Tianle Gao

Analgesic effect of sinomenine in rodents after inflammation and nerve injury.

Sinomenine is an alkaloid originally isolated from the root of the plant Sinomenium acutum. It is used in traditional medicine in China to treat rheumatic arthritis. In the present study, we evaluated the potential antinociceptive effects of sinomenine in rodents with nociceptive, inflammatory and neuropathic pain. In normal rats and mice, systemic sinomenine produced moderate antinociceptive effect in the hot plate and tail flick tests. Sinomenine also exerted analgesic effects on mechanical and heat hypersensitivity in mice after carrageenan induced inflammation. Finally, sinomenine effectively alleviated mechanical and cold allodynia in rats and mice after injury to peripheral nerve or spinal cord. The analgesic effect of sinomenine is not associated with side effects and is not reversed by the opioid receptor antagonist naloxone. Our results showed that sinomenine has a wide spectrum analgesic effect in rodent models of nociceptive, inflammatory and neuropathic pain.

Heparanase overexpression reduces carrageenan-induced mechanical and cold hypersensitivity in mice

Heparanase controls the structure and functions of extracellular matrix (ECM) by degrading heparan sulfate proteoglycans. Heparanase is involved in inflammatory process through modulating the functions of inflammatory cytokines. The present study aimed to find out whether overexpression of heparanase in mice affects carrageenan-induced localized inflammation and inflammatory hyperalgesia. Without challenge, the heparanase overexpression did not significantly affect the mice in response to mechanical, cold and heat stimulation. Unilateral subcutaneous administration of carrageenan produced hypersensitivity to mechanical and cold in both wildtype and the heparanase overexpression (Hpa-tg) mice 24h after treatment. In comparison to wildtype animals, the Hpa-tg mice showed significantly reduced mechanical and cold hypersensitivity. This may, at least partially, due to the reduced mast cell infiltration at the site of inflammation in Hpa-tg mice. These data support a role for heparanase that reduces localized inflammation and inflammatory hyperalgesia in mice.

Phenotypic changes in dorsal root ganglion and spinal cord in the collagen antibody-induced arthritis mouse model

The mechanisms underlying rheumatoid arthritis (RA)‐induced pain are still not fully elucidated, and accumulating data indicate that peripheral inflammation is not the only factor driving pain in these patients. The focus of our work is to investigate the molecular basis for long‐term alterations in nociceptive pathways induced by polyarthritis using the collagen antibody‐induced arthritis (CAIA) mouse model. In this model, mechanical hypersensitivity outlasts the joint inflammation by weeks. Here we examined expression levels of neuropeptides, ion channels, and nerve injury markers associated with neuropathic and/or inflammatory pain in dorsal root ganglia (DRGs) and spinal cord both during the peak of inflammation (day 15) and when the inflammation has resolved but the hypersensitivity persists (days 45–47). No apparent differences were observed in substance P, calcitonin gene‐related peptide, or neuropeptide Y protein expression in DRGs and spinal cord of CAIA mice. However, the neuropeptide galanin, the ATP‐gated ion channel P2X3, and calcium channel subunit α2δ1 were significantly increased in the CAIA DRGs as compared to controls, both 15 and 47 days after induction of arthritis. On day 15 there was an increase in expression of two factors associated with nerve injury and cell stress, activating transcription factor 3 and growth‐associated protein 43 in DRGs, whereby the latter was still dramatically upregulated after 47 days. In conclusion, this study suggests that long‐term joint inflammation has an impact on DRG neurons that resembles both inflammation and nerve injury‐induced pain states. Thus, antibody‐driven inflammation generates a pain state with a unique neurochemical profile. J. Comp. Neurol. 523:1505–1528, 2015.

N-terminal truncations of substance P1–7 amide affect its action on spinal cord injury-induced mechanical allodynia in rats

Central neuropathic pain can arise from injury of the spinal cord and can become chronic. Treatment is difficult and, because complete pain relief is currently very hard to achieve, there is a need for new, more effective treatment options. In this study we used an animal model of spinal cord injury to evaluate the potency of a bioactive fragment of substance P (SP), i.e. SP1-7, in alleviating signs of allodynia and acute pain. SP1-7 is known from earlier studies to possess antinociceptive properties. We also studied the effects of intraperitoneal injection of an amidated analog of this heptapeptide and of its truncated analogs, all of which had high affinity to the SP1-7 binding site, to evaluate the importance of the removed amino acids for the biodistribution and stability of the peptides. Most of the examined compounds alleviated mechanical allodynia without any signs of sedation or motor impairment in the rats. In contrast, the response threshold to acute nociceptive stimulation was not affected by any of the compounds tested. Most of the amino acids in the heptapeptide structure were essential for retaining the biological effect after peripheral injection. These observations suggest that the heptapeptide and its N-terminal truncated hexa- and pentapeptide analogs could be of interest for further development of analgesics in the management of mechanical allodynia.

Repeated sinomenine administration alleviates chronic neuropathic pain-like behaviours in rodents without producing tolerance

Abstract Background and aims We have previously reported that systemic administration of sinomenine produced antinociception in various experimental pain conditions in rodents, particularly in models of neuropathic pain. In the present study we assessed the effects of repeated administration of sinomenine in two rodent models of neuropathic pain in order to study the development of tolerance. Methods The analgesic effect of sinomenine was tested in female Sprague-Dawley rats that exhibited mechanical and cold hypersensitivity following ischaemic injury to the spinal cord and in male C57/BL6 mice that developed mechanical hypersensitivity after ischaemic injury to the sciatic nerve. Briefly, the animals were anaesthetized and injected i.v. with the photosensitizing dye erythrosine B. Vertebral segments T12 to T13 in rats or the sciatic nerve in mice were exposed and irradiated under an argon ion laser for 10min or 45s, respectively. In rats, mechanical hypersensitivity to pressure with von Frey hairs, the response to brushing and decreasing cold temperature were tested in the flanks or upper back areas. In mice, mechanical hypersensitivity on the hind paw to von Frey hairs and response to cold following a drop of acetone were measured. Sinomenine was administered i.p. in rats and p.o. in mice at 10:00 and 16:00, twice a day for 5 days. Response threshold before and 2h after drug administration at 10.00h was recorded. Results Repeated administration of sinomenine at 10 or 20mg/kg twice a day, doses that have no analgesic effect as single injection, alleviated mechanical, but not cold allodynia in spinally injured rats and the effect was maintained during the 5 day treatment period with no signs of tolerance. Furthermore, the pre-drug response threshold was significantly elevated during repeated treatment with 20mg/kg sinomenine. Sinomenine administered at 40mg/kg twice a day for 5 days significantly reduced mechanical and cold alldoynia, elevated pre-drug response threshold without tolerance development in spinally injured rats. Similarly, sinomenine at 80mg/kg twice a day for 5 days significantly reduced mechanical allodynia in mice with sciatic nerve injury and increased pre-drug response threshold with no sign of tolerance. The effect of sinomenine on response threshold persisted for days after termination of the 5 day drug administration. Conclusions The results suggest that repeated administration of simomenine produced an enhanced anti-allodynic effect without tolerance in rodent models of neuropathic pain. Implications Sinomenine may be tested as a novel analgesic in treating some forms of chronic neuropathic pain in patients.

Quantitative test of responses to thermal stimulation in spinally injured rats using a Peltier thermode: A new approach to study cold allodynia

In this work, we described a method of testing of responses of spinally injured rats to thermal stimulation (heating and cooling) to the flank area using a Peltier thermode. With a baseline holding temperature at 32°C and the temperature change rate of 0.5°C/s, we measured vocalization thresholds of rats to thermal stimulation in the flank area. While normal rats did not vocalize to temperatures changes ranging from 6°C to 50°C, the spinally injured rats exhibited significantly increased response to cooling with average response temperature above 15°C through the 70 day observation period after spinal cord injury. The response temperature to cooling in spinally injured rats is correlated with the magnitude of responses to cold stimulation scored after ethyl chloride spray and with the response threshold to mechanical stimulation. In contrast, we did not observe an increase in response to warm/heat stimuli. The results showed that ischemic spinal cord injury produced cold, but not heat, allodynia in rats. Furthermore, we showed that it is possible to quantitatively measure response of rats to thermal stimulation on the body using temperature as end points which may aid further studies on mechanisms and treatments of thermal stimulation, particularly cold, evoked pain.

Sinomenine alleviates mechanical hypersensitivity in mice with experimentally induced rheumatoid arthritis

Abstract Background and aims We have previously reported that sinomenine, an alkaloid isolated from the root of the plant Sinomenium acutum, had antinociceptive effect in rodent models of acute inflammatory or neuropathic pain. As a traditional medicine, sinomenine is used in China to treat rheumatoid arthritis (RA). Methods In the present study, we evaluated the potential antinociceptive effect of sinomenine in a mouse model of RA, collagen type II antibody (CII Ab) induced arthritis (CAIA) after acute and chronic administration. Results As single administration, sinomenine at 40 or 80 mg/kg significantly reduced mechanical hypersensitivity both at the time of peak joint inflammation (days 11–19 after CII Ab injection) or during the post-inflammatory phase (days 35–54). No tolerance to the effect of 80 mg/kg sinomenine was observed during repeated injection twice a day for 5 days from day 11 to day 19 or from day 49 to day 53 after CII Ab injection in CAIA mice. Conclusions We have shown that sinomenine is effective in alleviating localized and spread hypersensitivities in CAIA mice both during acute inflammation and in post-inflammatory phase. Further, repeated sinomenine administration has elevated the baseline mechanical threshold without producing tolerance. Implications Sinomenine may be clinically useful to treat chronic pain in RA, including wide-spread pain which appears to be a difficult clinical problem despite the improvement in the acute treatment of RA by disease modifying agents.

Activation of TRPM8 cold receptor triggers allodynia-like behavior in spinally injured rats

Abstract Aims Pain in response to innocuous cold stimulation (cold allodynia) is a common symptom in patients with neuropathic pain. Cold allodynia is difficult to treat and its mechanisms are poorly understood. Several transient receptor potential (TRP) channels have been shown to be the molecular sensors for cold stimulation in a temperature-dependent manner, but the contribution of various TRP channels in mediating cold allodynia in neuropathic pain is unclear. We have previously shown that spinally injured rats developed neuropathic pain-like behaviors, including marked cold allodynia. We now assessed the role of TRP channels in mediating cold allodynia in rats after ischemic spinal cord injury. Methods Methods: Spinal cord injury was produced using a photochemical method. The mechanical allodynia was assessed by examining the vocalization thresholds to graded mechanical touch/pressure applied with von Frey hairs. Temperature controlled cold stimulation was produced by a Peltier thermode (active surface 25 mm × 50 mm) connected to a MSA Thermal Simulator (Somedic, Sweden) with baseline temperature of 32 °C. The rate of temperature change was 0.5 °C/s. The temperature required to elicit cold allodynia was examined. The responses of the rats to topical application of icilin or menthol, agonists of transient receptor potential melastain 8 (TRPM8), were also studied. Results Normal rats did not exhibit nociceptive responses to cooling stimulation to the trunk and back area (minimal temperature +6°C) and they also did not react aversively to topical application of icilin or menthol. After spinal cord injury, the rats developed mechanical allodynia at the trunk and back just rostral to the dermatome of the injured spinal segments. In the same area, rats exhibited significant nociceptive responses to cooling from day 1 after injury, lasting for at least 70 days which is the longest time of observation. For the first two weeks after injury, the majority of spinally injured rats had a nociceptive response to cooling above 17°C. At day 70, about 50% of rats responded to cooling above 17 °C. Topical application of 400 μM icilin or 4mM menthol also elicited pain-like responses in spinally injured rats and these two cold mimetics also significantly exacerbated existing mechanical allodynia. Conclusion Our results showed that activation of the TRPM8 channel by menthol or icilin triggers allodynia in spinally injured rats and increases, rather than decreases, mechanical allodynia. TRPM8 channels which respond to cooling above 17 ° C may be involved at least in part in mediating cold allodynia in the rat model of neuropathic spinal cord injury pain. Implications The work introduced a method of quantitative testings of responses of rats to cold stimulation and may contribute to the understanding of mechanisms of cold allodynia after injury to the nervous system.

The anti-inflammatory alkaloid aloperine in Chinese herbal medicine is potentially useful for management of pain and itch

In this issue of the Scandinavian Journal of Pain, Yang and o-workers report interesting effects of aloperine on acute and nflammatory pain behaviour in mice [1]. Aloperine is an alkaloid solated from the plant Sophora alopecuroides L that, as indicated by reclinical evidence, possesses anti-inflammatory and anti-allergic roperties [2]. In the Yang and co-workers’ study, aloperine’s analesic efficacies were determined by performing behavioural tests f acute and inflammatory pain, and the authors documented that loperine can suppress pain-like behaviours in several inflammaory pain models in mice [1]. In acetic acid-induced writhing test, aloperine (40mg/kg or 0mg/kg) had an anti-nociceptive effect and reduced the writhing ehaviours. However, comparedwithmorphine (10mg/kg), which lmost completely inhibited the writhing response, the effects f these doses of aloperine were minor [1]. Similarly, aloperine as found to be able to dose-dependently suppress formalinnduced pain behaviour, both in the first and second phases, hile aspirin was only effective in the second phase [1]. Furhermore, the ear swelling test and carrageenan-induced paw edema test documented aloperine’s suppressing effect on inflamation. In these tests, aloperine was found to suppress the ro-inflammatory cytokines tumour necrosis factor, Interleukin-1 eta, and prostaglandin E2, as well as enhancing the production of nti-inflammatory cytokine interleukin-10, in the inflamed tissues 1].

Exploring the transcriptome of resident spinal microglia after collagen antibody-induced arthritis

Abstract Recent studies have suggested a sexually dimorphic role of spinal glial cells in the maintenance of mechanical hypersensitivity in rodent models of chronic pain. We have used the collagen antibody–induced arthritis (CAIA) mouse model to examine differences between males and females in the context of spinal regulation of arthritis-induced pain. We have focused on the late phase of this model when joint inflammation has resolved, but mechanical hypersensitivity persists. Although the intensity of substance P, calcitonin gene–related peptide, and galanin immunoreactivity in the spinal cord was not different from controls, the intensity of microglia (Iba-1) and astrocyte (glial fibrillary acidic protein) markers was elevated in both males and females. Intrathecal administration of the glial inhibitors minocycline and pentoxifylline reversed mechanical thresholds in male, but not in female mice. We isolated resident microglia from the lumbar dorsal horns and observed a significantly lower number of microglial cells in females by flow cytometry analysis. However, although genome-wide RNA sequencing results pointed to several transcriptional differences between male and female microglia, no convincing differences were identified between control and CAIA groups. Taken together, these findings suggest that there are subtle sex differences in microglial expression profiles independent of arthritis. Our experiments failed to identify the underlying mRNA correlates of microglial actions in the late phase of the CAIA model. It is likely that transcriptional changes are either subtle and highly localised and therefore difficult to identify with bulk isolation techniques or that other factors, such as changes in protein expression or epigenetic modifications, are at play.