Engineering an endocrine Neo-Pancreas by repopulation of a decellularized rat pancreas with islets of Langerhans

Napierala, Hendrik; Hillebrandt, Karl H.; Haep, Nils; Tang, Peter; Tintemann, M.; Gassner, Joseph Maria George Vernon; Noesser, Maximilian; Everwien, Hannah; Seiffert, Nicolai; Kluge, Martin; Teegen, E.; Polenz, Dietrich; Lippert, Steffen; Geisel, Dominik; Reutzel‐Selke, Anja; Raschzok, Nathanael; Ανδρέου, Ανδρέας; Pratschke, Johann; Sauer, Igor M.; Struecker, Benjamin

doi:10.1038/srep41777

Cited by 62 publications

(62 citation statements)

References 36 publications

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“…De et al () were the first researchers to delineate the appropriateness of two‐dimensional (2D) bioscaffolds in whole‐organ engineering. Furthermore, several research groups have evaluated the capacity of in vitro techniques for whole‐organ decellularization and regeneration of pancreatic tissue, including Napierala et al (), who claimed to be the first to provide proof‐of‐concept regeneration of functional islet cells. Hereby, we demonstrate a novel islet cell repopulation technique and the successful production of acellular bioscaffolds.…”

Section: Introductionmentioning

confidence: 99%

Application of a novel bioreactor for in vivo engineering of pancreas tissue

Hashemi

Pasalar

Soleimani

et al. 2017

Journal Cellular Physiology

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Type 1 diabetes is characterized by autoimmune destruction of pancreatic cells. Organ transplantation is an acceptable treatment for native organ failure. However, it is associated with several problems due to a number of reasons, such as the lack of appropriate donors and immunosuppression. In our present study, a novel model is presented for in vivo recellularization of acellular pancreas by implanting between the host pancreas and the adjacent omental flap. In this study, the pancreases were harvested and cannulated via the common bile duct and then, the scaffolds were acellularized by a detergent-based protocol. After that, the abdomens of 35 rats were opened and the spleen was extracted with the adjacent omentum, and placed outside the abdomen. The acellularized scaffold was stretched over the host pancreas and the omentum was wrapped around it to make a sandwich-like structure, which was then fixed with Chromic Sutures 6-0 and marked with Prolene 4-0 on four sides. All samples were biopsied at 14, 30, 60, 90, and 120 days post-transplantation. The result showed marked recellularization of acellularized pancreas with visible neovascularization and neoβ-cells with minimal inflammatory response. This study provides a new approach to produces a normal-like pancreas by allograft transplantation for pancreas tissue engineering. We observed that in vivo transplantation of acellularized pancreas can promote recellularization, proliferation, and differentiation by blood circulation. These findings support that in vivo studies can contribute to finding faster solutions for the treatment of diabetes.

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Section: Introductionmentioning

confidence: 99%

Application of a novel bioreactor for in vivo engineering of pancreas tissue

Hashemi

Pasalar

Soleimani

et al. 2017

Journal Cellular Physiology

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“…Depending on the cell type, the first technique involves recellularization via the vascular network or another hollow structure (e.g. bile duct, ureter, intestinal lumen or airway) . Alternatively, recellularization via direct cellular injection into the parenchymal compartment is also possible.…”

Section: Recellularizationmentioning

confidence: 99%

“…Only a few publications have examined the decellularization of whole pancreas and the subsequent repopulation with islets of Langerhans. Protocols for perfusion‐based decellularization of the mouse, rat, pig and human pancreas have been published , but use different detergents and times to decellularize the pancreas. Detergents include nonionic tensides such as Triton X‐100 and enzymatic agents such as DNAse.…”

Section: Pancreasmentioning

confidence: 99%

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Strategies based on organ decellularization and recellularization

et al. 2019

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Summary Transplantation is the only curative treatment option available for patients suffering from end‐stage organ failure, improving their quality of life and long‐term survival. However, because of organ scarcity, only a small number of these patients actually benefit from transplantation. Alternative treatment options are needed to address this problem. The technique of whole‐organ decellularization and recellularization has attracted increasing attention in the last decade. Decellularization includes the removal of all cellular components from an organ, while simultaneously preserving the micro and macro anatomy of the extracellular matrix. These bioscaffolds are subsequently repopulated with patient‐derived cells, thus constructing a personalized neo‐organ and ideally eliminating the need for immunosuppression. However, crucial problems have not yet been satisfyingly addressed and remain to be resolved, such as organ and cell sources. In this review, we focus on the actual state of organ de‐ and recellularization, as well as the problems and future challenges.

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“…Recently a group headed by Struecker has refined the entire process providing, for the first time, a proof-of-concept for the repopulation of the decellularized rat pancreas with functional islets of Langerhans [123]. Briefly rat pancreas was decellularized via vascular perfusion (1% Triton X: 0.5% SDS and 1% Triton X-100) with a flow-rate around 10 ml/min and then repopulated with approximately 2000 islets via the pancreatic duct to test viability and functionality of the islets after the process.…”

Section: Small Animal Modelsmentioning

confidence: 99%

Bioengineering the Pancreas: Cell-on-Scaffold Technology

Peloso¹,

Citro²,

Oldani³

et al. 2017

Scaffolds in Tissue Engineering - Materials, Technologies and Clinical Applications

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Nowadays, type I diabetes mellitus is a pathology afflicting millions of people globally with a dramatic assessment in the next future. Current treatments including exogenous insulin, pancreas transplantation and islets transplantation, are not free from important lifelong side effects. In the last decade, tissue engineering and regenerative medicine have shown encouraging results about the possibility to produce a functional bioengineered pancreas. Among many technologies, decellularization offers the opportunity to produce an organ-specific acellular matrix that could subsequently repopulate with endocrine cellular population. Herein, we aim to review the state-of-art and this technology highlighting the diabetes burden for the healthcare system and the major achievements toward the manufacturing of a bioengineered pancreas obtained by cell-on-scaffold technology.

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Engineering an endocrine Neo-Pancreas by repopulation of a decellularized rat pancreas with islets of Langerhans

Cited by 62 publications

References 36 publications

Application of a novel bioreactor for in vivo engineering of pancreas tissue

Application of a novel bioreactor for in vivo engineering of pancreas tissue

Strategies based on organ decellularization and recellularization

Bioengineering the Pancreas: Cell-on-Scaffold Technology

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