Optimizing Local Anesthetic Concentration for Continuous Popliteal-Sciatic Nerve Blocks

Relatively Healthy Volunteers

A continuous peripheral nerve block-also termed perineural local anesthetic infusion-involves the insertion of a tiny tube (a catheter) through the skin and adjacent to a peripheral nerve, followed by local anesthetic (numbing medicine) administration via the catheter, providing pain control following surgery. Continuous peripheral nerve blocks may be provided in the hospital setting, but the use of lightweight, portable pumps permits infusion at home as well. However, it remains unknown if the concentration of the local anesthetic influences the block effects; or, is it rather simply the total dose of medication that is important. If it is the latter, then the concentration of local anesthetic could be increased, allowing a decreased basal infusion rate, which would allow patients at home to receive twice the duration of potent pain control since their infusion pump local anesthetic reservoir would last twice as long as current practice. In addition, if one concentration/dose combination results in less muscle weakness, but with at least equivalent analgesia, then the risk of falling might be decreased as well. The investigators will test the hypothesis that providing ropivacaine at different concentrations and rates (0.1% at 8 mL/hour vs. 0.4% at 2 mL/hour)-but at an equivalent total basal (8 mg/hour)-produces comparable effects when used in a continuous popliteal-sciatic nerve block.

The investigators therefore propose a volunteer-based clinical trial testing the hypothesis that providing ropivacaine at different concentrations and rates (0.1% at 8 mL/hour vs. 0.4% at 2 mL/hour)-but at an equivalent total basal dose (8 mg/hour)-produces comparable effects when infused for a continuous popliteal-sciatic nerve block. The primary endpoint will be tolerance to cutaneous electrical current applied on the plantar aspect of the foot. This is an objective endpoint that has been validated in multiple previous publications and correlates with intra- and post-operative pain. This investigation will be a randomized, observer-masked, controlled, split-body, human-subjects clinical trial. Enrollment. Subjects will be volunteers of both sexes, age 18 and older. Volunteers will be solicited using newspaper advertisements, fliers, and an existing database of volunteers (IRB approved). If a volunteer meets inclusion/exclusion criteria and desires study participation, written, informed consent will be obtained. Selection for inclusion will not be based on race or socioeconomic status. The study population of interest includes men and women of all races and socioeconomic status. A urine pregnancy test will be administered to all women of childbearing age following written informed consent but before any study interventions. This urine test will be administered by CTRI nursing staff using standard, FDA-approved urine pregnancy testing devices. Inclusion criteria for the trial will be: (1) age ≥ 18 years; and (2) willing to have bilateral femoral perineural catheters placed with a subsequent ropivacaine infusion and motor/sensory testing for 6 hours, requiring an overnight stay in the UCSD GCRC/CTRI to allow dissipation of local anesthetic infusion effects by the following morning. Exclusion criteria for the trial will be: (1) current daily analgesic use; (2) opioid use within the previous 4 weeks; (3) any neuro-muscular deficit of either femoral nerves and/or quadriceps muscles; (4) morbid obesity \[weight \> 35 kg/m2\]; (5) pregnancy (as determined by a urine pregnancy test prior to any study interventions); and (6) incarceration. We expect to recruit a maximum of 30 healthy volunteers; with a target goal of 24 for the analysis. Selection for inclusion will not be based on gender, race, or socioeconomic status. The study population of interest includes men and women of all races and socioeconomic status. There will be no participants from vulnerable populations, such as pregnant women, children, or prisoners Perineural catheter insertion. Following written, informed consent, subjects will be admitted to the UCSD CTRI and have demographic/morphometric data recorded (e.g., age, weight, height). An intravenous line will be placed in an upper extremity, followed by external monitors (pulse oximeter, blood pressure, and EKG), and oxygen by nasal cannula. Sedation will be provided with intravenous fentanyl (50 mcg) and/or midazolam (1 mg), or oral valium (10 mg) and/or dilaudid (4 mg), as necessary. Subjects will then have bilateral popliteal-sciatic perineural catheters placed using standard UC San Diego techniques as previously published by the current P.I.7,8 Treatment Group Assignment. Subjects will have the right-sided catheter randomly assigned to one of two treatment groups: a ropivacaine concentration of 0.1% or 0.4%. Subjects will act as their own controls, with the contralateral side receiving the alternative concentration. The Investigational Drug Service will prepare the randomization list as well as the two ropivacaine reservoirs and two electronic infusion pumps (SIGMA Spectrum Infusion System, Baxter Healthcare International, Deerfield, IL) used to infuse the ropivacaine. All pumps will be FDA approved for infusion of local anesthetic. The basal rate of each infusion will be determined by the ropivacaine concentration in each pump reservoir: 0.1% (8 mL/h) or 0.4% (2 mL/h). While the basal rate and bolus volume will differ for each concentration, the total dose of local anesthetic will be the same for both treatments (8 mg/h). The local anesthetic reservoirs will be contained within an opaque bag prepared by the Investigational Drug Service, and the infusion rates displayed on the pumps covered, ensuring masking for both the subjects and observers (clinical research nurse taking the measurements). Following 6 hours (48 mg), the infusions will be discontinued and the catheters removed. Treatment Group Basal Rate (mL/h) Basal Dose (mg/h) Total Dose (mg in 6 h) Ropivacaine 0.1% 8 8 48 Ropivacaine 0.4% 2 8 48 The tubing from the pumps to the subjects will be gently wound at least 5 rotations and covered with opaque tape, masking which perineural catheter is receiving which treatment (ropivacaine is clear, so the flow through the clear tubing from the tape to the perineural catheters will not be visually distinguishable). Subjects will remain within the CTRI until the following morning at least until Hour 22 for the final measurement; or, until their perineural infusion sensory and motor effects have resolved. If a subject requests early withdrawal from the study, they will remain in the CTRI until their perineural infusion sensory and motor effects have resolved. Outcome Measurements. The selected measures have established reliability and validity and minimal inter-rater discordance. Measurements will be performed at Hour 0 (baseline), and on the hour until Hour 14, as well as the following morning at Hour 22. In all cases, measurements will be taken in the supine position with the dominant side measured first, followed by the non-dominant side. Tolerance of transcutaneous electrical stimulation: Sensory perception-depth of analgesia-will be evaluated using tolerance of transcutaneous electrical stimulation with the same quantitative procedure validated and used in multiple clinical trials. Electrocardiogram pads are placed on the lateral aspect of the plantar surface of the foot which is covered by the sciatic nerve distribution; and, the tolerance to cutaneous electrical current is obtained using a nerve stimulator. The current is increased from 0 mA until subjects detect the electrical current (up to a maximum of 80 mA), at which time the current is recorded and the nerve stimulator turned off. Muscle strength: We will evaluate muscle strength with an isometric force electromechanical dynamometer to measure the force produced during a maximum voluntary isometric plantar-flexion (muscles innervated by the sciatic nerve). The dynamometer will be placed against the bed's foot board (immobile) and the subject will be asked to take 2 seconds to come to maximum effort contracting the target muscles, maintain this effort for 5 seconds, and then relax. The measurements immediately prior to perineural ropivacaine administration will be designated as baseline measurements, and all subsequent measurements will be expressed as a percentage of the pre-infusion baseline. Food and Drink: Both food and accompanying beverages/water will be provided by the hospital and served by the nursing staff immediately following catheter insertion. Meals will be provided without charge to the study subjects. There is no restriction on oral intake following catheter insertion. Statistical Analysis. Sample size calculations are based on the primary aim of determining the relationship between perineural ropivacaine concentration and continuous popliteal-sciatic nerve block effects. To this end, we will perform an equivalency trial with the primary endpoint designated as the maximum tolerance to transcutaneous electrical stimulation at Hour 6. We will aim to demonstrate that differing the concentration (0.1% vs. 0.4%) applied to different legs of each subject, but providing an equal total dose (8 mg/h) of ropivacaine through a popliteal-sciatic perineural catheter does not result in a significant difference in tolerance between legs at Hour 6. We will conclude that the interventions are equivalent if the 95% confidence interval for the mean difference in tolerance between legs is contained within the pre-specified tolerance interval of +/- 10 mA. This value is used as the minimally clinically-relevant current since it approximates the tolerated electrical current range at baseline of the general population-in other words, natural variability and therefore a relatively small amount of current to detect.4 Based on previously-published data,1,4 we assume the standard deviation of tolerance difference between legs is SD=13 mA. With n=24 subjects, we will correctly conclude equivalence with approximately 80% probability (power). Alternatively, if the population difference is 10 mA, we will correctly reject equivalence with probability 5%. The mean difference between treatments will be estimated by Analysis of Covariance (ANCOVA), using baseline tolerance difference as a covariate. Subjects will receive each of the two treatments applied randomly to the left and right legs. The same analyses will be applied to the secondary endpoints. Profiles of the responses over time will be examined with spaghetti and mean plots. Further secondary analyses will include mixed-effects modeling of the repeated measures. These models account for the hierarchical correlation of paired measures from each subject over time, and will be used to test the effects of subject characteristics, including sex, height, weight, body mass index, and age. The model will also allow simultaneous analysis of all observations while accounting for within-subject correlation, which can improve the standard errors of the estimated differential at each time point. The within-subject correlation will be modeled via a subject-specific random intercept. This is similar to a compound symmetric correlation structure without a random effect. The change from baseline, Y, for subject i and time t will be modeled with the linear mixed-effect model: Yi(t¬j) = Yi(0) β0 + 1{t¬j=1}β1 + … + 1{t¬j=9}β9 + bi + eij where 1{t¬j=k} is 1 if t¬j=k and 0 otherwise. The subject-specific random intercepts bi and residuals eij are assumed to follow a Gaussian distribution. We will present the estimated difference at each hour with unadjusted p-values, and p-values adjusted using the single-step method for simultaneous inference from parametric models. Analyses will be executed using R version 2.12 (http://www.r-project.org). Additional analyses will include the Mann-Whitney U for nonparametric comparisons and Fisher's exact test for categorical variables (InStat, GraphPad Software, San Diego, California, United States).

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