Effect of preemptive intravenous oxycodone on low-dose bupivacaine spinal anesthesia with intrathecal sufentanil

Methods

This study was approved by the Institutional Ethics Committee and carried out at the First Hospital of Jilin University, Jilin, China. Written informed consent was obtained from 60 patients with American Society of Anesthesiologists (ASA) physical status I to II undergoing elective TURP for benign prostatic hypertrophy between March and September 2014. The patients were double blindly randomized into 2 groups (oxycodone [group O], n=30; normal saline [group N], n=30). Simple randomization was accomplished with a computer-generated sequence of numbers and sealed envelopes were used to divide patients into 2 groups. One of the researchers prepared the study drug before anesthesia. The anesthetic administrator and the patients were unaware of the group allocation. Patients with histories of substance abuse, mental disturbance and neurological disease, who have allergic reactions to the study drugs, with liver or renal dysfunctions, infection at spinal puncture sites, coagulopathy, and ASA III, and above were excluded from the study.

Routine monitorization including electrocardiogram, noninvasive blood pressure (BP) and oxygen saturation (SpO₂) was performed for patients taken to the operation room without premedication. A 16 gauge intravenous canula was sited. Before spinal anesthesia, the patients received 5 ml/kg normal saline over 20 minutes (min). The intravenous infusion was minimally maintained during the surgical procedure to avoid the fluid overloading associated with the absorption of irrigating fluid. Patients received bupivacaine 0.8 ml+sufentanil 0.1 ml (5 µg)+normal saline 0.7 ml - in total, bupivacaine 0.25% (1.6 ml) intrathecally. Spinal puncture was performed at L3-4, or L4-5 with a 25 G Quincke needle with the patient in a right-side lying position. The drug solution was given between 10 to 15 seconds (s) with cephalad orientation of the spinal needle bevel, after spinal puncture was successful. Patients were placed in a supine position, and their heads were tilted up 30°. Ten min. after spinal injection, 0.1mg/kg oxycodone (oxycodone hydrochloride injection, 10 mg/ml, HAMOL Limited, Nottingham, UK) diluted with normal saline to obtain a concentration of 1 mg/ml, or normal saline 0.1 ml/kg was injected slowly into the vein for 2 min in group O, or group N. The operation began 10 min later. Data regarding preoperative ultrasound-estimated prostate volume was collected, and mean blood pressure (MBP) and heart rate (HR) were recorded every 5 min until the end of surgery. Hypotension was defined by a decrease in SBP of <90 mm Hg, or <75% from the baseline value, and bradycardia was defined as HR <45 beat/min. In those cases, 4 mg of ephedrine or 0.5 mg of atropine was intravenously injected. When the patients complained of pain, 100 µg fentanyl was intravenously administered. If additional doses were necessary, the patient was excluded from the study, and general anesthesia was induced. The patients were observed in the recovery room, and in the in-patient clinic for the first 24 hours (h). The sensory block level, defined as the dermatomal segment with loss of pain sense to pin-prick test with a 22 G hypodermic needle on each side of the midthoracic line, was checked every 2 min from the drug injection until it reached the peak level, and then every 10 min during the surgery. The peak block level was selected as the same block level that could last for 4 consecutive tests. In cases with a discrepancy in the sensory block level between the 2 sides, the higher block level was chosen. We recorded the peak sensory block level, time to peak block level from intrathecal injection, time to 2-segment regression, the degree of peak motor block, time to peak motor block, use of supplemental analgesics intraoperatively, and time to the first analgesic request after operation. The degree of motor block was assessed with Bromage scale: 1 - complete motor block; 2 - almost complete motor block: able only to move the feet; 3 - partial motor block: able to move the knees; 4 - detectable weakness of hip flexion: able to raise the leg but is unable to keep it raised; 5 - no detectable weakness of hip flexion: can keep the leg raised for 10 s at least; 6 - no weakness at all.

The time to the first analgesic request (tramadol) was recorded. An independent investigator assessed the pain scales using the visual analogue scale (VAS: 0- no pain; 1, 2, 3 - mild pain; 4, 5, 6 - moderate pain; 7, 8, 9 - severe pain; 10 - the worst pain the patient had ever experienced) and the sedation score using Ramsay sedation scale (1 - anxious and agitated; 2 - cooperative and tranquil; 3 - drowsy but responds to command; 4 - asleep but responds to tactile stimulation; and 5 - asleep and no response). The study ended 24 hours after all data had been obtained. The VAS scores and Ramsay scores were recorded at 1, 2, 4, 8, 16, and 24 hours after the end of surgery. The total number of patients who required analgesics in the first 24 hours postoperatively was recorded. Adverse events such as hypotension, bradycardia, respiratory depression, nausea or/and vomiting, and pruritus were observed and recorded during the surgical procedure, and the first 24 h postoperatively. The incidence of adverse effects was evaluated with a “yes” or “no” survey.

Assuming that preemptive oxycodone would prolong time to the first analgesic request by 30 min. Twenty-three patients in each group were needed to detect the difference with a power of 90% at 5% significance level using the Statistical Package for Social Sciences version 17 (SPSS Inc., Chicago, IL, USA). Thirty patients were enrolled per group for possible dropouts. The results were shown as mean ± standard deviation (SD) and number of patients (percentage). Statistical analysis was performed using SPSS 17.0. Independent sample t-test was used to assess most of the demographic data (age, weight, and height), the duration of the operation, preoperative prostate volume, time to reach peak sensory block level, time to reach peak motor block level, time to 2-segment regression of sensory block, time to full recovery of motor block, time to full recovery of the sensory block, VAS scores, time to the first analgesic request, MBP, and HR at the same time point between groups. Changes in MBP and HR at various time points within each group were tested with ANOVA for repeated measures. The peak motor block level and the peak sensory block level were compared using the Mann-Whitney U-test. Categorical variables, such as American Society of Anesthesiologists physical status, the incidence of ephedrine and analgesic use, and adverse effects were analyzed between 2 groups with either chi-square statistics, or Fisher’s exact test. P<0.05 was considered statistically significant.