Fibrin supports human fetal islet-epithelial cell differentiation via p70s6k and promotes vascular formation during transplantation

Riopel, Matthew; Li, Jinming; Trinder, Mark; Fellows, George F; Wang, Rennian

doi:10.1038/labinvest.2015.74

Cited by 6 publications

(6 citation statements)

References 55 publications

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“…Fibrin was selected as the hydrogel of choice due to the fact that it has shown success in islet transplantation studies, facilitates microvessel ingrowth, and has an easy-to-use crosslinking mechanism achieved by combining fibrinogen with thrombin. 51 – 55 …”

Section: Resultsmentioning

confidence: 99%

“…Fibrin was selected as the hydrogel of choice due to the fact that it has shown success in islet transplantation studies, facilitates microvessel ingrowth, and has an easyto-use crosslinking mechanism achieved by combining fibrinogen with thrombin. [51][52][53][54][55] Rat-sized BVPs were created using rat pancreatic islets coated around decellularized human umbilical arteries (DHUA) that were 1 mm in diameter and 1-1.5 cm in length, with a wall thickness of 300-500 μm. 56,57 Pancreatic islets were isolated from adult rat pancreata using a series of enzymatic digestion steps, and then were coated onto the outer surface of DHUA by combining islets, fibrinogen, and thrombin together into a mold containing the DHUA (Figure 1(b)).…”

Section: Device Creationmentioning

confidence: 99%

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Development of a Bioartificial Vascular Pancreas

et al. 2021

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Transplantation of pancreatic islets has been shown to be effective, in some patients, for the long-term treatment of type 1 diabetes. However, transplantation of islets into either the portal vein or the subcutaneous space can be limited by insufficient oxygen transfer, leading to islet loss. Furthermore, oxygen diffusion limitations can be magnified when islet numbers are increased dramatically, as in translating from rodent studies to human-scale treatments. To address these limitations, an islet transplantation approach using an acellular vascular graft as a vascular scaffold has been developed, termed the BioVascular Pancreas (BVP). To create the BVP, islets are seeded as an outer coating on the surface of an acellular vascular graft, using fibrin as a hydrogel carrier. The BVP can then be anastomosed as an arterial (or arteriovenous) graft, which allows fully oxygenated arterial blood with a pO2 of roughly 100 mmHg to flow through the graft lumen and thereby supply oxygen to the islets. In silico simulations and in vitro bioreactor experiments show that the BVP design provides adequate survivability for islets and helps avoid islet hypoxia. When implanted as end-to-end abdominal aorta grafts in nude rats, BVPs were able to restore near-normoglycemia durably for 90 days and developed robust microvascular infiltration from the host. Furthermore, pilot implantations in pigs were performed, which demonstrated the scalability of the technology. Given the potential benefits provided by the BVP, this tissue design may eventually serve as a solution for transplantation of pancreatic islets to treat or cure type 1 diabetes.

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Section: Resultsmentioning

confidence: 99%

Section: Device Creationmentioning

confidence: 99%

Development of a Bioartificial Vascular Pancreas

et al. 2021

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“…In the present study, since no metabolically active cells were observed on SDS‐processed bladders, we decided it was not worth performing immunostaining and GSIS with INS‐1 cells seeded on those. Previously, studies have been conducted to characterize INS‐1 cell proliferation and functionality on fibronectin‐coated TCPS, RGD‐coated TCPS, and fibrin 68,71,72 . Here, TCPS was selected as positive control, as it is our established reference for INS‐1 cell attachment and functionality 73 .…”

Section: Resultsmentioning

confidence: 99%

“…Previously, studies have been conducted to characterize INS-1 cell proliferation and functionality on fibronectin-coated TCPS, RGDcoated TCPS, and fibrin. 68,71,72 Here, TCPS was selected as positive control, as it is our established reference for INS-1 cell attachment and functionality. 73 matrices such as MatriStem, Oasis or others could have been an option for instance, but it would be a study on its own, as no study of INS-1 cells on these matrices has been reported.…”

Section: Proliferation Of Ins-1 Cells On Decellularized Bladdersmentioning

confidence: 99%

Decellularized bladder as scaffold to support proliferation and functionality of insulin‐secreting pancreatic cells

Dhandapani

Vermette

2023

J Biomed Mater Res

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Loss in the number or function of insulin‐producing β‐cells in pancreatic islets has been associated with diabetes mellitus. Although islet transplantation can be an alternative treatment, complications such as apoptosis, ischaemia and loss of viability have been reported. The use of decellularized organs as scaffolds in tissue engineering is of interest owing to the unique ultrastructure and composition of the extracellular matrix (ECM) believed to act on tissue regeneration. In this study, a cell culture system has been designed to study the effect of decellularized porcine bladder pieces on INS‐1 cells, a cell line secreting insulin in response to glucose stimulation. Porcine bladders were decellularized using two techniques: a detergent‐containing and a detergent‐free methods. The resulting ECMs were characterized for the removal of both cells and dsDNA. INS‐1 cells were not viable on ECM produced using detergent (i.e., sodium dodecyl sulfate). INS‐1 cells were visualized following 7 days of culture on detergent‐free decellularized bladders using a cell viability and metabolism assay (MTT) and cell proliferation quantified (CyQUANT™ NF Cell Proliferation Assay). Further, glucose‐stimulated insulin secretion and immunostaining confirmed that cells were functional in response to glucose stimulation, as well as they expressed insulin and interacted with the detergent‐free produced ECM, respectively.

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“…Furthermore, much of the prior research has been focused on cellular encapsulation, which prevents vascularization of the transplanted graft, that causes cellular hypoxia, as oxygen is only delivered to the cells through diffusion, leading to either necrosis or greatly reduced function of transplanted islets [17,18]. A macroporous device would allow vascularization of the graft, improving survival and function and reducing delays in glucose sensing, and can be loaded with fibrin, which is biocompatible and degradable, to further promote β cell survival and function along with host integration and vascularization [19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Economic 3D-printing approach for transplantation of human stem cell-derivedβ-like cells

Song

Millman

2016

Biofabrication

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Transplantation of human pluripotent stem cells (hPSC) differentiated into insulin-producing β cells is a regenerative medicine approach being investigated for diabetes cell replacement therapy. This report presents a multifaceted transplantation strategy that combines differentiation into stem cell-derived β (SC-β) cells with 3D printing. By modulating the parameters of a low-cost 3D printer, we created a macroporous device composed of polylactic acid (PLA) that houses SC-β cell clusters within a degradable fibrin gel. Using finite element modeling of cellular oxygen diffusion-consumption and an in vitro culture system that allows for culture of devices at physiological oxygen levels, we identified cluster sizes that avoid severe hypoxia within 3D-printed devices and developed a microwell-based technique for resizing clusters within this range. Upon transplantation into mice, SC-β cell-embedded 3D-printed devices function for 12 weeks, are retrievable, and maintain structural integrity. Here, we demonstrate a novel 3D-printing approach that advances the use of differentiated hPSC for regenerative medicine applications and serves as a platform for future transplantation strategies.

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Fibrin supports human fetal islet-epithelial cell differentiation via p70s6k and promotes vascular formation during transplantation

Cited by 6 publications

References 55 publications

Development of a Bioartificial Vascular Pancreas

Development of a Bioartificial Vascular Pancreas

Decellularized bladder as scaffold to support proliferation and functionality of insulin‐secreting pancreatic cells

Economic 3D-printing approach for transplantation of human stem cell-derivedβ-like cells

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