Lev Langerman

HOT PLATE VERSUS TAIL FLICK : EVALUATION OF ACUTE TOLERANCE TO CONTINUOUS MORPHINE INFUSION IN THE RAT MODEL

The development of tolerance to continuous morphine infusion (2, 4 and 6 mg x kg(-1) x hr(-1) was assessed in rats using two different methods for evaluation of nociception, tail flick (TF) and hot plate (HP). The influence of repeated testing on nociception was evaluated using two regimens; series 1 was tested repeatedly 1, 2, 4, 6, and 8 hr after initiating the morphine infusion and series 2 was tested only twice, at maximum morphine effect and at 8 hr. Both, TF and HP showed pain threshold elevation after the morphine administration of 4 or 6 mg x kg(-1) x hr(-1), which reached a maximum at 2 hr after the start of the infusion. HP: reduction of the effect was found in group 4 mg x kg(-1) x hr(-1) in the series subjected to repeated testing; group 6 mg x kg(-1) x hr(-1) showed reduced effect in both sides. TF: the response latencies did not show reduction at 8 hr. Since TF is predominantly a spinal response and HP is predominantly supraspinal, the results suggest that tolerance during the first 8 hr of morphine infusion develops mainly at supraspinal level.

Prolongation of epidural anesthesia using a lipid drug carrier with procaine, lidocaine, and tetracaine

This study evaluated the effect of a lipid drug carrier (iophendylate) on epidural anesthesia. The intensity and duration of motor blockade produced by aqueous and lipid preparations of local anesthetics were assessed in rabbits with long-term indwelling catheters in the epidural space. Motor blockades produced by procaine (1%, 2%, and 4%), lidocaine (1%, 2%, and 4%), and tetracaine (0.5%, 1%, and 2%) in normal saline solution were compared with the effects produced by equimolar amounts of the drug solutions in iophendylate. Procaine (4%) in aqueous solution produced motor blockade lasting 30 +/- 3.54 min (mean +/- SD) versus 84 +/- 4.18 min in lipid solution. Lidocaine (2% and 4%) in aqueous solution produced motor blockade lasting 41 +/- 4.18 and 65 +/- 6.12 min versus 39 +/- 4.18 and 118 +/- 10.1 min, respectively, in lipid solution. Aqueous tetracaine (0.5%, 1%, and 2%) produced motor blockade of 106 +/- 9.62, 189 +/- 6.52, and 273 +/- 26.8 min versus 284 +/- 14.7, 335 +/- 15.8, and 365 +/- 26.9 min, respectively, in their lipid counterparts. A control group of animals that received normal saline solution or iophendylate alone did not exhibit motor blockade. These results may be attributed to sustained release of local anesthetics from the lipid vehicle. Hence, lipid drug carriers may be effective in prolonging epidural anesthesia.

The partition coefficient as a predictor of local anesthetic potency for spinal anesthesia : evaluation of five local anesthetics in a mouse model

Local anesthetic partition coefficients correlate with drug potencies in vitro, but in vivo data have not always complimented in vitro results. Despite extensive studies on intrathecal anesthetic action, whether there is correlation between the partition coefficient and local anesthetic potency has not been addressed. Mice (n = 150) were randomly allocated into 15 groups. Intrathecal injections of etidocaine (E), tetracaine (T), bupivacaine (B), lidocaine (L), or procaine (P) were administered and analgetic effect was measured using tail-flick (TF) test. Concentration-response regressions were constructed for each drug; EC50 values were calculated and compared at 95% confidence intervals. The EC50 values between E (0.017%), T (0.019%), and B (0.012%) were not significantly variant. The EC50 of L (0.098%) and P (0.229%) were significantly different from each other and from E, T, and B. The EC50 values were converted to ED50 in nmols. Relative anesthetic potency, defined as the inverse value of ED50 of drug was 23:16:15:2.4:1 for B, E, T, L, and P, respectively. ED50 showed high correlation (R = 0.978) with partition coefficients of local anesthetics. This study implies that the partition coefficient is a predictor of intrathecal local anesthetic potency. We suggest that the mouse model is reliable for evaluation of intrathecal local anesthetic action.

SPINAL ANESTHESIA : SIGNIFICANT PROLONGATION OF THE PHARMACOLOGIC EFFECT OF TETRACAINE WITH LIPID SOLUTION OF THE AGENT

A novel approach for increasing the duration of anesthesia after a single subarachnoid injection of a local anesthetic is presented. Tetracaine 1% 0.5 mg/kg was administered in 10% glucose or in lipid solution (iophendylate) in two groups of rabbits via catheters chronically implanted in the subarachnoid space. The pharmacologic effect was assessed by evaluation of the intensity and duration of the motor blockade according to a three-stage scale. Significant prolongation (447 +/- 13 min vs. 130 +/- 7 min, P less than 0.01) with a moderate decrease in the intensity of the motor blockade was observed with lipid solution as compared to the aqueous solution. This effect is attributed to the slow release of the agent from the lipid phase, which actually functions as a drug depot in the cerebrospinal fluid. The proposed method is suggested as an additional approach for the development of drug delivery system intended for prolongation of spinal anesthesia.

Prolonged analgesia and decreased toxicity with liposomal morphine in a mouse model.

Inadequate control of postoperative pain remains a major clinical problem. A reliable method of providing long-lasting postoperative analgesia with a single dose would be very useful. We synthesized a liposomal morphine formulation and compared it to free morphine with regard to duration of analgesia in the mouse. Analgesia was assessed after intraperitoneal injection using the tail-flick test. The systemic toxicity after administration of liposomal and free morphine was compared. The release rate of morphine from liposomes in vitro was also evaluated. The lethal intraperitoneal dose of free morphine in 50% of mice (LD50) was 400 mg/kg. The maximum safe (non-lethal) dose of free morphine was 130 mg/kg. The highest dose of liposomal morphine administered (1650 mg/kg) did not cause death in any animal. Duration of analgesia was significantly prolonged with the highest dose of liposomal morphine (21.5 +/- 5.3 h) compared to the maximum safe dose of free morphine (3.7 +/- 0.75 h), P < 0.01. In vitro experiments showed a slow release rate of morphine from the liposome depot. Prolonged analgesia and decreased systemic toxicity for liposomal morphine are explained by sustained release of morphine from the liposomal depot. These results suggest that liposomal narcotic formulations may provide prolonged analgesia with single-dose administration.

A rat sciatic nerve model for independent assessment of sensory and motor block induced by local anesthetics.

The purpose of this study was to develop a reliable model to independently quantify motor and sensory block produced by local anesthetics. The sciatic nerve was blocked in 52 rats by injecting 0.2 mL of 0.125%, 0.25%, 0.5%, or 0.75% bupivacaine (n = 13 for each concentration). Accurate needle placement was achieved using a nerve stimulator at 0.2 mA and 1 Hz. Ten control rats received 0.9% saline (n = 5) or sham nerve stimulation (n = 5). Motor block was assessed by measuring hindpaw grip strength with a dynamometer. Sensory block was determined by measuring hindpaw withdrawal latency from radiant heat. The intensity of both motor and sensory block measured at 30-min intervals was plotted against time until full recovery to obtain the area under the curve. Intergroup comparisons using analysis of variance showed increasing area under the curve with increasing concentrations of bupivacaine for motor blocks (P < 0.05 for all intergroup comparisons except 0.5% vs 0.75%) and sensory blocks (P < 0.05 for all intergroup comparisons). Normal saline or sham nerve stimulation did not result in any motor or sensory block.

Quantifiable dose-dependent withdrawal after morphine discontinuation in a rat model.

We evaluated the intensity of the withdrawal symptoms after the discontinuation of the morphine infusion in rats. Opiate addiction was induced by progressively increasing intraperitoneal morphine infusion rates. The control group (Group 1) received normal saline. The initial morphine rates were 1, 4, and 16 mg kg(-1) h for Groups 2, 3, and 4, respectively. Infusion rates were gradually increased by a factor of 1.4, 2, 2.8, and 4 on the second, third, fourth, and fifth days, respectively. The last rate was used for 48 h and then infusions were disconnected. Weight reduction, food consumption, and water intake were used for evaluation of withdrawal. All morphine groups showed a significant reduction of body weight during the 4 postdiscontinuation days and a decline in food and water intake on the first postdiscontinuation day. All changes were dependent on the morphine infusion concentration. No changes were observed in the control group. We suggest that the rat model used in this study may be utilized for quantification of spontaneous withdrawal.

Assessing local anesthetic effect using the mouse tail flick test

We used the tail flick test to quantify duration of local anesthetic-induced conduction block in the mouse. Using a baseline tail flick latency (TFL) between 1.0 and 2.5 sec, sensory block was considered present if TFL was > or = 4 sec. Two 20-microL local anesthetic injections were made on opposite sides of the tail base. TFL was tested every 10 min, and local block duration was interpreted as the time to return of TFL to < 4 sec. We tested three different concentrations of procaine (1%, 2%, and 4%), tetracaine (0.125%, 0.5%, and 1%), and lidocaine (0.5%, 1%, and 2%) with and without epinephrine. The testing method could discriminate between the duration of the various local anesthetic concentrations used. For the 1% concentrations, the duration of sensory block was 2 +/- 4 min (S.D.) for procaine, 20 +/- 10 min for lidocaine, 40 +/- 10 min for tetracaine, and 66 +/- 15 min for lidocaine with epinephrine. We found this to be a simple and reliable means of assessing local anesthetic conduction block in the mouse.

Perineural antinociceptive effect of opioids in a rat model

Background: The research on conductive analgesia induced by perineural opioids generated a large body of conflicting data. In this study we reassessed the antinociceptive response to perineural administration of morphine, fentanyl or meperidine in a rat model.

Intrathecal administration of liposomal morphine in a mouse model

The authors determined the duration of analgesia, toxicity, and neuraxial distribution of liposomal morphine after intrathecal administration in the mouse.Analgesic duration was determined using the tail-flick test after intrathecal injection of 12.5, 25, or 50 micro gram of plain or liposomal morphine (n = 6 mice/dose/formulation). Toxicity of the formulations was compared by estimating LD50. Neuraxial morphine distribution was determined after 20 micro gram of plain or liposomal morphine. The excised spinal cord and brain were divided into five segments at 1 min, and at 1, 4, and 8 h after injection for both formulations. In addition, for the liposomal morphine, similar sections were obtained at 24 h (n = 6 mice/formulation/time point). Segmental morphine concentration was quantified using radioimmunoassay. Liposomal encapsulation significantly prolonged duration of analgesia for the 25-micro gram (13.4 +/- 1.64 [SE] vs 4.1 +/- 0.5 h) and 50-micro gram doses (16.8 +/- 4.0 vs 4.6 +/- 1.0 h). The estimated LD50 was 200 (confidence interval 151-257 micro gram) for plain morphine, but was not determinable for the liposomal formulation, since no deaths occurred at the largest dose level which could be tested (371 micro gram). For plain morphine, the drug was not confined to a specific neuraxial segment, and segmental levels declined rapidly. After liposomal morphine, the most morphine was concentrated and persisted in the low spinal cord segment at each time interval. These results show that a single dose of liposomal morphine produces prolonged analgesia with decreased toxicity compared to the plain formulation. (Anesth Analg 1995;81:514-8)