Dense fibroadhesive scarring and poor blood vessel-maturation hamper the integration of implanted collagen scaffolds in an experimental model of spinal cord injury.

Altinova, Haktan;Hammes, Sebastian;Palm, Moniek;Achenbach, Pascal;Brook, Gary A;et.al.
(2020) Biomedical Materials : materials for tissue engineering and regenerative medicine — Vol. 15, n° 1, p. 15012 (2020)

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Authors
  • Altinova, Haktan
    Author
  • Hammes, Sebastian
    Author
  • Palm, Moniek
    Author
  • Achenbach, Pascal
    Author
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  • Brook, Gary A
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Abstract
Severe spinal cord injury (SCI) results in permanent functional deficits, which despite pre-clinical advances, remain untreatable. Combinational approaches, including the implantation of bioengineered scaffolds are likely to promote significant tissue repair. However, this critically depends on the extent to which host tissue can integrate with the implant. In the present paper, blood vessel formation and maturation were studied within and around implanted micro-structured type-I collagen scaffolds at 10 weeks post implantation in adult rat mid-cervical spinal cord lateral funiculotomy injuries. Morphometric analysis revealed that blood vessel density within the scaffold was similar to that of the lateral white matter tracts that the implant replaced. However, immunohistochemistry for zonula occludens-1 (ZO-1) and endothelial barrier antigen revealed that scaffold microvessels remained largely immature, suggesting poor blood-spinal cord barrier (BSB) reformation. Furthermore, a band of intense ZO-1-immunoreactive fibroblast-like cells isolated the implant. Spinal cord vessels outside the ZO-1-band demonstrated BSB-formation, while vessels within the scaffold generally did not. The formation of a double-layered fibrotic and astroglial scar around the collagen scaffold might explain the relatively poor implant-host integration and suggests a mechanism for failed microvessel maturation. Targeted strategies that improve implant-host integration for such biomaterials will be vital for future tissue engineering and regenerative medicine approaches for traumatic SCI.
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Altinova, H., Hammes, S., Palm, M., Achenbach, P., Gerardo-Nava, J., Deumens, R., Führmann, T., van Neerven, S. G. A., Hermans, E., Weis, J., & Brook, G. A. (2020). Dense fibroadhesive scarring and poor blood vessel-maturation hamper the integration of implanted collagen scaffolds in an experimental model of spinal cord injury. Biomedical Materials : materials for tissue engineering and regenerative medicine, 15(1), 15012. https://doi.org/10.1088/1748-605X/ab5e52 (Original work published 2020)