The CatWalk method: a detailed analysis of behavioral changes after acute inflammatory pain in the rat

Experimental pain research is often complicated by the absence of an objective and detailed method to analyze behavioral changes. In the present study, acute pain was induced into the right knee of the rat (n=15) through the injection of 2mg carrageenan (CAR) in saline. A control group received vehicle injection into the knee (n=15). With the use of an automated quantitative gait analysis system, the CatWalk, it was possible to quantitatively analyze behavioral changes at post-injection time 2.5, 4, 24 and 48h. The CatWalk analysis of individual paw parameters like the intensity of the paw print or the time contact with the floor showed a significant effect after CAR injection into the knee. These CatWalk parameters were highly correlated with von Frey data and thus representative for the development of mechanical allodynia. Furthermore, detailed CatWalk analysis of the gait (i.e. coordinated interaction between left and right hindlimb) showed very fine, accurate and significant coordination changes in the experimental rats from 4h post-injection. In conclusion, the CatWalk method allows an objective and detailed detection of both pain-induced gait adaptations as well as the development of mechanical allodynia in an acute inflammatory pain model.     

Morphine fails to produce tolerance when administered in the presence of formalin pain in rats

The present study examined the development of tolerance to morphine analgesia under conditions in which morphine was administered in the presence or absence of pain induced by subcutaneous injection of 50 μl of 2.5% formalin into the hind paw of rats. Animals were injected with morphine (25 mg/kg, i.p.) or saline for 3 consecutive days either in the presence of pain (10 min after formalin injection) or in the absence of pain (6 h prior to formalin injection). On the 4th day, tolerance to the analgesic effect of test doses of morphine (6 or 10 mg/kg) was assessed in the formalin and tail-flick tests, respectively. Significant tolerance in both tests was observed in animals receiving morphine in the absence of pain during the tolerance induction period, but not in animals receiving morphine in the presence of pain.     

Disruption of glial function enhances electroacupuncture analgesia in arthritic rats

Activated glia play a major role in mediating behavioral hypersensitive state following peripheral inflammation. Electroacupuncture is well known to relieve persistent inflammatory pain. The present study was undertaken to examine whether fluorocitrate, a glial metabolic inhibitor, could synergize electroacupuncture antagonizing thermal hyperalgesia and mechanical allodynia evoked by ankle joint inflammation. Monoarthritis of rat ankle joint was induced by an intra-articular injection of Complete Freund's Adjuvant (CFA). The paw withdrawal latency (PWL) from a thermal stimulus and paw withdrawal threshold (PWT) from von Frey hairs were measured in awake rats. Intrathecal (i.t.) injection of 1 nmol fluorocitrate markedly suppressed monoarthritis-induced thermal hyperalgesia and mechanical allodynia. Unilateral electroacupuncture stimulation of "Huantiao" (GB30) and "Yanglingquan" (GB34) acupuncture points (100/2 Hz alternation, 1-2-3 mA) significantly elevated the PWLs and PWTs for 45 min after cessation of electroacupuncture in monoarthritic rats. Co-application of 0.1 or 1 nmol fluorocitrate with electroacupuncture significantly potentiated electroacupuncture analgesia, although 0.1 nmol fluorocitrate alone had no effect on PWLs and PWTs in monoarthritic rats. These results suggested that electroacupuncture and disrupting glial function could synergistically antagonize inflammatory pain, which might provide a potential strategy for the treatment of arthritic pain.     

Intrathecal administration of doxepin attenuated development of formalin-induced pain in rats

Summary. The aim of the present research was to assess the influence of a tricyclic antidepressant doxepin administered intrathecally (i.t.) on the pain behavior in the formalin test (100 μl of 12% formalin was injected into the dorsal part of the hind paw under halotane anesthesia) in male Wistar rats. The influence of doxepin (62.5 μg i.t.) on the pain threshold and number of formalin-induced pain behaviors, as well as antinociceptive effect of morphine was studied. Doxepin significantly increased the nociceptive threshold in the paw pressure test, reduced formalin-induced pain behavior and potentiated morphine antinociceptive effect in formalin test. The obtained results indicate that analgesic effect of doxepin used before the injury is observable at the spinal level after intrathecal treatment, but not only after peripheral administration, which was shown in our previous study. The results of the present research demonstrated a possibility to modify the spinal nociceptive process by administration of doxepin before the formalin injection.     

CatWalk步态分析系统分析大鼠大脑中动脉阻塞模型的行为学特征

目的 探讨以CatWalk步态分析系统对大鼠暂时性大脑中动脉阻塞(MCAO)模型进行行为学评价的可行性.方法 30只SD雄性大鼠按随机数字表法分为MCAO模型组和对照组,其中模型组以线栓法制作成暂时性MCAO模型.分别于模型制作后第1、3、7、14、28天应用传统的18分制mNSS评分以及CatWalk步态分析系统对2组大鼠进行行为学特征分析.结果 CatWalk结果 显示MCAO模型组大鼠的四肢压强、接触面积和运行速度均比对照组大鼠减小减慢;在协调性方面,模型组大鼠造模后第3天时同为后侧的左后肢→右后肢的时间较对照组明显缩短,且其同为左侧的左前肢→左后肢的时间亦较对照组明显缩短,这一变化在第28天时仍然存在;在造模后第3天模型组出现了在对照组中并未见到的Ra型(1.5％)和Rb型(2.3％)步序;但步调、站立时间、抬爪时间和规律指数等参数在2组间差别不明显.结论 CatWalk步态分析系统在压强、速度、接触面积、步态以及协调性等方面可反映脑缺血造成的损伤及其随时间变化的过程,可用于动物模型的多种行为学特征的综合分析.     

The analgesic and anti-inflammatory effects of subcutaneous bupivacaine, morphine and tramadol in rats

The analgesic and anti-inflammatory effects of subcutaneously administered bupivacaine, morphine and tramadol on formalin-induced inflammation were compared. 0.25 % bupivacaine in Group B, 20 mg/kg tramadol in Group T, 1 mg/kg morphine in Group M and 0.9 % NaCl in Group S in a volume of 200 micro l were injected into the right hind paw of the rats (n: 40) 15 minutes before injection of 50 micro l 5 % formalin. Sedation and pain behaviour scores, number of flinches and licking-time were recorded. The degree of dermal edema, intraneural edema, vasodilation, erythrodiapedesis, infiltration of polymorphonuclear leukocyte/lymphocyte and mast cell counts were analyzed histopathologically. In Group T and B, circumferential changes were lower than in Group M and S. The pain behaviour scores were significantly lower in Group T and B. The number of flinches in Group T was lower than Group B and S. The vasodilation was significant only in Group M. The dermal edema was limited to deep dermis only in Group T. Preinflammational subcutaneous tramadol infiltration can provide effective analgesia and may have anti-inflammatory effects.     

Effect of long-term ketamine administration on vocalization to paw pressure and on spinal wind-up activity in monoarthritic rats

The antinociceptive effect of long-lasting ketamine administration (mini-osmotic pump) was studied in monoarthritic rats by using hindpaw pressure testing and wind-up measurement in a C-fiber reflex paradigm. Chronic ketamine induced antinociception in the monoarthritic paw and significantly suppressed mechanical hyperalgesia during the 14-day treatment period. The treatment also reduced C-reflex wind-up in the monoarthritic hindpaw. After pump removal, vocalization thresholds and spinal wind-up scores from the monoarthritic paw returned to control values, while hyperalgesia developed in the normal paw. Results suggest that ketamine upregulates NMDA receptors upon long-term administration, resulting in hyperalgesic response in the normal paw after drug withdrawal.     

Botulinum neurotoxin A enhances the analgesic effects on inflammatory pain and antagonizes tolerance induced by morphine in mice

Over the recent years compelling evidence has accumulated indicating that botulinum neurotoxin serotype A (BoNT/A) results in analgesic effects on neuropathic as well as inflammatory pain, both in humans and in animal models. In the present study, the pharmacological interaction of BoNT/A with morphine in fighting inflammatory pain was investigated in mice using the formalin test. Moreover, the effects of BoNT/A on the tolerance-induced by chronic administration of morphine were tested and the behavioral effects were correlated with immunofluorescence staining of glial fibrillary acidic protein, the specific marker of astrocytes, at the spinal cord level. An ineffective dose of BoNT/A (2 pg/paw) combined with an ineffective dose of morphine (1 mg/kg) exerted a significant analgesic action both during the early and the late phases of formalin test. A single intraplantar injection of BoNT/A (15 pg/paw; i.pl.), administered the day before the beginning of chronic morphine treatment (7 days of s.c. injections of 20 mg/kg), was able to counteract the occurrence of tolerance to morphine. Moreover, BoNT/A reduces the enhancement of the expression of astrocytes induced by inflammatory formalin pain. Side effects of opiates, including the development of tolerance during repeated use, may limit their therapeutic use, the possibility of using BoNT/A for lowering the effective dose of morphine and preventing the development of opioid tolerance would have relevant implications in terms of potential therapeutic perspectives.     

Cross-tolerance between analgesic low doses of morphine and naloxone in arthritic rats

The effects of acute injections of naloxone (3-3000 micrograms/kg i.v.) and morphine (100-1000 micrograms/kg i.v.) on the vocalization threshold induced by pressure on the paw were analyzed in adjuvant-induced arthritic rats pretreated either with naloxone or with morphine administered at low doses (9 micrograms/kg s.c. and 3000 micrograms/kg s.c., respectively) over 4 consecutive days. In naloxone-pretreated arthritic rats, the paradoxical analgesic effect of low doses of naloxone was almost abolished, and the potent analgesic effects of low doses of morphine were also strongly and dose-dependently reduced. In morphine-pretreated arthritic animals, the analgesic effect of low doses of naloxone was significantly attenuated. These results attest that a cross-tolerance with low analgesic doses of morphine and naloxone can be demonstrated in these chronic suffering animals. By contrast, in rats pretreated either with naloxone or morphine, the hyperalgesic effect of naloxone produced by higher doses persisted and even was unmasked for doses which were analgesic before the pretreatment. These data emphasize the involvement of opiate receptors different in their sensitivity and/or their functions in the two opposite effects of naloxone. They also suggest that opiate receptors and endorphinergic systems differ in normal animals and animals which experience persistent pain.     

EFFECT OF LONG-TERM KETAMINE ADMINISTRATION ON VOCALIZATION TO PAW PRESSURE AND ON SPINAL WIND-UP ACTIVITY IN MONOARTHRITIC RATS

The antinociceptive effect of long-lasting ketamine administration (mini-osmotic pump) was studied in monoarthritic rats by using hindpaw pressure testing and wind-up measurement in a C-fiber reflex paradigm. Chronic ketamine induced antinociception in the monoarthritic paw and significantly suppressed mechanical hyperalgesia during the 14-day treatment period. The treatment also reduced C-reflex wind-up in the monoarthritic hindpaw. After pump removal, vocalization thresholds and spinal wind-up scores from the monoarthritic paw returned to control values, while hyperalgesia developed in the normal paw. Results suggest that ketamine upregulates NMDA receptors upon long-term administration, resulting in hyperalgesic response in the normal paw after drug withdrawal.­­     

Can tolerance to morphine be induced in arthritic rats?

The effects of acute injections of morphine (0.1-1 mg/kg i.v.) upon vocalization threshold elicited by pressure of the paw were analyzed in normal and arthritic rats, both groups being initially pretreated with calculated doses of morphine. The analgesic effects of morphine were greatly reduced in both groups of chronically morphine-treated rats. The lowest doses (0.1 mg/kg in normal rats; 0.1 and 0.3 mg/kg in arthritic animals) became totally ineffective, while the highest dose (1 mg/kg) elicited a threshold increase only equivalent to that induced by 0.3 mg/kg in non-tolerant chronically vehicle-treated rats. Tolerance to morphine can be induced in rats suffering from arthritis, and appeared to be more complete than in normal rats.     

Pain hypersensitivity induced by paradoxical sleep deprivation is not due to altered binding to brain mu-opioid receptors

Previous studies have established a relationship between sleep disruption and pain, and it has been suggested that hyperalgesia induced by paradoxical sleep deprivation (PSD) could be due to a reduction of opioidergic neurotransmission in the brain. In the present study rats deprived of sleep for 96 h as well as rats allowed to recover for 24h after PSD and normal controls received vehicle or morphine (2.5, 5 and 10 mg/kg, i.p.) and were tested on a hot plate 1h later. Quantitative receptor autoradiography was used to map alterations in binding to brain mu-opioid receptors in separate groups. Results demonstrated that PSD induced a significant reduction in thermal pain threshold, as measured by paw withdrawal latencies. This effect did not return to baseline control values after 24h of sleep recovery. The usual analgesic effect of morphine was observed in the control group but not in PSD or rebound groups except at the highest dose (10 mg/kg). Binding of [3H]DAMGO to mu sites did not differ significantly among the three groups in any of the 33 brain regions examined. These results do not exclude the participation of the opioid system in PSD-induced pain hypersensitivity since sleep-deprived rats were clearly resistant to morphine. However, the fact no changes were seen in [3H]DAMGO binding indicates that mechanisms other than altered mu-opioid binding must be sought to explain the phenomenon.     

Use of animal models of clinical pain

For a better understanding of clinical pain, several groups involved in the study of basic pain mechanisms have proposed the use of various experimental models close to clinical situations. They are based either on neurogenic or inflammatory processes. Data obtained with three of these models will be developed in the paper: rats rendered arthritic by Freund's adjuvant injection into the tail, rats with an intraplantar injection of carrageenin in one hind-paw, rats with a moderate ligature of one common sciatic nerve. The various pharmacological approaches revealed dramatic changes of the analgesic effects of morphine and other opioid substances, and a spectacular modification of the endogenous opioid reactivity. A further enhancement of the initial hyperalgesia was observed with high doses (1-3 mg/kg iv) of naloxone (known as an antagonist of morphine), contrasting with the paradoxical analgesia induced with the low dose (peaking up for 3 micrograms/kg iv). Electrophysiological studies emphasized dramatic changes of neuronal responsiveness in structures involved in the transmission of the nociceptive messages. In each of these models, electrophysiological data provide new insights on the physiopathological mechanisms of the related clinical pain.     

Aminooxyacetic acid produces excitotoxic lesions in the rat striatum.

The neuropathological, biochemical, and behavioral effects of intrastriatal injection of aminooxyacetic acid (AOAA), a non-specific transaminase inhibitor, were examined in rats. AOAA, 0.1-1 mumol, produced neuronal damage when injected into the striatum of adult rats but failed to damage the striatum of 6-d-old or decorticated rats. AOAA-induced (0.25 mumol-1 mumol) striatal lesions in adult rats displayed excitotoxic characteristics and could be prevented by the N-methyl-D-aspartate (NMDA) receptor antagonists (-)-2-amino-7-phosphono-heptanoate (AP7; 0.25 mumol) or kynurenate (KYNA; 0.5 mumol), but not by the non-NMDA antagonist 2,3-dihydroxy-6-nitro-7-sulphamoyl-benzo(F)quinoxaline (NBQX; 0.25 mumol). AOAA produced a dose-dependent reduction in striatal L-glutamate decarboxylase activity, as measured 14 d following intrastriatal injection, which could also be prevented by AP7 or KYNA, but not by NBQX. These findings suggest that AOAA-induced lesions are preferentially mediated by activation of the NMDA subtype of excitatory amino acid receptors. Behavioral studies revealed that the cataleptic response to haloperidol, 2 mg/kg, was decreased whereas the cataleptic response to arecoline, 15 mg/kg, and morphine, 15 mg/kg, was potentiated in AOAA lesioned animals 14 d following bilateral intrastriatal injections of AOAA, 0.25 and 1 mumol. In rats which received unilateral intrastriatal injection of AOAA, 0.1-1 mumol, apomorphine, 0.5 mg/kg, induced circling towards the lesioned side. Rats which received AP7, 0.25 mumol, or KYNA, 0.5 mumol, coadministered with AOAA, 0.25 mumol, behaved as vehicle-treated controls, while those which received NBQX, 0.25 mumol, and AOAA, 0.25 mumol, had behavioral patterns similar to those subjected to AOAA alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

A novel automated method for measuring the effect of analgesics on formalin-evoked licking behavior in rats

The behavioral assessment of pain is essential for the analysis of pain mechanisms and the evaluation of analgesic drugs. The formalin test is one of such methods widely used as a model of injury-induced pain in rodents. This test is manually demanding and the recording of results is left to the subjectivity of the experimenters. Thus we developed a novel automated method to estimate the pharmacological response in formalin-induced licking behavior in rats using a multicolor detection technique. Two color markers were preliminarily applied to rats-yellow dye on the mouth and fluorescent green tape on the right hind paw. Behaviors of the animals were recorded from both above and below the subject, by a dual-view digital video camera system. After injection with formalin into the hind paw, rats exhibited a biphasic display of licking behavior. Licking time was measured by the sum of frames where the distance between these markers was less than an appropriate threshold of distance (TD). The split-plot analysis of variance demonstrated that the sum of squares of differences in licking time between manual and automated measurement was minimized when TD = 20mm. In addition, frames in which moving velocity of these markers is less than 2.5mm/s was neglected for calculation in order to eliminate sedative effect on the recorded data. On these conditions, subcutaneous administration of morphine in rats dose-dependently decreased formalin-elicited nociceptive responses. These results suggest that under optimal conditions the automated technique when applied to pharmacological studies are more reliable and efficient than if they are manually recorded.     

Does chronic nociceptive stimulation alter the development of morphine tolerance?

Conflicting results exist concerning the issues of whether chronic nociceptive stimulation (a) increases or decreases the effectiveness of morphine analgesia, and (b) facilitates or inhibits the development of narcotic tolerance. We carried out a series of experiments with appropriate controls in order to examine these two issues and their possible relationship. In experiment 1, rats received complete Freund's adjuvant (CFA), a chronic nociceptor, injected into a single hind paw or anesthesia without injection, together with morphine or placebo pellets in a 2 × 2 study design. The data indicate that the presence of the chronic nociceptive stimulus significantly facilitated the development of tolerance to morphine analgesia as measured using tail-flick latency (TFL) testing. Experiment 2 was designed to compare the analgetic effectiveness of an acute injection of morphine in rats experiencing chronic nociceptive stimulation and in controls. CFA was injected in the right hindpaw, and nine days later TFLs were tested after morphine doses of 1 and 2 mg/kg s.c. The data obtained showed that chronic nociceptive stimulation significantly reduced the effectiveness of morphine at the 1 mg/kg dose. However, baseline TFLs appeared to be shorter in rats treated with CFA, suggesting that the decrease in morphine effectiveness could be due to a general increase in pain sensitivity. Therefore, a third experiment was performed, using a less intense thermal stimulus to prolong baseline TFLs and accentuate any potential differences. Sixteen rats either received CFA or served as controls. TFLs were then measured at baseline and one hour after a 0.5 mg/kg dose of morphine. TFLs were significantly shorter in CFA injected animals at both times, suggesting that hyperalgesia had developed and that the observed decrease in morphine effectiveness could be due to an increase in pain sensitivity. We suggest that the primary effect is a facilitation of pain responsiveness in animals exposed to chronic nociceptors, and that experimental variables can lead to an apparent increase or decrease in the rate of development of tolerance to morphine. These results and their relation to previous findings are discussed.     

Monosodium urate test: a new analgesic test by crystal-induced monoarthritis in rats

The analgesic effects of various agents were evaluated in knee joint monoarthritic rats where arthritis was induced by monosodium urate (MSU) crystals injected into the knee joint cavities. The weight supported by each hind limb was measured quantitatively using pressure transducers, which revealed dose-dependent recovery produced by various analgesics including morphine but no changes in value by sedatives such as chlorpromazine. Relative potency obtained from the value of ED50 of each analgesic agent was congruent with that in clinical use. The MSU test may be quite suitable for quantitative and objective evaluation of the analgesic effects of various agents, particularly for spontaneous and tonic pain.     

Discriminative stimulus effects of morphine: central versus peripheral training

While it is well known that rats can discriminate a peripheral injection of morphine from a saline injection, to our knowledge no one has trained rats to discriminate a direct brain-site injection of morphine from saline. In the present series of studies, one group of rats was trained to discriminate morphine (0.3 microgram) from saline injected into the perifornical area of the hypothalamus (PFA), a process that took rats about 37 sessions to learn. A dose response generalization curve for PFA-injected morphine (0.01, 0.03, 0.1, and 0.17 microgram) was generated in which the two highest doses of morphine generalized to the morphine-appropriate training stimulus. Intraperitoneal (i.p.) injection of 3 mg/kg, but not 1 mg/kg morphine, resulted in morphine-appropriate responding in the PFA morphine-trained rats. A second group of rats was trained to discriminate i.p. injections of 3 mg/kg morphine from injections of saline. A dose-response generalization test for i.p.-injected morphine (0.3, 0.56, 1.0, and 1.7 mg/kg) was conducted in which the 0.17 mg/kg dose of morphine generalized to the morphine-appropriate training stimulus. Generalization tests using PFA-injected morphine doses (0.17, 0.56, 1.0, and 3.0 microgram) failed to result in morphine-appropriate responding in the i.p. morphine-trained rats. Naloxone administered into the PFA (50 microgram) or the periphery (3 mg/kg, i.p.) blocked morphine discrimination in the PFA-trained rats. However, when naloxone was injected into the PFA (50 microgram) together with i.p. morphine (3 mg/kg) in animals trained using i.p. injections, the antagonist failed to block morphine-appropriate responding. Thus, while peripheral injection of morphine generalized to the discriminative stimulus effects of morphine produced under PFA-injection training, the opposite effects were not noted.     

Paradoxical hyperalgesic effect of exceedingly low doses of systemic morphine in an animal model of persistent pain (Freund's adjuvant-induced arthritic rats)

The effects of exceedingly low doses of morphine (3-50 micrograms/kg i.v.) were studied upon the vocalization threshold induced by paw pressure in rats with Freund's adjuvant-induced arthritis. The highest dose used (50 micrograms/kg i.v.) clearly induced an analgesic effect. No significant modification of the vocalization threshold was observed with 30 micrograms/kg. By contrast, a significant hyperalgesic effect resulted with doses of 10 down to 3 micrograms/kg. Maximum hyperalgesia was observed with 6 micrograms/kg.     

Evidence that nitric oxide-glutamate cascade modulates spinal antinociceptive effect of morphine: a behavioural and microdialysis study in rats

We evaluated the ability of spinally administered nitric oxide (NO) synthase inhibitor to modulate antinociceptive action of intrathecal (i.t.) morphine in rats by measuring the early and late phases of flinching and licking/biting in the formalin test. To determine the contribution of spinal NO and glutamate, we measured the release of NO metabolites (nitrite/nitrate) and glutamate from the spinal cord in rats, using a microdialysis probe placed in the lumbar space. The i.t. administration of NG-nitro L-arginine methyl ester (L-NAME) produced a dose-dependent reduction in the number of flinches during the late phase, whereas there were no significant alterations in the late phase licking/biting, and early phase flinching and licking/biting. Spinal administration of morphine at low doses produced a significant antinociceptive activity in the early and late phases of the flinching behaviour, whereas higher doses of morphine were required to obtain a significant effect in the licking/biting behaviour during both phases. Combination of L-NAME with morphine resulted in an enhanced reduction in the early and late phase flinching. Enhanced antinociceptive activity was observed in the late phase licking/biting by i.t. combined administration of L-NAME (400 nmol) and morphine (1.25 nmol). In the present study, we have confirmed our prior results that injection of formalin (5.0%) into the plantar surface of the paw evoked a biphasic spinal release of nitrite/nitrate and a transient release of glutamate. Formalin-evoked release of nitrite/nitrate and glutamate was also reduced markedly by i.t. combined administration of L-NAME and morphine. These behavioural and biochemical results suggest that i.t. administered L-NAME may enhance morphine-induced antinociception through an increased inhibition of nitrite/nitrate and glutamate releases evoked by formalin injection at the spinal cord level.