Whole organ sheep kidney tissue engineering and in vivo transplantation: Effects of perfusion-based decellularization on vascular integrity

During the past decade, increased efforts have been made to develop alternative management options instead of dialysis and homograft renal transplantation for end-stage renal disease. State-of-the-art methods employ tissue engineering to produce natural acellular scaffolds that could resolve the con...

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Bibliographic Details
Published in:Materials Science & Engineering C 2019-05, Vol.98, p.392-400
Main Authors: Kajbafzadeh, Abdol-Mohammad, Khorramirouz, Reza, Nabavizadeh, Behnam, Ladi Seyedian, Seyedeh-Sanam, Akbarzadeh, Aram, Heidari, Reza, Masoumi, Ahmad, Azizi, Bahram, Seyed Hossein Beigi, Reza
Format: Article
Language:English
Subjects:
Acellular kidney
Angiography
Biocompatibility
Bioscaffold
Computed tomography
Dialysis
End-stage renal disease
Extracellular matrix
Extravasation
Graft rejection
Histopathology
Immunosuppressive agents
In vivo methods and tests
Integrity
Kidney diseases
Kidney transplantation
Kidneys
Materials science
Perfusion
Preservation
Protocol
Protocol (computers)
Scaffolds
Sheep
Sheep model
Tissue engineering
Transplantation
Transplants & implants
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Summary:During the past decade, increased efforts have been made to develop alternative management options instead of dialysis and homograft renal transplantation for end-stage renal disease. State-of-the-art methods employ tissue engineering to produce natural acellular scaffolds that could resolve the concern of allograft rejection and obviate the need for immunosuppressive therapy. Complete decellularization of kidney with intact extracellular matrix is crucial for in vivo compatibility and success of transplantation. Herein, we evaluate the efficacy of two different whole organ decellularization protocols, vasculature integrity, and in vivo transplantation of sheep kidneys. Eight sheep kidneys were decellularized by perfusion-based method utilizing two different protocols (Protocol 1: 1% Triton X-100 and 0.5% SDS vs. Protocol 2: 1% SDS). The samples were evaluated by histopathology in terms of decellularization and extracellular matrix preservation. Computerized tomography angiography was performed to evaluate vasculature. Subsequently, both methods were transplanted in four sheep and monitored for vascular integrity and extravasations in short-term. Scaffolds obtained from both protocols were entirely decellularized. However; the extracellular matrix was better preserved in protocol 1 compared to protocol 2. In addition, the vascular integrity was intact in decellularized scaffolds treated with Triton X-100 plus SDS (protocol 1). After transplantation, the samples treated with protocol 2 showed extravasation of fluid in the interstitial space while the samples treated with protocol 1 showed intact extracellular matrix and vasculature. This study demonstrated the efficacy of well-preserved acellular scaffold and vasculature network in post renal transplant outcome in a sheep model. These results have potential to pave the road for further investigations in acellular whole organ transplantation. •In whole organ decellularization it is of utmost importance to maintain an intact vasculature.•Decellularized scaffolds treated with Triton X-100 + SDS had better vascular integrity.•Acellular kidney transplantation resulted in better outcomes with this protocol in a sheep model.•Preservation of microvasculature could be the mainstays for effective in vitro re-endothelialization.
ISSN:0928-4931
1873-0191
DOI:10.1016/j.msec.2019.01.018