered solutions with no added Ca2+. Desflurane was diluted in strongly Ca2+-buffered solutions, with [Ca2+] between 3.0 and 24.9 [mu]m for [Ca2+]-force relations. Force transients were transformed into Ca2+ transients based on the individual [Ca2+]-force relations. As controls, 30 mm caffeine and equimolar sevoflurane were investigated in the same muscle fibers.

Results: At 3.5 mm, desflurane induced peak force transients of 8 +/- 4% (mean +/- SD) of maximal Ca2+-activated force (Tmax). These peak values were significantly smaller than those in the presence of 3.5 mm sevoflurane (24 +/- 10% of Tmax, P < 0.05), and 4 or 5 times smaller than previously reported Ca2+-release-induced force transients by equimolar halothane. Calculated peak Ca2+ transients derived from force transients and induced by 3.5 and 0.6 mm desflurane were significantly smaller than those induced by 30 mm caffeine. The [Ca2+]-force relation was shifted by desflurane, resulting in a Ca2+-sensitizing effect. The maximal Ca2+-activated force was significantly increased by 0.6 mm desflurane in comparison with the control, with no added substance (P <= 0.05).     

ATX II, a sodium channel toxin, sensitizes skeletal muscle to halothane, caffeine, and ryanodine.

BACKGROUND: The function or expression of subtypes of the sodium ion (Na+) channel is altered in biopsies or cultures of skeletal muscle from many persons who are susceptible to malignant hyperthermia (MH). ATX II, a specific Na+ channel toxin from a sea anemone, causes delayed inactivation of the channel similar to that seen in cell cultures of MH muscle. ATX II was added to skeletal muscle to determine whether altered Na+ channel function could increase the sensitivity of normal skeletal muscle to agents (halothane, caffeine, ryanodine) to which MH muscle is hypersensitive. METHODS: Studies were performed of fiber bundles from the vastus lateralis muscle of persons who were deemed not MH susceptible (MH-) or MH susceptible (MH+) according to the MH diagnostic test and of strips of diaphragm muscle from rats. Preparations in a tissue bath containing Krebs solution were connected to a force transducer. ATX II was introduced 5 min before halothane, caffeine, or ryanodine. RESULTS: ATX II increased the magnitude of contracture to halothane in preparations from most MH-, but not MH+, human participants. After ATX II treatment, preparations from 9 of 24 MH- participants generated contractures to halothane, 3%, that were of the same magnitude as those from MH+ participants. Preparations from four of six ATX II-treated healthy participants also gave responses of the same magnitude as those of MH-susceptible participants to a graded halothane challenge (0.5-3%). The contractures to bolus doses of halothane in specimens from male participants were more than three times larger than the contractures in specimens from female participants. In rat muscle, ATX II increased the magnitude of contracture to caffeine (2 mM) and decreased the time to produce a 1-g contracture to ryanodine (1 microM). CONCLUSIONS: ATX II, which causes delayed inactivation of the Na+ channel in cell cultures similar to that reported in cultures of MH+ skeletal muscle, increased the sensitivity of normal muscle to three agents to which MH+ muscle is hypersensitive. The increased sensitivity to halothane, 3%, occurred in most (79%), but not all, MH- participants, and this effect was most evident in male participants. Therefore, abnormal function of the Na+ channel, even if it is a secondary event in MH, may contribute to a positive contracture test result for MH.     

Malignant hyperthermia: A disease of specific myofiber type?

The present study attempts to determine if malignant hyperthermia susceptibility (MHS) is limited to muscles composed predominantly of a single major fiber type. The MHS trapezius muscle (49 per cent type 1 and 51 per cent type 2 fibers) has greater abnormal contracture response to halothane or to caffeine than does MHS gracilis ( 11 per cent type 1 and 80 per cent type 2 fibers). The dynamic properties (contraction and relaxation times) of MHS trapezius and MHS gracilis are similar, suggesting that the greater contracture response of MHS trapezius to halothane or to caffeine is more biochemical than physiological in origin. The results of this study are discussed in relevance to the diagnosis and to aetiologic investigation of malignant hyperthermia.