Delayed decompression exacerbates ischemia-reperfusion injury in cervical compressive myelopathy
Pia M. Vidal, Spyridon K. Karadimas, Antigona Ulndreaj, Alex M. Laliberte, Lindsay Tetreault, Stefania Forner, Jian Wang, Warren D. Foltz, Michael G. Fehlings
Pia M. Vidal, Spyridon K. Karadimas, Antigona Ulndreaj, Alex M. Laliberte, Lindsay Tetreault, Stefania Forner, Jian Wang, Warren D. Foltz, Michael G. Fehlings
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Research Article Inflammation Neuroscience

Delayed decompression exacerbates ischemia-reperfusion injury in cervical compressive myelopathy

Abstract

Degenerative cervical myelopathy (DCM) is the most common progressive nontraumatic spinal cord injury. The most common recommended treatment is surgical decompression, although the optimal timing of intervention is an area of ongoing debate. The primary objective of this study was to assess whether a delay in decompression could influence the extent of ischemia-reperfusion injury and alter the trajectory of outcome in DCM. Using a DCM mouse model, we show that decompression acutely led to a 1.5- to 2-fold increase in levels of inflammatory cytokines within the spinal cord. Delayed decompression was associated with exacerbated reperfusion injury, astrogliosis, and poorer neurological recovery. Additionally, delayed decompression was associated with prolonged elevation of inflammatory cytokines and an exacerbated peripheral monocytic inflammatory response (P < 0.01 and 0.001). In contrast, early decompression led to resolution of reperfusion-mediated inflammation, neurological improvement, and reduced hyperalgesia. Similar findings were observed in subjects from the CSM AOSpine North America and International studies, where delayed decompressive surgery resulted in poorer neurological improvement compared with patients with an earlier intervention. Our data demonstrate that delayed surgical decompression for DCM exacerbates reperfusion injury and is associated with ongoing enhanced levels of cytokine expression, microglia activation, and astrogliosis, and paralleled with poorer neurological recovery.

Authors

Pia M. Vidal, Spyridon K. Karadimas, Antigona Ulndreaj, Alex M. Laliberte, Lindsay Tetreault, Stefania Forner, Jian Wang, Warren D. Foltz, Michael G. Fehlings

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Figure 6

Surgical decompression does not affect the number of recruited microglia/macrophages in the spinal cord.

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Surgical decompression does not affect the number of recruited microglia...
(A) Representative images of Iba1+ cells in the dorsal horn from mice at 5 weeks after either early or delayed decompression and age-matched sham controls. (B) At 5 weeks after decompression, Iba1+ cells were quantified in the regions of dorsal horns outlined by red squares, as indicated in the spinal cord diagram. A slight decrease in Iba1+ cells was detected in the dorsal horns of the DCM-E + Dec group (n = 6) compared with the DCM-E group (n = 7). (C and D) No significant differences were observed in the DCM-E group (n = 4) compared with the DCM-E + Dec (n = 3) in the dorsal columns (C) and the lateral corticospinal tracts (D). In all cases, the analyzed area is represented by the red squares in the diagram of the spinal cord. (EG) No significant changes were observed in the number of Iba1+ cells in the dorsal horns (E), dorsal columns (F), and lateral corticospinal tracts (G) between the DCM-D (n = 4) and DCM-D + Dec (n = 5–4) at 5 weeks after decompression. All the results are presented as mean ± SEM of 5 to 6 slides per animal. Scale bars: 25 μm. DCM, degenerative cervical myelopathy; Dec, decompression; DCM-E, age-matched early sham decompressed group; DCM-D, age-matched delayed sham decompressed group.