Chi-Fei Wang

Enduring prevention and transient reduction of postoperative pain by intrathecal resolvin D1

&NA; Postoperative pain slows surgical recovery, impacting the return of normal function for weeks, months, or longer. Here we report the antihyperalgesic actions of a new compound, resolvin D1 (RvD1), known to reduce inflammation and to suppress pain after peripheral nerve injury, on the acute pain occurring after paw incision and the prolonged pain after skin‐muscle retraction. Injection of RvD1 (20–40 ng) into the L5–L6 intrathecal space 30 minutes before surgery reduces the postincisional primary mechanical hypersensitivity, lowering the peak change by approximately 70% (with 40 ng) and reducing the area under the curve (AUC) for the entire 10‐day postincisional course by approximately 60%. Intrathecal injection of RvD1 on postoperative day (POD) 1 reduces the hyperalgesia to the same level as that from preoperative injection within a few hours, an effect that persists for the remaining PODs. Tactile allodynia and hyperalgesia following the skin/muscle incision retraction procedure, measured at the maximum values 12 to 14 days, is totally prevented by intrathecal RvD1 (40 ng) given at POD 2. However, delaying the injection until POD 9 or POD 17 results in RvD1 causing only transient and incomplete reversal of hyperalgesia, lasting for <1 day. These findings demonstrate the potent, effective reduction of postoperative pain by intrathecal RvD1 given before or shortly after surgery. The much more limited effect of this compound on retraction‐induced pain, when given 1 to 2 weeks later, suggests that the receptors or pathways for resolvins are more important in the early than the later stages of postoperative pain. Single intrathecal injections of resolvin D1 in rats before or 1 to 2 days after surgery strongly reduce postoperative pain for several weeks.

Coapplication of Lidocaine and the Permanently Charged Sodium Channel Blocker QX-314 Produces a Long-lasting Nociceptive Blockade in Rodents

Background:Nociceptive-selective local anesthesia is produced by entry of the permanently charged lidocaine-derivative QX-314 into nociceptors when coadministered with capsaicin, a transient receptor potential vanilloid 1 (TRPV1) channel agonist. However, the pain evoked by capsaicin before establishment of the QX-314–mediated block would limit clinical utility. Because TRPV1 channels are also activated by lidocaine, the authors tested whether lidocaine can substitute for capsaicin to introduce QX-314 into nociceptors through TRPV1 channels and produce selective analgesia. Methods:Lidocaine (0.5% [17.5 mm], 1% [35 mm], and 2% [70 mm]) alone, QX-314 (0.2% [5.8 mm]) alone, and a combination of the two were injected subcutaneously and adjacent to the sciatic nerve in rats and mice. Mechanical and thermal responsiveness were measured, as was motor block. Results:Coapplication of 0.2% QX-314 with lidocaine prolonged the nociceptive block relative to lidocaine alone, an effect attenuated in TRPV1 knockout mice. The 0.2% QX-314 alone had no effect when injected intraplantary or perineurally, and it produced only weak short-lasting inhibition of the cutaneous trunci muscle reflex. Perisciatic nerve injection of lidocaine with QX-314 produced a differential nociceptive block much longer than the transient motor block, lasting 2 h (for 1% lidocaine) to 9 h (2% lidocaine). Triple application of lidocaine, QX-314, and capsaicin further increased the duration of the differential block. Conclusions:Coapplication of lidocaine and its quaternary derivative QX-314 produces a long-lasting, predominantly nociceptor-selective block, likely by facilitating QX-314 entry through TRPV1 channels. Delivery of QX-314 into nociceptors by using lidocaine instead of capsaicin produces sustained regional analgesia without nocifensive behavior.

Capsaicin Combined with Local Anesthetics Preferentially Prolongs Sensory/Nociceptive Block in Rat Sciatic Nerve

Background: Transient receptor potential vanilloid 1 channels integrate nociceptive stimuli and are predominantly expressed by unmyelinated C-fiber nociceptors, but not low-threshold mechanoreceptive sensory or motor fibers. A recent report showed that the transient receptor potential vanilloid 1 channel agonist capsaicin allows a hydrophilic quaternary ammonium derivative of lidocaine, QX-314, to selectively block C fibers without motor block. The authors tested whether a similar differential block would be produced using amphipathic N-methyl amitriptyline, amitriptyline, bupivacaine, or lidocaine, either alone or together with 0.05% capsaicin, in a rat sciatic nerve block model. Methods: Rats (n = 8/group) were anesthetized with sevoflurane, and 0.2 ml of drug was injected either alone or with capsaicin (simultaneously or 10 min later) next to the sciatic nerve in the sciatic notch. Motor function was assessed by the extensor postural thrust. Nociception was evaluated by the nocifensive withdrawal reflex and vocalization evoked by pinch of a skin fold over the lateral metatarsus (cutaneous pain) with a serrated forceps. Results: N-Methyl amitriptyline, amitriptyline, bupivacaine, or lidocaine, followed by injection of capsaicin 10 min later, each elicited a predominantly nociceptive-specific blockade. In comparison, simultaneous application of each local anesthetic with capsaicin did not elicit a clinically significant differential block, with the exception of N-methyl amitriptyline. Conclusions: Both tertiary amine local anesthetics and their quaternary ammonium derivatives can elicit a predominantly sensory/nociceptor selective block when followed by injection of capsaicin. The combined application of transient receptor potential vanilloid 1 channel agonists and various local anesthetics or their quaternary ammonium derivatives is an appealing strategy to achieve a long-lasting differential block in regional analgesia.

Bulleyaconitine A Isolated from aconitum Plant Displays Long-acting Local Anesthetic Properties in Vitro and in Vivo

Background:Bulleyaconitine A (BLA) is an active ingredient of Aconitum bulleyanum plants. BLA has been approved for the treatment of chronic pain and rheumatoid arthritis in China, but its underlying mechanism remains unclear. Methods:The authors examined (1) the effects of BLA on neuronal voltage-gated Na+ channels in vitro under the whole cell patch clamp configuration and (2) the sensory and motor functions of rat sciatic nerve after single BLA injections in vivo. Results:BLA at 10 μm did not affect neuronal Na+ currents in clonal GH3 cells when stimulated infrequently to +50 mV. When stimulated at 2 Hz for 1,000 pulses (+50 mV for 4 ms), BLA reduced the peak Na+ currents by more than 90%. This use-dependent reduction of Na+ currents by BLA reversed little after washing. Single injections of BLA (0.2 ml at 0.375 mm) into the rat sciatic notch not only blocked sensory and motor functions of the sciatic nerve but also induced hyperexcitability, followed by sedation, arrhythmia, and respiratory distress. When BLA at 0.375 mm was coinjected with 2% lidocaine (approximately 80 mm) or epinephrine (1:100,000) to reduce drug absorption by the bloodstream, the sensory and motor functions of the sciatic nerve remained fully blocked for approximately 4 h and regressed completely after approximately 7 h, with minimal systemic effects. Conclusions:BLA reduces neuronal Na+ currents strongly at +50 mV in a use-dependent manner. When coinjected with lidocaine or epinephrine, BLA elicits prolonged block of both motor and sensory functions in rats with minimal adverse effects.

An absorbable local anesthetic matrix provides several days of functional sciatic nerve blockade.

BACKGROUND: Functional blockade of peripheral nerves is the primary objective of local anesthesia, and it is often desirable to have a persistent blockade, sustained throughout and beyond a surgical procedure. Current local anesthetics give effective analgesia for <8–12 h after a single bolus injection. We report on an implantable, controlled-release drug delivery system intended for use in bone and consisting of a Food and Drug Administration-approved matrix containing lidocaine that is capable of local delivery for several days. METHODS: Xybrex™, an absorbable, controlled-release delivery system containing 16% (w/w) lidocaine, was implanted next to the sciatic nerve of male rats (300–350 gm), at lidocaine doses of 5.3, 10.6, 16, and 32 mg lidocaine per rat. For comparison, a lidocaine HCl solution (0.2 mL, 2% = 4 mg) was injected in close proximity to the sciatic nerve. Rats were assessed behaviorally for analgesia by a forceps pinch of the lateral digits, and for motor block by quantifying the extensor postural thrust. Potential neurotoxicity of sciatic nerves was evaluated histologically at 24 h, 4 days, and 4 wk after implantation. The kinetics of lidocaine’s release from the matrix was measured in vitro by ultraviolet detection of lidocaine in samples collected at 2.5, 6.5, 20, and 24.25 h. RESULTS: Xybrex at the highest doses (300 and 600 mg/kg, containing 16 and 32 mg of lidocaine free base, respectively) provided complete analgesia to an intense pinch for 7.0 ± 2.0 h, 6.9 ± 1.7 h and partial analgesia for 60.0 ± 5.4 h, 58.8 ± 4.2 h, respectively, compared to 0.61 ± 0.03 h of complete analgesia and 0.96 ± 0.03 h of partial analgesia by sciatic block from the 2% lidocaine solution (containing 4 mg lidocaine). These same high doses of Xybrex produced complete motor block for 17.0 ± 3.3 h, 17.6 ± 3.3 h with full recovery in 352.0 ± 55.7 h (14.7 ± 2.3 days), 579.0 ± 36.1 h (24.1 ± 1.5 days) respectively. Data are reported as mean ± se. P < 0.001 for all Xybrex groups compared to the 2% lidocaine group. Minor local tissue inflammation/pathology, primarily in the connective tissue and muscle 0.1 mm adjacent to the nerve, was observed equally in animals treated with Xybrex and 2% lidocaine solution. There were no behavioral signs of systemic toxicity. The in vitro release followed exponential kinetics and its comparison to the time-course of functional nociceptive deficit implied that the duration of nociception represented the local, immediate interaction of lidocaine between the nerve and the matrix and not a cumulative effect of previously released drug. CONCLUSIONS: Xybrex is an absorbable, controlled-release drug delivery system that provides several days of analgesia for rat peripheral nerves without apparent significant local neurotoxicity or systemic toxicity.

Magnesium Sulfate Diminishes the Effects of Amide Local Anesthetics in Rat Sciatic-Nerve Block

Background and Objectives: Magnesium sulfate (MgSO4) is well known as an antagonist of N-methyl-d-aspartate receptors and was used for intrathecal analgesia a century ago. However, the effects of MgSO4 combined with local anesthetics (LAs) on peripheral nerves are unclear. We tested the hypothesis that MgSO4 could be used as an adjuvant to prolong and intensify conduction block by amide-type LAs in a rat sciatic-nerve block model. Further, the mechanism of possible synergy between LAs and MgSO4 was investigated in whole-cell mode patch-clamp experiments. Methods: Sciatic nerves were exposed to 2%/73.9 mM lidocaine, 0.25%/7.7 mM bupivacaine, and 0.5%/15.4 mM ropivacaine, with or without addition of 1.25%, 2.5%, or 5% MgSO4/50.7 mM, and nerve block characteristics were assessed. To elucidate the LA-MgSO4 interaction, voltage-dependent inactivation curves were determined in cultured rat GH3 cells that expressed neuronal Na+ channels. Results: Unexpectedly, the addition of MgSO4 overall significantly shortened the duration of block by lidocaine, bupivacaine, and ropivacaine. The steady-state inactivation of Na+ channels in the presence of 300 &mgr;M lidocaine was almost unchanged by the addition of 10 mM MgSO4, indicating that MgSO4 does not affect the potency of lidocaine toward the inactivated Na+ channel. Conclusions: MgSO4 coadministered with amide-type LAs shortened the duration of sciatic-nerve block in rats. Therefore, it does not seem to be useful as an adjuvant for peripheral-nerve block. The mechanism of this observed antagonism is unclear but appears to be independent of the action of LAs and MgSO4 at the LA receptor within the Na+ channel.

Low-dose systemic bupivacaine prevents the development of allodynia after thoracotomy in rats.

BACKGROUND: Chronic pain after thoracotomy has been recently reproduced in a rat model that allows investigation of the effect of drugs that might reduce the incidence of allodynia after thoracotomy. Previous studies suggest that intrathecal or systemic morphine, clonidine, neostigmine, and gabapentin reduce the incidence of allodynia in the rat postthoracotomy pain model. Our purpose was to test whether intercostal and systemic injection of bupivacaine prevented the development of allodynia in an animal model of chronic intercostal neuropathic pain. METHODS: Male Sprague-Dawley rats were anesthetized and the right 4th and 5th ribs surgically exposed. The pleura were opened and the ribs were retracted for 1 h. Intercostal or systemic bupivacaine 1 mg (0.2 mL at 0.5%) was injected before and after surgery, or before surgery; a control group underwent rib retraction and did not receive any drug. Rats were tested for mechanical allodynia at a predetermined area around the incision site during the 3 wk after surgery. RESULTS: Allodynia developed in 43% of the animals that did not receive bupivacaine (control group); in contrast, allodynia developed in only 6%, 12%, and 12% of those animals that received intercostal bupivacaine before surgery, after surgery, or systemically before surgery, respectively. DISCUSSION: Previous studies suggest that allodynia after rib retraction can be prevented by opioids, α2-adrenergic agonists, neostigmine, and gabapentin. The current results suggest that bupivacaine is effective in preventing mechanical allodynia, whether given by intercostal injection before or after surgery, or systemically before surgery.

The relationship between functional sciatic nerve block duration and the rate of release of lidocaine from a controlled-release matrix.

BACKGROUND: Nerve blocks of long duration are often desirable in perioperative and postoperative situations. The relationship between the duration of such blocks and the rate at which a local anesthetic is released is important to know for developing a localized drug delivery system that will optimize block duration. METHODS: Lidocaine concentration was varied in 1 series of formulations (OSB-L) containing a constant amount of release rate modifier. In another series (OST-R), the release rate modifier was varied while the lidocaine content was held constant. Release kinetics were measured in vitro and correlated to the in vivo duration of antinociceptive and motor block effects when the formulation was implanted next to the rat sciatic nerve. In parallel studies, rats receiving different formulations of slow-release lidocaine were fixed by intracardiac perfusion with 4% paraformaldehyde and nerve-muscle tissue taken for histopathological analysis. RESULTS: In this study, we have demonstrated that the most important variable for effecting functional nerve block, i.e., the blockade of impulses in the relevant fibers of the sciatic nerve, is the rate of lidocaine release at that time. For the OSB-L formulations (lidocaine concentrations of 1.875%, 3.75%, 7.5%, and 15% at a constant release rate modifier of 5%), the average in vitro release rates at 50% recovery of motor block and nociceptive block were 0.91 ± 0.28 and 1.75 ± 0.61 mg/h, respectively. For the OST-R formulations (16% lidocaine with release rate modifier concentrations of 1.875%, 3.75%, 7.5%, and 15%), the average in vitro release rates at 50% recovery of motor block and nociceptive block were 2.33 ± 1.39 and 4.34 ± 1.09 mg/h, respectively. The OSB-L formulations showed a dose-dependent increase in block duration proportional to an increase in initial lidocaine concentration, whereas the OST-R formulations showed a nonmonotonic relationship between release rate modifier concentration and block duration. The histopathological studies at 24 hours, 3, 5, or 7 days, and 4 weeks after the implantation revealed inflammatory reactions with degrees correlated with lidocaine content, but limited to the connective tissue and muscle immediately surrounding the implanted material. Despite these observed inflammatory reactions, nociceptive and motor block function returned to normal, preimplantation values in all animals. CONCLUSIONS: Increasing initial lidocaine content proportionately increased the duration of functional sciatic nerve block. However, decreasing the release rate per se does not give a proportional increase in block duration. Instead, there seems to be an optimal, intermediate release rate for achieving the maximum duration of block.

Use of Bulleyaconitine A as an Adjuvant for Prolonged Cutaneous Analgesia in the Rat

BACKGROUND: Bulleyaconitine A (BLA) is an analgesic and antiinflammatory drug isolated from Aconitum plants. BLA has several potential targets, including voltage-gated Na+ channels. We tested whether BLA elicited long-lasting cutaneous analgesia, when co-injected with lidocaine and epinephrine, as a model for prolonged infiltration anesthesia. METHODS: The local anesthetic properties of BLA were assessed by the patch-clamp technique in HEK293t cells expressing Nav1.7 and Nav1.8 neuronal Na+ channels, both crucial for nociception. Drug solutions (0.6 mL) were injected subcutaneously via rat shaved dorsal skin. Inhibition of the cutaneous trunci muscle reflex was evaluated by pinpricks. Skin cross-sections were stained with hematoxylin and eosin or with antibodies against PGP9.5. RESULTS: BLA at 10 &mgr;M interacted minimally with resting or inactivated Nav1.7 and Nav1.8 Na+ channels when infrequently stimulated to +50 mV for 3 ms. However, when stimulated at 2 Hz for 1000 pulses, their peak Na+ currents were >90% reduced by BLA. This use-dependent inhibition was not significantly reversed after 15-min washing. Complete nociceptive blockade after injection of lidocaine (0.5%)/epinephrine (1:200,000) lasted for approximately 1 h in rats; full recovery occurred after approximately 6 h. Co-injection of 0.125 mM BLA with lidocaine/epinephrine increased the duration of complete nociceptive blockade to 24 h. Full recovery occurred after approximately 6 days. Skin histology including peripheral nerve fibers appeared unaffected by BLA. CONCLUSIONS: BLA inhibits Nav1.7 and Nav1.8 Na+ currents in a use-dependent manner. Co-injection of BLA at ≤0.125 mM with lidocaine and epinephrine elicits complete cutaneous analgesia that lasts for up to 24 h without adverse effects.

The Effects of Resiniferatoxin in an Experimental Rat Thoracotomy Model

BACKGROUND: Chronic pain after thoracotomy has been reproduced in a rat model that allows investigation of drugs that might reduce the incidence of allodynia after thoracotomy. Previous studies suggest that morphine, clonidine, neostigmine, gabapentin, and bupivacaine reduce the incidence of allodynia in the rat postthoracotomy pain model. One purpose of this study was to test whether intercostal injection of resiniferatoxin (RTX) decreased the amount of allodynia in an animal model of chronic postthoracotomy pain. We also tested whether RTX induced a transient mechanical hyperalgesic response in uninjured animals. METHODS: Male Sprague-Dawley rats were anesthetized, and the right fourth and fifth ribs were surgically exposed. The pleura was opened, and the ribs were retracted. Intercostal RTX 0.8 or 8 μg was injected in animals that developed allodynia after surgery; a control group underwent rib retraction and received vehicle only. An additional group of uninjured animals received RTX. Rats were tested for mechanical allodynia at a predetermined area around the incision site for 3 wk. RESULTS: Allodynia developed in 42% of the animals that underwent thoracotomy. A transient hyperalgesic response was noted in the uninjured group that underwent drug injections. Intercostal RTX did not modify the course of allodynia in injured rats. DISCUSSION: The current results suggest that intercostal RTX causes a transient hyperalgesic response in uninjured animals and is ineffective in reducing the mechanical allodynia after thoracotomy.