THE first descriptions of the syndrome that would eventually be named malignant hyperthermia (MH) were made in the early 1960s. 1By 1970, it became clear that alterations in skeletal muscle constituted the primary defect in MH. Through the collaboration of an outstanding pharmacologist, Werner Kalow, and a thoughtful clinical anesthesiologist, Beverly Britt, the basic elements of the common test for MH were described. Kalow and Britt subjected biopsied muscle to graded increments of caffeine, demonstrating a leftward shift of the dose–response curve in muscle from patients who had experienced an episode of MH. 2Ellis et al.  3described how muscle from these patients developed contractures to clinical concentrations of halothane in vitro . Between 1970 and 1985, testing was standardized (e.g. , which muscle to biopsy, exposure regimens, diagnostic thresholds) to develop an accurate diagnostic test for MH. Two slightly different protocols emerged: a European version and a North American version, both using halothane alone and caffeine alone as the testing reagents. 4,5Meanwhile, in Japan, a slightly different approach was developed using muscle fibers that were chemically or mechanically “skinned.” This review summarizes the clinical evaluation of the patient with presumed MH susceptibility (MHS) and describe tests that are used in this evaluation.

In general, suitable patients for biopsy include those with a family history of MH or who display unexplained hypercarbia, and those who exhibit perioperative rhabdomyolysis (table 1). By itself, massive rhabdomyolysis in association with hyperkalemia and cardiac arrest is usually not MH. Nonetheless, some experts advise muscle biopsy, as much for histology and analysis for dystrophin to detect muscular dystrophy as to exclude MH. Exercise-induced rhabdomyolysis has also been associated with MH. 6MH is a hypermetabolic disorder, and many other diseases and conditions can mimic it. Modern anesthetic techniques and drugs seem to retard the development of an MH episode, relative to the classic fulminant episode, e.g. , marked hypermetabolism, hyperthermia, acidosis, rhabdomyolysis, and cardiac arrhythmias. This led to the development of a clinical grading scale to estimate the likelihood that an MH episode has occurred. 7The scale incorporates six clinical criteria: evidence of muscle rigidity, muscle breakdown, respiratory acidosis, temperature increase, cardiac involvement, and family history (table 2). The likelihood of MH increases if the patient has manifested multiple signs of MH. However, in the absence of certain laboratory values or incomplete vital signs, the grading scale loses power and might underestimate the probability of MH. The appropriate course is to have the patient and family evaluated for MHS at an MH biopsy center; this might include biopsy of both parents of a patient with possible MHS.

Table 1. NA

* Web site of the Malignant Hyperthermia Association of the US. Accessed September 2001.

† Web site of the European MH Group. Accessed September 2001.

Table 1. NA
Table 1. NA

Table 2. NA

CO2= carbon dioxide; Paco2= arterial carbon dioxide tension; MH = malignant hyperthermia.

Table 2. NA
Table 2. NA

Regional anesthesia using nerve blocks or neuroaxial blocks is usually employed for muscle biopsy, supplemented with sedation as needed. Some clinicians supplement a nontrigger general anesthetic with a nerve block. Direct muscle infiltration with local anesthetic is contraindicated because it could adversely affect tissue viability. Most centers do not perform biopsies in patients aged less than 5 yr because of the amount of muscle required to be harvested. The procedure is usually performed on an outpatient basis. Proper surgical technique is crucial. The surgeon must not use electrocautery or stretch the muscle.

The Caffeine–Halothane Contracture Test

The caffeine–halothane contracture test (CHCT) requires approximately 2 g of muscle excised from the vastus lateralis or vastus medialis muscle. In the laboratory, the muscle is longitudinally dissected into strips. Small sutures are placed at both ends, and the strips are mounted into baths, with one end attached to a stationary hook and the other to a force transducer. Electrical stimulation resulting in muscle contraction (twitching) confirms tissue viability. Six muscle strips are mounted. In the North American protocol, halothane (3%) is added to the gas flow to three baths via  an in-line vaporizer, while caffeine is added incrementally to the other three. The diagnostic end point is the development of a contracture, which is an increase in baseline muscle tension. If a contracture of 0.7 g or greater develops in any halothane-exposed muscle strip or if a contracture of 0.3 g or greater develops in any strip exposed to caffeine at 0.5, 1, or 2 mm, then the test is considered to be positive, and the patient has MHS (figs. 1A and B). Contractures of 0.5–0.69 g to 3% halothane are sometimes classified as MH equivocal. The addition of ryanodine or 4-chloro-m-cresol to the baths can increase the accuracy of the CHCT. 8 

Fig. 1. (A ) Abnormal (positive) response to 3% halothane. Each small box represents 0.1 g tension. The contracture response in this case is 1.6 g. A normal response to 3% halothane is a contracture up to 0.7 g. After exposure to halothane, 32 mm caffeine is added to the bath to determine maximal response. (B ) Abnormal (positive) response to caffeine. Caffeine exposure is to 0.5, 1.0, 2.0, 4.0, 8.0, and 32 mm for 4 min. A contracture of greater than 0.3 g to 2 mm caffeine or less indicates susceptibility.

Fig. 1. (A ) Abnormal (positive) response to 3% halothane. Each small box represents 0.1 g tension. The contracture response in this case is 1.6 g. A normal response to 3% halothane is a contracture up to 0.7 g. After exposure to halothane, 32 mm caffeine is added to the bath to determine maximal response. (B ) Abnormal (positive) response to caffeine. Caffeine exposure is to 0.5, 1.0, 2.0, 4.0, 8.0, and 32 mm for 4 min. A contracture of greater than 0.3 g to 2 mm caffeine or less indicates susceptibility.

Close modal

It is important that a small amount of muscle undergoes microscopic examination to detect structural abnormalities, which might include central cores, internal nuclei, and marked variation in fiber diameter. Histologic examination by itself cannot be used to diagnose MHS specifically—the defect is functional, not structural.

Occasionally, the biopsy results might be normal, but microscopic examination reveals muscular dystrophy, in which case, the patient must not be administered succinylcholine because this could lead to massive rhabdomyolysis and life-threatening hyperkalemia. Many recommend avoidance of volatile anesthetics.

The European MH CHCT protocol differs slightly from the North American CHCT protocol. 9The European protocol uses more increments in the caffeine and halothane concentrations, which lead to lower diagnostic thresholds. Several studies have evaluated the outcome of the testing procedures when applied to muscle from the same patient. In one study, 1 of 48 patients was positive to the North American protocol but negative to the European protocol. 9In a second study, 5 of 74 patients tested positive with the European protocol but negative with North American protocol. 10Conversely, 8 of 48 patients who tested negative with the North American protocol were MH equivocal with the European testing protocol. In the second study, 9 of 74 patients who tested negative with the North American protocol were MH equivocal with the European version. 10In a recent study in which muscle was harvested and tested in one European center and a portion was transported and tested in a nearby center, there was a 12% discordance in diagnostic conclusions for MHS. That is, one center determined that the patient had MHS, and the other determined that the patient was MH negative. This finding indicates that refinements in testing protocols are still required. 11In Japan, a different method has been used. Skeletal muscle fibers are chemically or mechanically “skinned,”i.e. , the sarcolemma is removed, leaving the sarcoplasmic reticulum, actin, and myosin and other proteins intact. Contractures to halothane and caffeine are assessed. Insufficient data exist comparing the Japanese protocol to the European or North American protocols.

To define the sensitivity, specificity, and predictive value of a diagnostic test, known positive subjects and known controls for the disorder must be studied, and the probability that the individual being tested has MH should also be estimated. Inasmuch as the phenotypic and clinical presentation is variable, researchers have relied on using individuals who have had an unequivocal MH episode. The diagnostic thresholds are adjusted to maximize sensitivity, thereby minimizing false negatives. Currently, the North American and European tests are 97–99% sensitive (i.e. , 1–3% false negatives). This sacrifices specificity, so that 10–15% of normal patients will have false-positive tests. 12The specificity of the European protocol (≈ 90%) is greater than that of the North American protocol (≈ 80–85%). For unclear reasons, the lower specificity in the North American protocol is related to center-to-center variability and not within-center variability. This specificity and low prevalence of susceptibility for MH limits the test as a screening tool. 13The consensus among MH experts is that it is probably safer to label a healthy person MH susceptible than to label an MH patient nonsusceptible. This is based on the thought that it is easier to administer a nontriggering anesthetic than to treat a patient with full-blown MH. The disadvantage of this approach is that not only are some patients falsely labeled, but so too are members of their families. Because there is a significant false-positive response and a low prevalence of MH (perhaps 1 in 50,000), the positive predictive value of the contracture test is low. 13By selecting those patients with a high likelihood of MH based on the clinical grading scale, 7the positive predictive value may be improved. However, the negative predictive value is excellent because of the test's high sensitivity and the relative lack of effect of pretest probability. 13Other pharmacologic agents (primarily ryanodine and chlorocresol) that alter intracellular calcium homeostasis have been integrated into the standard testing procedures in hopes of minimizing intermediate responses.

The CHCT has been standardized using freshly harvested tissue from the vastus lateralis or medialis muscles, so the patient must present to the biopsy center. The test must be completed within approximately 5 h after muscle harvest. After the biopsy, there is a period of relative disability of 2–7 days, depending on one's occupation and activity level. The cost of the procedure, based on operating room time, surgical and pathology fees, and testing costs, can easily reach $6,000. There are 22 biopsy centers in Europe and 12 in North America. Each center performs 10–40 biopsies per year.

For one of the few (if not only) remaining physiologic in vitro  diagnostic tests in medicine, the CHCT has served well. However, refinements of the testing procedure have continued for several reasons:

  • 1. Although most specimens from a biopsy respond in an identical manner, some (perhaps 30%) do not. 11 

  • 2. There is not a distinct separation of MH nonresponders and MH-susceptible patients; intermediate values are found in 10–15% of patients. Therefore, it is necessary to determine a threshold to separate the groups.

  • 3. The test involves biologic material that degrades with time, and it is not possible to create a standard that can be shared among all laboratories.

  • 4. Patients with myopathies whose basic defect entails increased intracellular calcium, such as muscular dystrophy, may display abnormal contractures to halothane and caffeine.

  • 5. The lack of a common structural defect in MH muscle diminishes the usefulness of histologic examination as a diagnostic test.

Most recently, the demonstration that a mutation in the gene that encodes the calcium release channel (the ryanodine receptor, RYR-1) underlies porcine MH increased the expectation of a simple DNA-based test for MH in humans as well. 14That expectation has not yet been realized. There are many mutations in skeletal muscle that may be causal for different forms of the syndrome. However, with time, an accurate DNA-based test that is applicable to most patients will become available. A significant international effort is underway to clarify the molecular genetic basis for MH. At least four gene loci have been associated with MHS. However, linkage analysis reveals that approximately 50% of MH families are genetically linked to the RYR-1  gene located on chromosome 19q 12-13. To date, 23 missense mutations in the gene have been reported to segregate with MHS in European and North American families. Most are clustered in two regions. Brandt et al.  15have reported that 25% of patients from 105 families diagnosed as MH susceptible by the CHCT have RYR  mutations. Sambuughin et al.  16have reported similar findings, but the distribution of mutations in these North American families differed from those reported by Brandt et al.  15from Germany. The largest genetic analysis from one family showed variable concordance between genetic mutation in the RYR-1  gene and the CHCT, depending on the thresholds used for the CHCT. 17Discordance of phenotype and genotype in this family was likely due to a second mutation causative for MHS. 17A recent article and its accompanying editorial highlighted the quandary of genetic testing of MHS. Urwyler et al.  18described the heterogeneity of genetic defects in European patients with MHS. They emphasized that genetic testing cannot currently stand alone in the absence of contracture testing. Likewise, Robinson and Hopkins 19stated that although genetic testing must continue, contracture testing must continue to be the basis of MH evaluation. Therefore, we believe that when possible and appropriate, molecular genetic analysis should be used in some families to supplement the CHCT.

Several other tests have been proposed or are being investigated as less-invasive diagnostic tests. Approaches with limited or no value (calcium uptake–calcium adenosine triphosphatase, lymphocyte calcium test, platelet adenosine triphosphatase) have been abandoned. Other tests show some promise of at least providing a less-invasive test to determine susceptibility of relatives of known MH positive individuals.

Creatine Kinase

Creatine kinase concentrations are chronically increased in perhaps 50% of MH patients. However, creatine kinase is increased in many myopathic diseases and may be increased secondary to trauma. Therefore, its sensitivity and specificity are not satisfactory for it to be used for routine testing. If a first-degree relative of a patient with known MHS has increased creatine kinase, they are highly likely to have MHS as well. 20 

Nuclear Magnetic Resonance Spectroscopy

Nuclear magnetic resonance spectroscopy measures the concentrations of adenosine triphosphate, phosphocreatine, and other phosphomonoesters, along with pH, both in vivo  and noninvasively, in muscle and other tissue. Several studies have shown delayed reconstitution of pH, adenosine triphosphate, and increased phosphocreatine in MH patients during and after graded exercise. A recent study reports 100% concordance between abnormalities in adenosine triphosphate and high-energy phosphates produced by a specific exercise protocol and the results of muscle biopsy. 21Most patients were analyzed post hoc  with nuclear magnetic resonance spectroscopy techniques; only 10 were analyzed prospectively using both nuclear magnetic resonance spectroscopy and halothane–caffeine testing. One drawback of nuclear magnetic resonance spectroscopy is the requirement for expensive, technologically sophisticated equipment, along with personnel trained in the interpretation of the spectra. It is also known that changes similar to those found in MH patients can be found in a variety of myopathies.

Lymphocyte Tests

Recently, Sei et al.  22have shown RYR-1  receptors on B lymphocytes in humans. This implied that these cells might demonstrate changes in calcium flux similar to those demonstrated in muscle. They found that lymphocytes from MH patients, when incubated with 4-chloro-m-cresol, showed increased intracellular calcium concentrations. However, halothane did not affect intracellular calcium concentrations.

Cultured Muscle Cells

Censier et al.  23have also shown enhanced intracellular calcium release from muscle cultured from MH-susceptible patients. Further studies (including patients with other muscle diseases) are required to define the sensitivity and specificity of the technique.

The CHCT, by diagnosing MHS in a meaningful way, provides clinical information for patients and anesthesia providers. Genetic testing has emerged as a viable supplement to the CHCT. Far too much emphasis has been placed on the limitations of the contracture test (e.g. , the 10–15% false-positive rate and the need for fresh viable muscle) without recognition of the test's value. The following considerations are useful when judging the importance of the CHCT in evaluation of MHS:

  • 1. In the vast majority of circumstances, differentiation can be made between normal and abnormal responders.

  • 2. Establishing an MH-positive or -negative diagnosis has clinical significance for the individual and his or her family in terms of subsequent anesthetic treatment.

  • 3. There are many families in which relatives of a patient who died from MH or presumed MH have clearly abnormal responses on the CHCT.

  • 4. The inheritance of MHS as determined by the CHCT follows a specific autosomal dominant pattern, just as the clinical syndrome does.

  • 5. Similar patterns of response to halothane, caffeine, ryanodine, and 4-chloro-m-cresol have been found in testing centers throughout the world.

  • 6. The objective responses observed in muscle tissue form the basis for identifying genetic mutations causal for MH. Although there are discrepancies between presence of ryanodine mutations and contracture responses to test agents, there are families in which there is excellent agreement. Identification of the genetic defect or defects in MH and related disorders will ultimately lead to a better understanding of the biochemical changes that underpin an MH reaction. Progress in identifying the genetic basis for MH will be limited without the CHCT. Continued testing is essential for the development of the next generation of less-invasive, hopefully more accurate techniques, such as genetic or lymphocyte testing based on blood samples.

The authors thank Barbara Brandom, M.D. (Professor of Anesthesiology, University of Pittsburgh, Pittsburgh, PA), for her constructive comments.

Denborough MA, Lovell RRH: Anaesthetic deaths in a family (letter). Lancet 1960; 2: 45
Kalow W, Britt BA, Richter A: The caffeine test of isolated human muscle in relation to malignant hyperthermia. Can Anaesth Soc J 1977; 24: 678–94
Ellis FR, Harriman DGF, Keaney NP, Kyei-Mensah K, Tyrell JH: Halothane induced muscle contracture as a cause of hyperpyrexia. Br J Anaesth 1971; 43: 721–4
Anonymous: A protocol for the investigation of malignant hyperpyrexia (MH) susceptibility. The Malignant Hyperpyrexia Group. Br J Anaesth 1984; 56: 1267–9
Larach MG: Standardization of the caffeine halothane muscle contracture test. North American Malignant Hyperthermia Group. Anesth Analg 1989; 69: 511–5
Wappler F, Fiege M, Steinfath M, Agarwal K, Scholz J, Singh S, Matschke J, Schulte am Esch J: Evidence for susceptibility to malignant hyperthermia in patients with exercise-induced rhabdomyolysis. A nesthesiology 2001; 94: 95–100
Larach MG, Localio AR, Allen GC, Denborough MA, Ellis FR, Gronert GA, Kaplan RF, Muldoon SM, Nelson TE, Ording H, Rosenberg H, Waud BE, Wedel DJ: A clinical grading scale to predict malignant hyperthermia susceptibility. A nesthesiology 1994; 80: 771–9
Baur CP, Bellon L, Felleiter P, Fiege M, Fricker R, Glahn K, Heffron JJA, Herrmann-Frank A, Jurkat-Rott K, Klingler W, Lehane M, Ording H, Tegazzin V, Wappler F, Georgieff M, Lehmann-Horn F: A multicenter study of 4-chloro-m-cresol for diagnosing malignant hyperthermia susceptibility. Anesth Analg 2000; 90: 200–5
Fletcher JE, Rosenberg H, Aggarwal M: Comparison of European and North American malignant hyperthermia diagnostic protocol outcomes for use in genetic studies. A nesthesiology 1999; 90: 654–61
Islander G, Twetman ER: Comparison between the European and North American protocols for diagnosis of malignant hyperthermia susceptibility in humans. Anesth Analg 1999; 88: 1155–60
Ording H, Islander G, Bendixin D, Ranklev-Twetman E: Between-center variability of results of the in vitro contracture test for malignant hyperthermia susceptibility. Anesth Analg 2000; 91: 452–7
Allen GC, Larach MG, Kunselman AR: The sensitivity and specificity of the caffeine-halothane contracture test: a report from the North American Malignant Hyperthermia Registry. The North American Malignant Hyperthermia Registry of MHAUS. A nesthesiology 1998; 88: 579–88
Loke JC, MacLennan DH: Bayesian modeling of muscle biopsy contracture testing for malignant hyperthermia susceptibility. A nesthesiology 1998; 88: 589–600
Gillard EF, Otsu K, Fujii J, Khanna VK, de Leon S, Derdemezi J, Britt BA, Duff CL, Worton RG, MacLennan DH: A substitution of cysteine for arginine 614 in the ryanodine receptor is potentially causative of human malignant hyperthermia. Genomics 1991; 11: 751–5
Brandt A, Schleithoff L, Jurkat-Rott K, Klingler W, Baur C, Lehmann-Horn F: Screening of the ryanodine receptor gene in 105 malignant hyperthermia families: Novel mutations and concordance with the in vitro contracture test. Hum Mol Genetics 1999; 8: 2055–62
Sambuughin N, Sei Y, Gallagher KL, Wyre HW, Madsen D, Nelson TE, Fletcher JE, Rosenberg H, Muldoon SM: North American malignant hyperthermia population: Screening of the ryanodine receptor gene and identification of novel mutations. A nesthesiology 2001; 95: 594–9
Brown RL, Pollock AN, Couchman KG, Hodges M, Hutchinson DO, Waaka R, Lynch P, McCarthy TV, Stowell KM: A novel ryanodine receptor mutation and genotype-phenotype correlation in a large malignant hyperthermia New Zealand Maori pedigree. Hum Mol Genetics 2000; 9: 1515–24
Urwyler A, Deufel T, McCarthy T, West S, for the European Malignant Hyperthermia Group: Guidelines for molecular genetic detection of susceptibility to malignant hyperthermia. Br J Anaesth 2001; 86: 283–7
for the European Malignant Hyperthermia Group:
Robinson RL, Hopkins PM: A breakthrough in the genetic diagnosis of malignant hyperthermia. Br J Anaesth 2001; 86: 166–8
Gronert GA, Antognini JF, Pessah IN: Malignant hyperthermia, Anesthesia, 5th edition. Edited by Miller RD. Philadelphia, Churchill-Livingstone, 2000, pp 1033–52
Bendahan D, Kozak-Ribbens G, Rodet L, Confort-Gouny S, Cozzone PJ: 31-Phosphorus magnetic resonance spectroscopy characterization of muscular metabolic anomalies in patients with malignant hyperthermia: Application to diagnosis. A nesthesiology 1998; 88: 96–107
Sei Y, Gallagher KL, Basile AS: Skeletal muscle type-like ryanodine receptor is involved in calcium signaling in human B-lymphocytes. J Biol Chem 1999; 274: 5995–6002
Censier K, Urwyler A, Zorzato F, Treves S: Intracellular calcium homeostasis in human primary muscle cells from malignant hyperthermia-susceptible and normal individuals. J Clin Invest 1998; 101: 1233–42