Study on vascular remodeling, inflammatory response, and their correlations in acute spinal cord injury in rats_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

XU Zixing ,  XU Weihong , CHEN Xuemin , ZHOU Yinan

Department of Spinal and Orthopedic Surgery, the First Affiliated Hospital of Fujian Medical University, Fuzhou Fujian, 350005, P.R.China;

Corresponding author：

XU Weihong, Email: xuweihongfj@163.com

Keywords：

Spinal cord injury; angiogenesis; vascular remodeling; inflammatory response; correlation analysis; rat

DOI：

10.7507/1002-1892.202003186

Video：

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Objective To study the local vascular remodeling, inflammatory response, and their correlations following acute spinal cord injury (SCI) with different grades, and to assess the histological changes in SCI rats.Methods One hundred and sixteen adult female Sprague Dawley rats were randomly divided into 4 groups (n=29). The rats in sham group were received laminectomy only. A standard MASCIS spinal cord compactor was applied with drop height of 12.5, 25.0, or 50.0 mm to establish the mild, moderate, or severe SCI model, respectively. Quantitative rat endothelial cell antigen 1 (RECA1) and CD68 positive areas and the correlations were studied by double immunofluorescent (DIF) staining at 12 hours, 24 hours, 3 days, 7 days, and 28 days following SCI. Moreover, qualitative neurofilament-H (NF-H) and glial fibrillary acidic protein (GFAP) positive glial cells were studied by DIF staining at 28 days. ELISA was used to detect the levels of tumor necrosis factor α (TNF-α), interleukin 1β (IL-1β), and IL-6 in spinal cord homogenates at 12 hours, 24 hours, and 3 days, and the correlations between TNF-α, IL-1β, or IL-6 levels and microvascular density (RECA1) were accordingly studied. Moreover, the neural tissue integrity and neuron damage were assessed by HE staining at 12 hours, 24 hours, 3 days, 7 days, and 28 days, and Nissl’s staining at 28 days following SCI, respectively.Results DIF staining revealed that the ratio of RECA1 positive area was the highest in moderate group, higher in mild and severe groups, and the lowest in sham group with significant differences between groups (P<0.05). The ratio of CD68 positive area was the highest in severe group, higher in moderate and mild groups, and the lowest in sham group with significant differences between groups (P<0.05), except the comparisons between mild and moderate groups at 24 hours and 28 days after SCI (P>0.05). There was no significant correlation between the RECA1 and CD68 expressions in sham group at different time points (P>0.05). At 12 and 24 hours after SCI, the RECA1 and CD68 expressions in mild and moderate groups showed significant positive correlations (P<0.05), while no significant correlation was found in severe group (P>0.05). No significant correlations between the RECA1 and CD68 expressions was shown in all SCI groups at 3 days and in severe group at 7 days (P>0.05), while the negative correlations were shown in mild and moderate groups at 7 days, and in all SCI groups at 28 days (P<0.05). In mild, moderate, and severe groups, the axons became disrupted, shorter and thicker rods-like, or even merged blocks with increased injury, while the astrocytes decreased in number, unorganized and condensed in appearance. ELISA studies showed that TNF-α, IL-1β, and IL-6 levels in sham group were significantly lower than those in other 3 groups at different time points (P>0.05). The differences in TNF-α, IL-1β, and IL-6 levels between SCI groups at different time points were sinificant (P<0.05), except IL-1β levels between the mild and moderate groups at 12 hours (P>0.05). Three inflammatory factors were all significantly correlated with the microvascular density grades (P<0.05). Histological analysis indicated that the damage to spinal cord tissue structure correlated with the extent of SCI. In severe group, local hemorrhage, edema, and infiltration of inflammatory cells were found the most drastic, the grey/white matter boundary was disappeared concurrently with the formation of cavity and shortage of normal neurons.Conclusion In the acute stage following mild or moderate SCI, progressively aggravated injury result in higher microvessel density and increased inflammation. However, at the SCI region, the relation between microvessel density and inflammation inverse with time in the different grades of SCI. Accordingly, the destruction of neural structures positively relate to the grades of SCI and severity of inflammation.

Citation： XU Zixing, XU Weihong, CHEN Xuemin, ZHOU Yinan. Study on vascular remodeling, inflammatory response, and their correlations in acute spinal cord injury in rats. Chinese Journal of Reparative and Reconstructive Surgery, 2020, 34(11): 1429-1437. doi: 10.7507/1002-1892.202003186 Copy

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2.	Zhou T, Zheng Y, Sun L, et al. Microvascular endothelial cells engulf myelin debris and promote macrophage recruitment and fibrosis after neural injury. Nat Neurosci, 2019, 22(3): 421-435.
3.	Muramatsu R, Takahashi C, Miyake S, et al. Angiogenesis induced by CNS inflammation promotes neuronal remodeling through vessel-derived prostacyclin. Nat Med, 2012, 18(11): 1658-1664.
4.	Rengarajan M, Hayer A, Theriot JA. Endothelial cells use a formin-dependent phagocytosis-like process to internalize the bacterium listeria monocytogenes. PLoS Pathog, 2016, 12 (5): e1005603.
5.	Popa C, Popa F, Grigorean VT, et al. Vascular dysfunctions following spinal cord injury. J Med Life, 2010, 3 (3): 275-285.
6.	Rocha LA, Sousa RA, Learmonth DA, et al. The role of biomaterials as angiogenic modulators of spinal cord injury: mimetics of the spinal cord, cell and angiogenic factor delivery agents. Front Pharmacol, 2018, 9: 164.
7.	Xu ZX, Zhang LQ, Zhou YN, et al. Histological and functional outcomes in a rat model of hemisected spinal cord with sustained VEGF/NT-3 release from tissue-engineered grafts. Artif Cells Nanomed Biotechnol, 2020, 48 (1): 362-376.
8.	Batista CM, Mariano ED, Onuchic F, et al. Characterization of traumatic spinal cord injury model in relation to neuropathic pain in the rat. Somatosens Mot Res, 2019, 36 (1): 14-23.
9.	Morse LR, Xu Y, Solomon B, et al. Severe spinal cord injury causes immediate multi-cellular dysfunction at the chondro-osseous junction. Transl Stroke Res, 2011, 2 (4): 643-650.
10.	Figley SA, Khosravi R, Legasto JM, et al. Characterization of vascular disruption and blood-spinal cord barrier permeability following traumatic spinal cord injury. J Neurotrauma, 2014, 31 (6): 541-552.
11.	Ng MT, Stammers AT, Kwon BK. Vascular disruption and the role of angiogenic proteins after spinal cord injury. Transl Stroke Res, 2011, 2 (4): 474-491.
12.	Shah M, Peterson C, Yilmaz E, et al. Current advancements in the management of spinal cord injury: a comprehensive review of literature. Surg Neurol Int, 2020, 11: 2.
13.	Tu YF, Tsai YS, Wang LW, et al. Overweight worsens apoptosis, neuroinflammation and blood-brain barrier damage after hypoxic ischemia in neonatal brain through JNK hyperactivation. J Neuroinflammation, 2011, 8: 40.
14.	Mu J, Bakreen A, Juntunen M, et al. Combined adipose tissue-derived mesenchymal stem cell therapy and rehabilitation in experimental stroke. Front Neurol, 2019, 10: 235.
15.	Zhong D, Cao Y, Li CJ, et al. Neural stem cell-derived exosomes facilitate spinal cord functional recovery after injury by promoting angiogenesis. Exp Biol Med (Maywood), 2020, 245 (1): 54-65.
16.	Xu ZX, Zhang LQ, Wang CS, et al. Acellular spinal cord scaffold implantation promotes vascular remodeling with sustained delivery of VEGF in a rat spinal cord hemisection model. Curr Neurovasc Res, 2017, 14 (3): 274-289.
17.	Mortezaee K, Khanlarkhani N, Beyer C, et al. Inflammasome: Its role in traumatic brain and spinal cord injury. J Cell Physiol, 2018, 233 (7): 5160-5169.
18.	Orr MB, Gensel JC. Spinal cord injury scarring and inflammation: therapies targeting glial and inflammatory responses. Neurotherapeutics, 2018, 15(3): 541-553.
19.	Bloom O, Herman PE, Spungen AM. Systemic inflammation in traumatic spinal cord injury. Exp Neurol, 2020, 325: 113143.
20.	Gensel JC, Zhang B. Macrophage activation and its role in repair and pathology after spinal cord injury. Brain Res, 2015, 1619: 1-11.
21.	Lee YS, Cho DC, Kim CH, et al. Effect of curcumin on the inflammatory reaction and functional recovery after spinal cord injury in a hyperglycemic rat model. Spine J, 2019, 19 (12): 2025-2039.
22.	DiPietro LA. Angiogenesis and wound repair: when enough is enough. J Leukoc Biol, 2016, 100 (5): 979-984.
23.	Lin KC, Niu KC, Tsai KJ, et al. Attenuating inflammation but stimulating both angiogenesis and neurogenesis using hyperbaric oxygen in rats with traumatic brain injury. J Trauma Acute Care Surg, 2012, 72 (3): 650-659.
24.	Tran KA, Partyka PP, Jin Y, et al. Vascularization of self-assembled peptide scaffolds for spinal cord injury repair. Acta Biomater, 2020, 104: 76-84.

1. Ahuja CS, Nori S, Tetreault L, et al. Traumatic spinal cord injury-repair and regeneration. Neurosurgery, 2017, 80(3S): S9-S22.
2. Zhou T, Zheng Y, Sun L, et al. Microvascular endothelial cells engulf myelin debris and promote macrophage recruitment and fibrosis after neural injury. Nat Neurosci, 2019, 22(3): 421-435.
3. Muramatsu R, Takahashi C, Miyake S, et al. Angiogenesis induced by CNS inflammation promotes neuronal remodeling through vessel-derived prostacyclin. Nat Med, 2012, 18(11): 1658-1664.
4. Rengarajan M, Hayer A, Theriot JA. Endothelial cells use a formin-dependent phagocytosis-like process to internalize the bacterium listeria monocytogenes. PLoS Pathog, 2016, 12 (5): e1005603.
5. Popa C, Popa F, Grigorean VT, et al. Vascular dysfunctions following spinal cord injury. J Med Life, 2010, 3 (3): 275-285.
6. Rocha LA, Sousa RA, Learmonth DA, et al. The role of biomaterials as angiogenic modulators of spinal cord injury: mimetics of the spinal cord, cell and angiogenic factor delivery agents. Front Pharmacol, 2018, 9: 164.
7. Xu ZX, Zhang LQ, Zhou YN, et al. Histological and functional outcomes in a rat model of hemisected spinal cord with sustained VEGF/NT-3 release from tissue-engineered grafts. Artif Cells Nanomed Biotechnol, 2020, 48 (1): 362-376.
8. Batista CM, Mariano ED, Onuchic F, et al. Characterization of traumatic spinal cord injury model in relation to neuropathic pain in the rat. Somatosens Mot Res, 2019, 36 (1): 14-23.
9. Morse LR, Xu Y, Solomon B, et al. Severe spinal cord injury causes immediate multi-cellular dysfunction at the chondro-osseous junction. Transl Stroke Res, 2011, 2 (4): 643-650.
10. Figley SA, Khosravi R, Legasto JM, et al. Characterization of vascular disruption and blood-spinal cord barrier permeability following traumatic spinal cord injury. J Neurotrauma, 2014, 31 (6): 541-552.
11. Ng MT, Stammers AT, Kwon BK. Vascular disruption and the role of angiogenic proteins after spinal cord injury. Transl Stroke Res, 2011, 2 (4): 474-491.
12. Shah M, Peterson C, Yilmaz E, et al. Current advancements in the management of spinal cord injury: a comprehensive review of literature. Surg Neurol Int, 2020, 11: 2.
13. Tu YF, Tsai YS, Wang LW, et al. Overweight worsens apoptosis, neuroinflammation and blood-brain barrier damage after hypoxic ischemia in neonatal brain through JNK hyperactivation. J Neuroinflammation, 2011, 8: 40.
14. Mu J, Bakreen A, Juntunen M, et al. Combined adipose tissue-derived mesenchymal stem cell therapy and rehabilitation in experimental stroke. Front Neurol, 2019, 10: 235.
15. Zhong D, Cao Y, Li CJ, et al. Neural stem cell-derived exosomes facilitate spinal cord functional recovery after injury by promoting angiogenesis. Exp Biol Med (Maywood), 2020, 245 (1): 54-65.
16. Xu ZX, Zhang LQ, Wang CS, et al. Acellular spinal cord scaffold implantation promotes vascular remodeling with sustained delivery of VEGF in a rat spinal cord hemisection model. Curr Neurovasc Res, 2017, 14 (3): 274-289.
17. Mortezaee K, Khanlarkhani N, Beyer C, et al. Inflammasome: Its role in traumatic brain and spinal cord injury. J Cell Physiol, 2018, 233 (7): 5160-5169.
18. Orr MB, Gensel JC. Spinal cord injury scarring and inflammation: therapies targeting glial and inflammatory responses. Neurotherapeutics, 2018, 15(3): 541-553.
19. Bloom O, Herman PE, Spungen AM. Systemic inflammation in traumatic spinal cord injury. Exp Neurol, 2020, 325: 113143.
20. Gensel JC, Zhang B. Macrophage activation and its role in repair and pathology after spinal cord injury. Brain Res, 2015, 1619: 1-11.
21. Lee YS, Cho DC, Kim CH, et al. Effect of curcumin on the inflammatory reaction and functional recovery after spinal cord injury in a hyperglycemic rat model. Spine J, 2019, 19 (12): 2025-2039.
22. DiPietro LA. Angiogenesis and wound repair: when enough is enough. J Leukoc Biol, 2016, 100 (5): 979-984.
23. Lin KC, Niu KC, Tsai KJ, et al. Attenuating inflammation but stimulating both angiogenesis and neurogenesis using hyperbaric oxygen in rats with traumatic brain injury. J Trauma Acute Care Surg, 2012, 72 (3): 650-659.
24. Tran KA, Partyka PP, Jin Y, et al. Vascularization of self-assembled peptide scaffolds for spinal cord injury repair. Acta Biomater, 2020, 104: 76-84.

Chinese Journal of Reparative and Reconstructive Surgery

Study on vascular remodeling, inflammatory response, and their correlations in acute spinal cord injury in rats

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