Aina Mogas Barcons
In vitro model of neurotrauma using the chick embryo to test regenerative bioimplantation.
Mogas Barcons, Aina; Chari, Divya M; Adams, Christopher
Abstract
Effective repair of spinal cord injury sites remains a major clinical challenge. One promising strategy is the implantation of multifunctional bioscaffolds to enhance nerve fibre growth, guide regenerating tissue and modulate scarring/inflammation processes. Given their multifunctional nature, such implants require testing in models which replicate the complex neuropathological responses of spinal injury sites. This is often achieved using live, adult animal models of spinal injury. However, these have substantial drawbacks for developmental testing, including the requirement for large numbers of animals, costly infrastructure, high levels of expertise and complex ethical processes. As an alternative, we show that organotypic spinal cord slices can be derived from the E14 chick embryo and cultured with high viability for at least 24 days, with major neural cell types detected. A transecting injury could be reproducibly introduced into the slices and characteristic neuropathological responses similar to those in adult spinal cord injury observed at the lesion margin. This included aligned astrocyte morphologies and upregulation of glial fibrillary acidic protein in astrocytes, microglial infiltration into the injury cavity and limited nerve fibre outgrowth. Bioimplantation of a clinical grade scaffold biomaterial was able to modulate these responses, disrupting the astrocyte barrier, enhancing nerve fibre growth and supporting immune cell invasion. Chick embryos are inexpensive and simple, requiring facile methods to generate the neurotrauma model. Our data show the chick embryo spinal cord slice system could be a replacement spinal injury model for laboratories developing new tissue engineering solutions.
Citation
Mogas Barcons, A., Chari, D. M., & Adams, C. (in press). In vitro model of neurotrauma using the chick embryo to test regenerative bioimplantation. Alternatives to animal experimentation : a journal for new paths in biomedical science / edited by the Swiss Society ALTEX Edition, 41(2), 202-212. https://doi.org/10.14573/altex.2304171
Journal Article Type | Article |
---|---|
Acceptance Date | Oct 20, 2023 |
Online Publication Date | Nov 2, 2023 |
Deposit Date | Nov 20, 2023 |
Publicly Available Date | Nov 20, 2023 |
Journal | ALTEX |
Print ISSN | 1868-596X |
Electronic ISSN | 1868-8551 |
Publisher | ALTEX Edition |
Peer Reviewed | Peer Reviewed |
Volume | 41 |
Issue | 2 |
Pages | 202-212 |
DOI | https://doi.org/10.14573/altex.2304171 |
Keywords | neuropathology, neural tissue engineering, injury model, organotypic, implantation, regeneration |
Public URL | https://keele-repository.worktribe.com/output/637251 |
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