Transient nerve root compression load and duration differentially mediate behavioral sensitivity and associated spinal astrocyte activation and mGLuR5 expression.

Injury to the cervical nerve roots is a common source of neck pain. Animal models of nerve root compression have previously established the role of compression magnitude and duration in nerve root-mediated pain and spinal inflammation; yet, the response of the spinal glutamatergic system to transient nerve root compression and its relationship to compression mechanics have not been studied. The glutamate receptor, mGluR5, has a central role in pain, and its expression by neurons and astrocytes in the spinal cord may be pivotal for neuronal-glial signaling. This study quantified spinal GFAP and mGluR5 expression following nerve root compressions of different magnitudes and durations in the rat. Compression to the C7 nerve root was applied for a duration that was either above (10 min) or below (3 min) the critical duration for mediating afferent discharge rates during compression. To also test for the effect of the magnitude of the compression load, either a 10 gf or a 60 gf was applied to the nerve root for each duration. Mechanical allodynia was assessed, and the C7 spinal cord was harvested on day 7 for immunofluorescent analysis. Double labeling was used to localize the expression of mGluR5 on astrocytes (GFAP) and neurons (MAP2). Seven days after injury, 10 min of compression produced significantly greater behavioral sensitivity (P<0.001) and spinal GFAP expression (P=0.002) than 3 min of compression, regardless of the compression magnitude. Nerve root compression at 60 gf produced a significant increase (P<0.001) in spinal mGluR5 for both of the durations studied. There was no difference in the distribution of mGluR5 between astrocytes and neurons following nerve root compression of any type. The glutamatergic and glial systems are differentially modulated by the mechanics of nerve root compression despite the known contribution of glia to pain through glutamatergic signaling.

Activating transcription factor 4, a mediator of the integrated stress response, is increased in the dorsal root ganglia following painful facet joint distraction.

Chronic neck pain is one of the most common musculoskeletal disorders in the US. Although biomechanical and clinical studies have implicated the facet joint as a primary source of neck pain, specific cellular mechanisms still remain speculative. The purpose of this study was to investigate whether a mediator (activating transcription factor; 4ATF4) of the integrated stress response (ISR) is involved in facet-mediated pain. Holtzman rats underwent C6/C7 facet joint loading that produces either painful (n=16) or nonpainful (n=8) responses. A sham group (n=9) was also included as surgical controls. Behavioral sensitivity was measured and the C6 dorsal root ganglia (DRGs) were harvested on day 7 to evaluate the total and neuronal ATF4 expression. In separate groups, an intra-articular ketorolac injection was administered either immediately (D0 ketorolac) or 1 day (D1 ketorolac) after painful facet joint loading. Allodynia was measured at days 1 and 7 after injury to assess the effects on behavioral responses. ATF4 and BiP (an indicator of ISR activation) were separately quantified at day 7. Facet joint loading sufficient to elicit behavioral hypersensitivity produced a threefold increase in total and neuronal ATF4 expression in the DRG. After ketorolac treatment at the time of injury, ATF4 expression was significantly (P<0.01) reduced despite not producing any attenuation of behavioral responses. Interestingly, ketorolac treatment at day 1 significantly (P<0.001) alleviated behavioral sensitivity at day 7, but did not modify ATF4 expression. BiP expression was unchanged after either intervention time. Results suggest that ATF4-dependent activation of the ISR does not directly contribute to persistent pain, but it may sensitize neurons responsible for pain initiation. These behavioral and immunohistochemical findings imply that facet-mediated pain may be sustained through other pathways of the ISR.