Neuromuscular dose-response studies: determining sample size.

BACKGROUND Investigators planning dose-response studies of neuromuscular blockers have rarely used a priori power analysis to determine the minimal sample size their protocols require. Institutional Review Boards and peer-reviewed journals now generally ask for this information. This study outlines a proposed method for meeting these requirements. METHODS The slopes of the dose-response relationships of eight neuromuscular blocking agents were determined using regression analysis. These values were substituted for γ in the Hill equation. When this is done, the coefficient of variation (COV) around the mean value of the ED₅₀ for each drug is easily calculated. Using these values, we performed an a priori one-sample two-tailed t-test of the means to determine the required sample size when the allowable error in the ED₅₀ was varied from ±10-20%. RESULTS The COV averaged 22% (range 15-27%). We used a COV value of 25% in determining the sample size. If the allowable error in finding the mean ED₅₀ is ±15%, a sample size of 24 is needed to achieve a power of 80%. Increasing 'accuracy' beyond this point requires increasing greater sample sizes (e.g. an 'n' of 37 for a ±12% error). CONCLUSIONS On the basis of the results of this retrospective analysis, a total sample size of not less than 24 subjects should be adequate for determining a neuromuscular blocking drug's clinical potency with a reasonable degree of assurance.

[1]  C. Lien,et al.  Determining the potency of neuromuscular blockers: are traditional methods flawed? , 2010, British journal of anaesthesia.

[2]  C. Lien Acceleromyography and mechanomyography for establishing potency of neuromuscular blocking agents: a randomized-controlled trial , 2010 .

[3]  L. Skovgaard,et al.  Good clinical research practice in pharmacodynamic studies of neuromuscular blocking agents II: the Stockholm revision , 2007, Acta anaesthesiologica Scandinavica.

[4]  Edgar Erdfelder,et al.  G*Power 3: A flexible statistical power analysis program for the social, behavioral, and biomedical sciences , 2007, Behavior research methods.

[5]  P. Rehak,et al.  Geographic Regional Differences in Rocuronium Bromide Dose–Response Relation and Time Course of Action: An Overlooked Factor in Determining Recommended Dosage , 2006, Anesthesiology.

[6]  A. Kopman,et al.  Dose–Response and Onset/Offset Characteristics of Rapacuronium , 2000, Anesthesiology.

[7]  A. Kopman,et al.  An Alternate Method for Estimating the Dose-Response Relationships of Neuromuscular Blocking Drugs , 2000, Anesthesia and Analgesia.

[8]  A. Turkistani,et al.  Comparative Clinical Pharmacology of Rocuronium, Cisatracurium, and Their Combination , 1998, Anesthesiology.

[9]  A. El-Bakry,et al.  Comparative potency of steroidal neuromuscular blocking drugs and isobolographic analysis of the interaction between rocuronium and other aminosteroids. , 1995, British journal of anaesthesia.

[10]  J. van Egmond,et al.  Muscle Paralysis by Rocuronium During Halothane, Enflurane, Isoflurane, and Total Intravenous Anesthesia , 1993, Anesthesia and analgesia.

[11]  F. Guirimand,et al.  Relative Potency of Vecuronium on the Diaphragm and the Adductor Pollicis , 1989, British journal of anaesthesia.

[12]  O. Meretoja,et al.  Two-dose technique to create an individual dose-response curve for atracurium. , 1989, Anesthesiology.

[13]  R. Katz Neuromuscular Effects of d-Tubocurarine, Edrophonium and Neostigmine in Man , 1967, Anesthesiology.