Development of an apoptosis-assisted decellularization method for maximal preservation of nerve tissue structure

R. C. Cornelison, S. M. Wellman, J. H. Park, S. L. Porvasnik, Y. H. Song, Rebecca Wachs, C. E. Schmidt

Research output: Contribution to journalArticle

1 Citation (Scopus)

Abstract

Preservation of tissue structure is often a primary goal when optimizing tissue and organ decellularization methods. Many current protocols nonetheless rely on detergents that aid extraction of cellular components but also damage tissue architecture. It may be more beneficial to leverage an innate cellular process such as apoptosis and promote cell removal without the use of damaging reagents. During apoptosis, a cell detaches from the extracellular matrix, degrades its internal components, and fragments its contents for easier clearance. We have developed a method that leverages this process to achieve tissue decellularization using only mild wash buffers. We have demonstrated that treating peripheral nerve tissue with camptothecin induced both an early marker of apoptosis, cleaved caspase-3 expression, as well as a late stage marker, TUNEL + DNA fragmentation. Clearance of the cellular components was then achieved in an apoptosis-dependent manner using a gentle wash in hypertonic phosphate buffered saline followed by DNase treatment. This wash paradigm did not significantly affect collagen or glycosaminoglycan content, but it was sufficient to remove any trace of the cytotoxic compound based on conditioned media experiments. The resulting acellular tissue graft was immunogenically tolerated in vivo and exhibited an intact basal lamina microarchitecture mimicking that of native, unprocessed nerve. Hence, ex vivo induction of apoptosis is a promising method to decellularize tissue without the use of harsh reagents while better preserving the benefits of native tissue such as tissue-specific composition and microarchitecture. Statement of Significance: Tissue decellularization has expanded the ability to generate non-immunogenic organ replacements for a broad range of health applications. Current technologies typically rely on the use of harsh agents for clearing cellular debris, altering the tissue structure and potentially diminishing the pro-regenerative effects. We have developed a method for effectively, yet gently, removing cellular components from peripheral nerve tissue while preserving the native tissue architecture. The novelty of this process is in the induction of programmed cell death – or apoptosis – via a general cytotoxin, thereby enabling antigen clearance using only hypertonic wash buffers. The resulting acellular nerve scaffolds are nearly identical to unprocessed tissue on a microscopic level and elicit low immune responses comparable to an isograft negative control in a model of subcutaneous implantation.

Original languageEnglish (US)
Pages (from-to)116-126
Number of pages11
JournalActa Biomaterialia
Volume77
DOIs
StatePublished - Sep 1 2018

Fingerprint

Biological materials preservation
Nerve Tissue
Cell death
Tissue
Apoptosis
Peripheral Nerves
Buffers
Isografts
Tissue Preservation
Camptothecin
Deoxyribonucleases
Cytotoxins
In Situ Nick-End Labeling
DNA Fragmentation
Conditioned Culture Medium
Glycosaminoglycans

Keywords

  • Apoptosis
  • Decellularization
  • Detergent-free
  • Peripheral nerve graft

ASJC Scopus subject areas

  • Biotechnology
  • Biomaterials
  • Biochemistry
  • Biomedical Engineering
  • Molecular Biology

Cite this

Development of an apoptosis-assisted decellularization method for maximal preservation of nerve tissue structure. / Cornelison, R. C.; Wellman, S. M.; Park, J. H.; Porvasnik, S. L.; Song, Y. H.; Wachs, Rebecca; Schmidt, C. E.

In: Acta Biomaterialia, Vol. 77, 01.09.2018, p. 116-126.

Research output: Contribution to journalArticle

Cornelison, R. C. ; Wellman, S. M. ; Park, J. H. ; Porvasnik, S. L. ; Song, Y. H. ; Wachs, Rebecca ; Schmidt, C. E. / Development of an apoptosis-assisted decellularization method for maximal preservation of nerve tissue structure. In: Acta Biomaterialia. 2018 ; Vol. 77. pp. 116-126.
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AU - Song, Y. H.

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