Your search keyword '"beta cell replacement therapy"' showing total 11 results

1. Replenishable prevascularized cell encapsulation devices increase graft survival and function in the subcutaneous space

Author

Chendke, Gauree S, Kharbikar, Bhushan N, Ashe, Sudipta, Faleo, Gaetano, Sneddon, Julie B, Tang, Qizhi, Hebrok, Matthias, and Desai, Tejal A

Subjects

Engineering, Biomedical Engineering, Autoimmune Disease, Pediatric, Diabetes, Transplantation, Metabolic and endocrine, beta cell replacement therapy, cell encapsulation device, human stem cells, prevascularization, transplantation in subcutaneous space, type 1 diabetes, Biomedical engineering, Chemical engineering

Abstract

Beta cell replacement therapy (BCRT) for patients with type 1 diabetes (T1D) improves blood glucose regulation by replenishing the endogenous beta cells destroyed by autoimmune attack. Several limitations, including immune isolation, prevent this therapy from reaching its full potential. Cell encapsulation devices used for BCRT provide a protective physical barrier for insulin-producing beta cells, thereby protecting transplanted cells from immune attack. However, poor device engraftment posttransplantation leads to nutrient deprivation and hypoxia, causing metabolic strain on transplanted beta cells. Prevascularization of encapsulation devices at the transplantation site can help establish a host vascular network around the implant, increasing solute transport to the encapsulated cells. Here, we present a replenishable prevascularized implantation methodology (RPVIM) that allows for the vascular integration of replenishable encapsulation devices in the subcutaneous space. Empty encapsulation devices were vascularized for 14 days, after which insulin-producing cells were inserted without disrupting the surrounding vasculature. The RPVIM devices were compared with nonprevascularized devices (Standard Implantation Methodology [SIM]) and previously established prevascularized devices (Standard Prevascularization Implantation Methodology [SPVIM]). Results show that over 75% of RPVIM devices containing stem cell-derived insulin-producing beta cell clusters showed a signal after 28 days of implantation in subcutaneous space. Notably, not only was the percent of RPVIM devices showing signal significantly greater than SIM and SPVIM devices, but the intraperitoneal glucose tolerance tests and histological analyses showed that encapsulated stem-cell derived insulin-producing beta cell clusters retained their function in the RPVIM devices, which is crucial for the successful management of T1D.

Published

2023

2. Replenishable prevascularized cell encapsulation devices increase graft survival and function in the subcutaneous space

Author

Gauree S. Chendke, Bhushan N. Kharbikar, Sudipta Ashe, Gaetano Faleo, Julie B. Sneddon, Qizhi Tang, Matthias Hebrok, and Tejal A. Desai

Subjects

beta cell replacement therapy, cell encapsulation device, human stem cells, prevascularization, transplantation in subcutaneous space, type 1 diabetes, Chemical engineering, TP155-156, Biotechnology, TP248.13-248.65, Therapeutics. Pharmacology, RM1-950

Abstract

Abstract Beta cell replacement therapy (BCRT) for patients with type 1 diabetes (T1D) improves blood glucose regulation by replenishing the endogenous beta cells destroyed by autoimmune attack. Several limitations, including immune isolation, prevent this therapy from reaching its full potential. Cell encapsulation devices used for BCRT provide a protective physical barrier for insulin‐producing beta cells, thereby protecting transplanted cells from immune attack. However, poor device engraftment posttransplantation leads to nutrient deprivation and hypoxia, causing metabolic strain on transplanted beta cells. Prevascularization of encapsulation devices at the transplantation site can help establish a host vascular network around the implant, increasing solute transport to the encapsulated cells. Here, we present a replenishable prevascularized implantation methodology (RPVIM) that allows for the vascular integration of replenishable encapsulation devices in the subcutaneous space. Empty encapsulation devices were vascularized for 14 days, after which insulin‐producing cells were inserted without disrupting the surrounding vasculature. The RPVIM devices were compared with nonprevascularized devices (Standard Implantation Methodology [SIM]) and previously established prevascularized devices (Standard Prevascularization Implantation Methodology [SPVIM]). Results show that over 75% of RPVIM devices containing stem cell‐derived insulin‐producing beta cell clusters showed a signal after 28 days of implantation in subcutaneous space. Notably, not only was the percent of RPVIM devices showing signal significantly greater than SIM and SPVIM devices, but the intraperitoneal glucose tolerance tests and histological analyses showed that encapsulated stem‐cell derived insulin‐producing beta cell clusters retained their function in the RPVIM devices, which is crucial for the successful management of T1D.

Published

2023

3. Supporting Survival of Transplanted Stem‐Cell‐Derived Insulin‐Producing Cells in an Encapsulation Device Augmented with Controlled Release of Amino Acids

Author

Chendke, Gauree S, Faleo, Gaetano, Juang, Charity, Parent, Audrey V, Bernards, Daniel A, Hebrok, Matthias, Tang, Qizhi, and Desai, Tejal A

Subjects

Engineering, Biomedical Engineering, Biomedical and Clinical Sciences, Immunology, Transplantation, Regenerative Medicine, Autoimmune Disease, Stem Cell Research - Nonembryonic - Non-Human, Diabetes, Stem Cell Research, 5.2 Cellular and gene therapies, Development of treatments and therapeutic interventions, Metabolic and endocrine, beta cell replacement therapy, cell encapsulation device, nanotechnology, transplantation, type 1 diabetes, Biochemistry and cell biology, Medical biotechnology, Biomedical engineering

Abstract

Pancreatic islet transplantation is a promising treatment for type I diabetes, which is a chronic autoimmune disease in which the host immune cells attack insulin-producing beta cells. The impact of this therapy is limited due to tissue availability and dependence on immunosuppressive drugs that prevent immune rejection of the transplanted cells. These issues can be solved by encapsulating stem cell-derived insulin-producing cells in an immunoprotective device. However, encapsulation exacerbates ischemia, and the lack of vasculature at the implantation site post-transplantation worsens graft survival. Here, an encapsulation device that supplements nutrients to the cells is developed to improve the survival of encapsulated stem cell-derived insulin-producing cells in the poorly vascularized subcutaneous space. An internal compartment in the device is fabricated to provide zero-order release of alanine and glutamine for several weeks. The amino acid reservoir sustains viability of insulin-producing cells in nutrient limiting conditions in vitro. Moreover, the reservoir also increases cell survival by 30% after transplanting the graft in the subcutaneous space.

Published

2019

4. Protecting Stem Cell Derived Pancreatic Beta-Like Cells From Diabetogenic T Cell Recognition

Author

Roberto Castro-Gutierrez, Aimon Alkanani, Clayton E. Mathews, Aaron Michels, and Holger A. Russ

Subjects

autoimmune type 1 diabetes, stem cell derived pancreatic insulin producing beta-like cells, beta- immune cell interface, PD-L1 and HLA class I, beta cell replacement therapy, genome engineering, Diseases of the endocrine glands. Clinical endocrinology, RC648-665

Abstract

Type 1 diabetes results from an autoimmune attack directed at pancreatic beta cells predominantly mediated by T cells. Transplantation of stem cell derived beta-like cells (sBC) have been shown to rescue diabetes in preclinical animal models. However, how sBC will respond to an inflammatory environment with diabetogenic T cells in a strict human setting has not been determined. This is due to the lack of model systems that closely recapitulates human T1D. Here, we present a reliable in vitro assay to measure autologous CD8 T cell stimulation against sBC in a human setting. Our data shows that upon pro-inflammatory cytokine exposure, sBC upregulate Human Leukocyte Antigen (HLA) class I molecules which allows for their recognition by diabetogenic CD8 T cells. To protect sBC from this immune recognition, we utilized genome engineering to delete surface expression of HLA class I molecules and to integrate an inducible overexpression system for the immune checkpoint inhibitor Programmed Death Ligand 1 (PD-L1). Genetically engineered sBC that lack HLA surface expression or overexpress PD-L1 showed reduced stimulation of diabetogenic CD8 T cells when compared to unmodified cells. Here, we present evidence that manipulation of HLA class I and PD-L1 receptors on sBC can provide protection from diabetes-specific immune recognition in a human setting.

Published

2021

5. Protecting Stem Cell Derived Pancreatic Beta-Like Cells From Diabetogenic T Cell Recognition.

Author

Castro-Gutierrez, Roberto, Alkanani, Aimon, Mathews, Clayton E., Michels, Aaron, and Russ, Holger A.

Subjects

CELLULAR recognition, T cells, STEM cells, ANIMAL models of diabetes, STEM cell transplantation, T cell receptors

Abstract

Type 1 diabetes results from an autoimmune attack directed at pancreatic beta cells predominantly mediated by T cells. Transplantation of stem cell derived beta-like cells (sBC) have been shown to rescue diabetes in preclinical animal models. However, how sBC will respond to an inflammatory environment with diabetogenic T cells in a strict human setting has not been determined. This is due to the lack of model systems that closely recapitulates human T1D. Here, we present a reliable in vitro assay to measure autologous CD8 T cell stimulation against sBC in a human setting. Our data shows that upon pro-inflammatory cytokine exposure, sBC upregulate Human Leukocyte Antigen (HLA) class I molecules which allows for their recognition by diabetogenic CD8 T cells. To protect sBC from this immune recognition, we utilized genome engineering to delete surface expression of HLA class I molecules and to integrate an inducible overexpression system for the immune checkpoint inhibitor Programmed Death Ligand 1 (PD-L1). Genetically engineered sBC that lack HLA surface expression or overexpress PD-L1 showed reduced stimulation of diabetogenic CD8 T cells when compared to unmodified cells. Here, we present evidence that manipulation of HLA class I and PD-L1 receptors on sBC can provide protection from diabetes-specific immune recognition in a human setting. [ABSTRACT FROM AUTHOR]

Published

2021

6. Replenishable prevascularized cell encapsulation devices increase graft survival and function in the subcutaneous space.

Author

Faleo, Gaetano, Faleo, Gaetano, Sneddon, Julie, Tang, Qizhi, Hebrok, Matthias, Desai, Tejal, Chendke, Gauree, Kharbikar, Bhushan, Ashe, Sudipta, Faleo, Gaetano, Faleo, Gaetano, Sneddon, Julie, Tang, Qizhi, Hebrok, Matthias, Desai, Tejal, Chendke, Gauree, Kharbikar, Bhushan, and Ashe, Sudipta

Abstract

Beta cell replacement therapy (BCRT) for patients with type 1 diabetes (T1D) improves blood glucose regulation by replenishing the endogenous beta cells destroyed by autoimmune attack. Several limitations, including immune isolation, prevent this therapy from reaching its full potential. Cell encapsulation devices used for BCRT provide a protective physical barrier for insulin-producing beta cells, thereby protecting transplanted cells from immune attack. However, poor device engraftment posttransplantation leads to nutrient deprivation and hypoxia, causing metabolic strain on transplanted beta cells. Prevascularization of encapsulation devices at the transplantation site can help establish a host vascular network around the implant, increasing solute transport to the encapsulated cells. Here, we present a replenishable prevascularized implantation methodology (RPVIM) that allows for the vascular integration of replenishable encapsulation devices in the subcutaneous space. Empty encapsulation devices were vascularized for 14 days, after which insulin-producing cells were inserted without disrupting the surrounding vasculature. The RPVIM devices were compared with nonprevascularized devices (Standard Implantation Methodology [SIM]) and previously established prevascularized devices (Standard Prevascularization Implantation Methodology [SPVIM]). Results show that over 75% of RPVIM devices containing stem cell-derived insulin-producing beta cell clusters showed a signal after 28 days of implantation in subcutaneous space. Notably, not only was the percent of RPVIM devices showing signal significantly greater than SIM and SPVIM devices, but the intraperitoneal glucose tolerance tests and histological analyses showed that encapsulated stem-cell derived insulin-producing beta cell clusters retained their function in the RPVIM devices, which is crucial for the successful management of T1D.

Published

2023

7. Protecting Stem Cell Derived Pancreatic Beta-Like Cells From Diabetogenic T Cell Recognition

Author

Aaron W. Michels, Clayton E. Mathews, Roberto Castro-Gutierrez, Holger A. Russ, and Aimon K. Alkanani

Subjects

0301 basic medicine, PD-L1 and HLA class I, Endocrinology, Diabetes and Metabolism, medicine.medical_treatment, T cell, beta- immune cell interface, Human leukocyte antigen, beta cell replacement therapy, Biology, CD8-Positive T-Lymphocytes, Diseases of the endocrine glands. Clinical endocrinology, B7-H1 Antigen, 03 medical and health sciences, 0302 clinical medicine, Endocrinology, Downregulation and upregulation, Insulin-Secreting Cells, medicine, Diabetes Mellitus, Cytotoxic T cell, Humans, human pluripotent stem cells, Receptor, Cells, Cultured, Original Research, autoimmune type 1 diabetes, Stem Cells, Histocompatibility Antigens Class I, direct differentiation, RC648-665, stem cell derived pancreatic insulin producing beta-like cells, Transplantation, 030104 developmental biology, Cytokine, medicine.anatomical_structure, Cancer research, Stem cell, genome engineering, 030217 neurology & neurosurgery

Abstract

Type 1 diabetes results from an autoimmune attack directed at pancreatic beta cells predominantly mediated by T cells. Transplantation of stem cell derived beta-like cells (sBC) have been shown to rescue diabetes in preclinical animal models. However, how sBC will respond to an inflammatory environment with diabetogenic T cells in a strict human setting has not been determined. This is due to the lack of model systems that closely recapitulates human T1D. Here, we present a reliable in vitro assay to measure autologous CD8 T cell stimulation against sBC in a human setting. Our data shows that upon pro-inflammatory cytokine exposure, sBC upregulate Human Leukocyte Antigen (HLA) class I molecules which allows for their recognition by diabetogenic CD8 T cells. To protect sBC from this immune recognition, we utilized genome engineering to delete surface expression of HLA class I molecules and to integrate an inducible overexpression system for the immune checkpoint inhibitor Programmed Death Ligand 1 (PD-L1). Genetically engineered sBC that lack HLA surface expression or overexpress PD-L1 showed reduced stimulation of diabetogenic CD8 T cells when compared to unmodified cells. Here, we present evidence that manipulation of HLA class I and PD-L1 receptors on sBC can provide protection from diabetes-specific immune recognition in a human setting.

Published

2021

8. Supporting Survival of Transplanted Stem-Cell-Derived Insulin-Producing Cells in an Encapsulation Device Augmented with Controlled Release of Amino Acids.

Author

Chendke, Gauree, Chendke, Gauree, Faleo, Gaetano, Juang, Charity, Parent, Audrey, Desai, Tejal, Hebrok, Matthias, Tang, Qizhi, Bernards, Daniel, Chendke, Gauree, Chendke, Gauree, Faleo, Gaetano, Juang, Charity, Parent, Audrey, Desai, Tejal, Hebrok, Matthias, Tang, Qizhi, and Bernards, Daniel

Abstract

Pancreatic islet transplantation is a promising treatment for type I diabetes, which is a chronic autoimmune disease in which the host immune cells attack insulin-producing beta cells. The impact of this therapy is limited due to tissue availability and dependence on immunosuppressive drugs that prevent immune rejection of the transplanted cells. These issues can be solved by encapsulating stem cell-derived insulin-producing cells in an immunoprotective device. However, encapsulation exacerbates ischemia, and the lack of vasculature at the implantation site post-transplantation worsens graft survival. Here, an encapsulation device that supplements nutrients to the cells is developed to improve the survival of encapsulated stem cell-derived insulin-producing cells in the poorly vascularized subcutaneous space. An internal compartment in the device is fabricated to provide zero-order release of alanine and glutamine for several weeks. The amino acid reservoir sustains viability of insulin-producing cells in nutrient limiting conditions in vitro. Moreover, the reservoir also increases cell survival by 30% after transplanting the graft in the subcutaneous space.

Published

2019

9. Supporting Survival of Transplanted Stem-Cell-Derived Insulin-Producing Cells in an Encapsulation Device Augmented with Controlled Release of Amino Acids

Author

Gaetano Faleo, Matthias Hebrok, Tejal A. Desai, Qizhi Tang, Audrey Parent, Gauree S. Chendke, Charity Juang, and Daniel A. Bernards

Subjects

type 1 diabetes, medicine.medical_treatment, cell encapsulation device, Biomedical Engineering, beta cell replacement therapy, Regenerative Medicine, Autoimmune Disease, General Biochemistry, Genetics and Molecular Biology, Article, Biomaterials, Immune system, medicine, Metabolic and endocrine, Transplantation, nanotechnology, 5.2 Cellular and gene therapies, Chemistry, Insulin, Diabetes, Stem Cell Research, Controlled release, In vitro, Cell biology, Glutamine, Stem Cell Research - Nonembryonic - Non-Human, Pancreatic islet transplantation, Development of treatments and therapeutic interventions, Stem cell

Abstract

Pancreatic islet transplantation is a promising treatment for type I diabetes, which is a chronic autoimmune disease in which the host immune cells attack insulin-producing beta cells. The impact of this therapy is limited due to tissue availability and dependence on immunosuppressive drugs that prevent immune rejection of the transplanted cells. These issues can be solved by encapsulating stem cell-derived insulin-producing cells in an immunoprotective device. However, encapsulation exacerbates ischemia, and the lack of vasculature at the implantation site post-transplantation worsens graft survival. Here, an encapsulation device that supplements nutrients to the cells is developed to improve the survival of encapsulated stem cell-derived insulin-producing cells in the poorly vascularized subcutaneous space. An internal compartment in the device is fabricated to provide zero-order release of alanine and glutamine for several weeks. The amino acid reservoir sustains viability of insulin-producing cells in nutrient limiting conditions in vitro. Moreover, the reservoir also increases cell survival by 30% after transplanting the graft in the subcutaneous space.

Published

2019

10. Selective deletion of human leukocyte antigens protects stem cell-derived islets from immune rejection.

Author

Parent AV, Faleo G, Chavez J, Saxton M, Berrios DI, Kerper NR, Tang Q, and Hebrok M

Subjects

Alleles, Animals, Cell Line, Clone Cells, Humans, Killer Cells, Natural immunology, Lymphocyte Activation immunology, Male, Mice, Inbred NOD, T-Lymphocytes immunology, Mice, Gene Deletion, Graft Rejection immunology, HLA Antigens metabolism, Islets of Langerhans immunology, Pluripotent Stem Cells cytology

Abstract

Stem cell-based replacement therapies hold the promise to restore function of damaged or degenerated tissue such as the pancreatic islets in people with type 1 diabetes. Wide application of these therapies requires overcoming the fundamental roadblock of immune rejection. To address this issue, we use genetic engineering to create human pluripotent stem cells (hPSCs) in which the majority of the polymorphic human leukocyte antigens (HLAs), the main drivers of allogeneic rejection, are deleted. We retain the common HLA class I allele HLA-A2 and less polymorphic HLA-E/F/G to allow immune surveillance and inhibition of natural killer (NK) cells. We employ a combination of in vitro assays and humanized mouse models to demonstrate that these gene manipulations significantly reduce NK cell activity and T-cell-mediated alloimmune response against hPSC-derived islet cells. In summary, our approach produces hypoimmunogenic hPSCs that can be readily matched with recipients to avoid alloimmune rejection., Competing Interests: Declaration of interests M.H. is on the scientific advisory board (SAB) of Encellin and Thymmune Therapeutics; holds stocks in Encellin, Thymmune Therapeutics, and Viacyte; and has received research support from Eli Lilly. He is the co-founder and SAB member of Minutia and EndoCrine Biotherapeutics and holds stocks and options in both companies. A.V.P. is on the SAB of Thymmune Therapeutics and holds stock options in the company. Q.T. is on the SAB of Encellin, eGenesis, and Qihan Bio and holds stocks in Encellin and eGenesis., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

11. Clinical intraocular islet transplantation is not a number issue.

Author

Shishido A, Caicedo A, Rodriguez-Diaz R, Pileggi A, Berggren PO, and Abdulreda MH

Abstract

It is now well established that beta cell replacement through pancreatic islet transplantation results in significant improvement in the quality-of-life of type 1 diabetes (T1D) patients. This is achieved through improved control and prevention of severe drops in blood sugar levels. Islet transplant therapy is on the verge of becoming standard-of-care in the USA. Yet, as with other established transplantation therapies, there remain hurdles to overcome to bring islet transplantation to full fruition as a long-lasting therapy of T1D. One of these hurdles is establishing reliable new sites, other than the liver, where durable efficacy and survival of transplanted islets can be achieved. In this article, we discuss the anterior chamber of the eye as a new site for clinical islet transplantation in the treatment of T1D. We specifically focus on the common conceptions, and preconceptions, on the requirements of islet mass, and whether or not the anterior chamber can accommodate sufficient islets to achieve meaningful efficacy and significant impact on hyperglycemia in clinical application.

Published

2016