Possible impact of genetic differences on the development of neuropathic pain-like behaviors after unilateral sciatic nerve ischemic injury in rats.

The development of neuropathic-like behaviors following unilateral ischemic injury to the sciatic nerve was examined and compared in four rat strains: Sprague--Dawley (SD), Wistar--Kyoto (WK), spontaneously hypertensive (SHR) and Dark--Agouti (DA). We have also compared two sub-strains of SD rats supplied from two different vendors (SD-BK and SD-DK). The responses to mechanical, heat or cold stimuli of both hind paws were measured before and regularly after injury for up to 10 weeks. Spontaneous paw lifting and changes in paw posture after nerve injury were also examined. Significant differences in basal sensitivity to mechanical or heat stimulation were seen among the four rat strain studied with SHR and DA rats being less sensitive than the SD and WK rats. All strains of rats developed bilateral mechanical allodynia and ipsilateral heat hyperalgesia after photochemically-induced nerve ischemia, but the time-course and magnitude of the responses were significantly different among the strains. Again, the SHR and DA were found to be least susceptible to the development of abnormal pain-like responses. Cold allodynia occurred only in WK and SD-BK. SD-DK rats on the other hand developed more severe mechanical allodynia than SD-BK. SHR and DA rats showed less deficits in paw posture after nerve injury whereas spontaneous pain lifting, a measure of possible spontaneous pain, was comparable among all strains. Light microscopic study of the injured sciatic nerve showed comparable nerve damage in SHR, WK and two sub-strains of SD rats. The DA rats however exhibited reduced area of intraneural damage. Finally, electronmicroscopic examination revealed that damage to both myelinated and unmyelinated fibers occurred in this model in all strains. These results showed that normal sensitivity and the development of pain-like response after partial nerve injury differ substantially among different strains of rats, supporting the emerging concept that genetic factors affect pain sensitivity under normal conditions and after nerve injury. The apparent resistance of DA rats to nerve ischemia, however, may suggest that genetic factors not directly related to pain modulation also play a role in the diverse outcomes. Our results indicate that sub-strains of rats also showed variable development of neuropathic pain-like behaviors to both the modality and magnitude of the effect. Thus, controlling sub-strains is also important in experimental studies of neuropathic pain in rats.