Your search keyword '"Rotem, Avi"' showing total 18 results

1. Favorable outcome of experimental islet xenotransplantation without immunosuppression in a nonhuman primate model of diabetes

Author

Ludwig, Barbara, Ludwig, Stefan, Steffen, Anja, Knauf, Yvonne, Zimerman, Baruch, Heinke, Sophie, Lehmann, Susann, Schubert, Undine, Schmid, Janine, Bleyer, Martina, Schönmann, Uwe, Colton, Clark K., Bonifacio, Ezio, Solimena, Michele, Reichel, Andreas, Schally, Andrew V., Rotem, Avi, Barkai, Uriel, Grinberg-Rashi, Helena, Kaup, Franz-Josef, Avni, Yuval, Jones, Peter, and Bornstein, Stefan R.

Published

2017

2. Transplantation of bovine adrenocortical cells encapsulated in alginate

Author

Balyura, Mariya, Gelfgat, Evgeny, Ehrhart-Bornstein, Monika, Ludwig, Barbara, Gendler, Zohar, Barkai, Uriel, Zimerman, Baruch, Rotem, Avi, Block, Norman L., Schally, Andrew V., and Bornstein, Stefan R.

Published

2015

3. Transplantation of human islets without immunosuppression

Author

Ludwig, Barbara, Reichel, Andreas, Steffen, Anja, Zimerman, Baruch, Schally, Andrew V., Block, Norman L., Colton, Clark K., Ludwig, Stefan, Kersting, Stephan, Bonifacio, Ezio, Solimena, Michele, Gendler, Zohar, Rotem, Avi, Barkai, Uriel, and Bornstein, Stefan R.

Published

2013

4. Improvement of islet function in a bioartificial pancreas by enhanced oxygen supply and growth hormone releasing hormone agonist

Author

Ludwig, Barbara, Rotem, Avi, Schmid, Janine, Weir, Gordon C., Colton, Clark K., Brendel, Mathias D., Neufeld, Tova, Block, Norman L., Yavriyants, Karina, Steffen, Anja, Ludwig, Stefan, Chavakis, Triantafyllos, Reichel, Andreas, Azarov, Dimitri, Zimermann, Baruch, Maimon, Shiri, Balyura, Mariya, Rozenshtein, Tania, Shabtay, Noa, Vardi, Pnina, Bloch, Konstantin, de Vos, Paul, Schally, Andrew V., Bornstein, Stefan R., and Barkai, Uriel

Published

2012

5. Long-term viability and function of transplanted islets macroencapsulated at high density are achieved by enhanced oxygen supply

Author

Evron, Yoav, Colton, Clark K., Ludwig, Barbara, Weir, Gordon C., Zimermann, Baruch, Maimon, Shiri, Neufeld, Tova, Shalev, Nurit, Goldman, Tali, Leon, Assaf, Yavriyants, Karina, Shabtay, Noa, Rozenshtein, Tania, Azarov, Dimitri, DiIenno, Amanda R., Steffen, Anja, de Vos, Paul, Bornstein, Stefan R., Barkai, Uriel, Rotem, Avi, Colton, Clark K, DiIenno, Amanda Rose, Translational Immunology Groningen (TRIGR), Man, Biomaterials and Microbes (MBM), University of Zurich, Colton, Clark K, Massachusetts Institute of Technology. Department of Chemical Engineering, and DiIenno, Amanda Rose

Subjects

0301 basic medicine, Blood Glucose, Male, BIOARTIFICIAL PANCREAS, endocrine system diseases, 10265 Clinic for Endocrinology and Diabetology, Islets of Langerhans Transplantation, lcsh:Medicine, HYPOXIA, 02 engineering and technology, Oxygen, lcsh:Science, Oxygen supply, Multidisciplinary, geography.geographical_feature_category, IMMUNOSUPPRESSION, Chemistry, Graft Survival, 021001 nanoscience & nanotechnology, Islet, DIFFUSION, ALGINATE, 0210 nano-technology, BETA-CELL MASS, endocrine system, Intravenous Glucose Tolerance, Alginates, Cell Survival, chemistry.chemical_element, High density, 610 Medicine & health, Gas chamber, Article, Diabetes Mellitus, Experimental, 03 medical and health sciences, Islets of Langerhans, Oxygen Consumption, Animals, Immunosuppression Therapy, geography, 1000 Multidisciplinary, LANGERHANS, Oxygen metabolism, lcsh:R, CONSUMPTION, Glucose Tolerance Test, Rats, Transplantation, 030104 developmental biology, Rats, Inbred Lew, RAT, lcsh:Q, IMMUNE-SYSTEM, Biomedical engineering

Abstract

Transplantation of encapsulated islets can cure diabetes without immunosuppression, but oxygen supply limitations can cause failure. We investigated a retrievable macroencapsulation device wherein islets are encapsulated in a planar alginate slab and supplied with exogenous oxygen from a replenishable gas chamber. Translation to clinically-useful devices entails reduction of device size by increasing islet surface density, which requires increased gas chamber pO[subscript 2]. Here we show that islet surface density can be substantially increased safely by increasing gas chamber pO[subscript 2] to a supraphysiological level that maintains all islets viable and functional. These levels were determined from measurements of pO[subscript 2] profiles in islet-alginate slabs. Encapsulated islets implanted with surface density as high as 4,800 islet equivalents/cm[superscrip 3] in diabetic rats maintained normoglycemia for more than 7 months and provided near-normal intravenous glucose tolerance tests. Nearly 90% of the original viable tissue was recovered after device explantation. Damaged islets failed after progressively shorter times. The required values of gas chamber p[subscript O] were predictable from a mathematical model of oxygen consumption and diffusion in the device. These results demonstrate feasibility of developing retrievable macroencapsulated devices small enough for clinical use and provide a firm basis for design of devices for testing in large animals and humans., Israel. Ministry of Science

Published

2018

6. Transplantation of macroencapsulated human islets within the bioartificial pancreas βAir to patients with type 1 diabetes mellitus

Author

Carlsson, Per-Ola, Espes, Daniel, Sedigh, Amir, Rotem, Avi, Zimerman, Baruch, Grinberg, Helena, Goldman, Tali, Barkai, Uriel, Avni, Yuval, Westermark, Gunilla T., Carlbom, Lina, Ahlström, Håkan, Eriksson, Olof, Olerud, Johan, and Korsgren, Olle

Subjects

Blood Glucose, Male, Pancreas, Artificial, Adolescent, translational research/science, Islets of Langerhans Transplantation, Capsules, Endocrinology and Diabetes, clinical research/practice, Islets of Langerhans, endocrinology, Humans, Child, science, Monitoring, Physiologic, Bioartificial Organs, diabetology, islet transplantation, Kirurgi, Immunology in the medical area, Clinical Science, Prognosis, practice, Diabetes Mellitus, Type 1, clinical research, translational research, type 1 [diabetes], Child, Preschool, cellular biology, Immunologi inom det medicinska området, diabetes: type 1, Endokrinologi och diabetes, encapsulation, Female, Original Article, Surgery, endocrinology/diabetology, ORIGINAL ARTICLES, islets of Langerhans, Follow-Up Studies

Abstract

Macroencapsulation devices provide the dual possibility of immunoprotecting transplanted cells while also being retrievable, the latter bearing importance for safety in future trials with stem cell–derived cells. However, macroencapsulation entails a problem with oxygen supply to the encapsulated cells. The βAir device solves this with an incorporated refillable oxygen tank. This phase 1 study evaluated the safety and efficacy of implanting the βAir device containing allogeneic human pancreatic islets into patients with type 1 diabetes. Four patients were transplanted with 1‐2 βAir devices, each containing 155 000‐180 000 islet equivalents (ie, 1800‐4600 islet equivalents per kg body weight), and monitored for 3‐6 months, followed by the recovery of devices. Implantation of the βAir device was safe and successfully prevented immunization and rejection of the transplanted tissue. However, although beta cells survived in the device, only minute levels of circulating C‐peptide were observed with no impact on metabolic control. Fibrotic tissue with immune cells was formed in capsule surroundings. Recovered devices displayed a blunted glucose‐stimulated insulin response, and amyloid formation in the endocrine tissue. We conclude that the βAir device is safe and can support survival of allogeneic islets for several months, although the function of the transplanted cells was limited (Clinicaltrials.gov: NCT02064309)., An investigator‐initiated phase 1 study of the safety and efficacy of implanting the macroencapsulation device βAir with an incorporated refillable oxygen tank containing allogeneic human pancreatic islets into 4 patients with type 1 diabetes shows that the device is safe and can support survival of allogeneic islets for several months, though the function of the transplanted cells is limited.

Published

2018

7. Transplantation of macroencapsulated human islets within the bioartificial pancreas βAir to patients with type 1 diabetes mellitus

Author

Carlsson, Per-Ola, primary, Espes, Daniel, additional, Sedigh, Amir, additional, Rotem, Avi, additional, Zimerman, Baruch, additional, Grinberg, Helena, additional, Goldman, Tali, additional, Barkai, Uriel, additional, Avni, Yuval, additional, Westermark, Gunilla T., additional, Carlbom, Lina, additional, Ahlström, Håkan, additional, Eriksson, Olof, additional, Olerud, Johan, additional, and Korsgren, Olle, additional

Published

2018

8. This title is unavailable for guests, please login to see more information.

Author

Carlsson, Per-Ola, Espes, Daniel, Sedigh, Amir, Rotem, Avi, Zimermann, Baruch, Grinberg, Helena, Goldman, Tali, Barkai, Uriel, Avni, Yuval, Westermark, Gunilla T., Carlbom, Lina, Ahlström, Håkan, Eriksson, Olof, Olerud, Johan, Korsgren, Olle, Carlsson, Per-Ola, Espes, Daniel, Sedigh, Amir, Rotem, Avi, Zimermann, Baruch, Grinberg, Helena, Goldman, Tali, Barkai, Uriel, Avni, Yuval, Westermark, Gunilla T., Carlbom, Lina, Ahlström, Håkan, Eriksson, Olof, Olerud, Johan, and Korsgren, Olle

Abstract

De två första författarna delar förstaförfattarskapet.

Published

2018

9. Long-term viability and function of transplanted islets macroencapsulated at high density are achieved by enhanced oxygen supply

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K, DiIenno, Amanda Rose, Evron, Yoav, Colton, Clark K., Ludwig, Barbara, Weir, Gordon C., Zimermann, Baruch, Maimon, Shiri, Neufeld, Tova, Shalev, Nurit, Goldman, Tali, Leon, Assaf, Yavriyants, Karina, Shabtay, Noa, Rozenshtein, Tania, Azarov, Dimitri, DiIenno, Amanda R., Steffen, Anja, de Vos, Paul, Bornstein, Stefan R., Barkai, Uriel, Rotem, Avi, Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K, DiIenno, Amanda Rose, Evron, Yoav, Colton, Clark K., Ludwig, Barbara, Weir, Gordon C., Zimermann, Baruch, Maimon, Shiri, Neufeld, Tova, Shalev, Nurit, Goldman, Tali, Leon, Assaf, Yavriyants, Karina, Shabtay, Noa, Rozenshtein, Tania, Azarov, Dimitri, DiIenno, Amanda R., Steffen, Anja, de Vos, Paul, Bornstein, Stefan R., Barkai, Uriel, and Rotem, Avi

Abstract

Transplantation of encapsulated islets can cure diabetes without immunosuppression, but oxygen supply limitations can cause failure. We investigated a retrievable macroencapsulation device wherein islets are encapsulated in a planar alginate slab and supplied with exogenous oxygen from a replenishable gas chamber. Translation to clinically-useful devices entails reduction of device size by increasing islet surface density, which requires increased gas chamber pO[subscript 2]. Here we show that islet surface density can be substantially increased safely by increasing gas chamber pO[subscript 2] to a supraphysiological level that maintains all islets viable and functional. These levels were determined from measurements of pO[subscript 2] profiles in islet-alginate slabs. Encapsulated islets implanted with surface density as high as 4,800 islet equivalents/cm[superscrip 3] in diabetic rats maintained normoglycemia for more than 7 months and provided near-normal intravenous glucose tolerance tests. Nearly 90% of the original viable tissue was recovered after device explantation. Damaged islets failed after progressively shorter times. The required values of gas chamber p[subscript O] were predictable from a mathematical model of oxygen consumption and diffusion in the device. These results demonstrate feasibility of developing retrievable macroencapsulated devices small enough for clinical use and provide a firm basis for design of devices for testing in large animals and humans., Israel. Ministry of Science

Published

2018

10. Favorable outcome of experimental islet xenotransplantation without immunosuppression in a nonhuman primate model of diabetes

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K, Ludwig, Barbara, Ludwig, Stefan, Steffen, Anja, Knauf, Yvonne, Zimerman, Baruch, Heinke, Sophie, Lehmann, Susann, Schubert, Undine, Schmid, Janine, Bleyer, Martina, Schönmann, Uwe, Bonifacio, Ezio, Solimena, Michele, Reichel, Andreas, Schally, Andrew V., Rotem, Avi, Barkai, Uriel, Grinberg-Rashi, Helena, Kaup, Franz-Josef, Avni, Yuval, Jones, Peter, Bornstein, Stefan R., Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K, Ludwig, Barbara, Ludwig, Stefan, Steffen, Anja, Knauf, Yvonne, Zimerman, Baruch, Heinke, Sophie, Lehmann, Susann, Schubert, Undine, Schmid, Janine, Bleyer, Martina, Schönmann, Uwe, Bonifacio, Ezio, Solimena, Michele, Reichel, Andreas, Schally, Andrew V., Rotem, Avi, Barkai, Uriel, Grinberg-Rashi, Helena, Kaup, Franz-Josef, Avni, Yuval, Jones, Peter, and Bornstein, Stefan R.

Abstract

Transplantation of pancreatic islets for treating type 1 diabetes is restricted to patients with critical metabolic lability resulting from the need for immunosuppression and the shortage of donor organs. To overcome these barriers, we developed a strategy to macroencap-sulate islets from different sources that allow their survival and function without immunosuppression. Here we report successful and safe transplantation of porcine islets with a bioartificial pancreas device in diabetic primates without any immune suppression. This strategy should lead to pioneering clinical trials with xenotransplantation for treatment of diabetes and, thereby, represents a previously unidentified approach to efficient cell replacement for a broad spectrum of endocrine disorders and other organ dysfunctions. Keywords: diabetes; porcine islets; beta-cell replacement; immune barrier

Published

2018

11. Survival of encapsulated islets: More than a membrane story

Author

Barkai, Uriel, primary, Rotem, Avi, additional, and de Vos, Paul, additional

Published

2016

12. Extended Microbiological Characterization of Göttingen Minipigs in the Context of Xenotransplantation: Detection and Vertical Transmission of Hepatitis E Virus

Author

Morozov, Vladimir A., primary, Morozov, Alexey V., additional, Rotem, Avi, additional, Barkai, Uriel, additional, Bornstein, Stefan, additional, and Denner, Joachim, additional

Published

2015

13. Transplantation of human islets without immunosuppression

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Ludwig, Barbara, Reichel, Andreas, Steffen, Anja, Zimerman, Baruch, Schally, Andrew V., Block, Norman L., Ludwig, Stefan, Kersting, Stephan, Bonifacio, Ezio, Solimena, Michele, Gendler, Zohar, Rotem, Avi, Barkai, Uriel, Bornstein, Stefan R., Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Ludwig, Barbara, Reichel, Andreas, Steffen, Anja, Zimerman, Baruch, Schally, Andrew V., Block, Norman L., Ludwig, Stefan, Kersting, Stephan, Bonifacio, Ezio, Solimena, Michele, Gendler, Zohar, Rotem, Avi, Barkai, Uriel, and Bornstein, Stefan R.

Abstract

Transplantation of pancreatic islets is emerging as a successful treatment for type-1 diabetes. Its current stringent restriction to patients with critical metabolic lability is justified by the long-term need for immunosuppression and a persistent shortage of donor organs. We developed an oxygenated chamber system composed of immune-isolating alginate and polymembrane covers that allows for survival and function of islets without immunosuppression. A patient with type-1 diabetes received a transplanted chamber and was followed for 10 mo. Persistent graft function in this chamber system was demonstrated, with regulated insulin secretion and preservation of islet morphology and function without any immunosuppressive therapy. This approach may allow for future widespread application of cell-based therapies.

Published

2014

14. The Efficacy of an Immunoisolating Membrane System for Islet Xenotransplantation in Minipigs

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Neufeld, Tova, Ludwig, Barbara, Barkai, Uriel, Weir, Gordon C., Evron, Yoav, Balyura, Maria, Yavriyants, Karina, Zimermann, Baruch, Azarov, Dmitri, Maimon, Shiri, Shabtay, Noa, Rozenshtein, Tania, Lorber, Dana, Steffen, Anja, Willenz, Udi, Bloch, Konstantin, Vardi, Pnina, Taube, Ran, de Vos, Paul, Lewis, Eli C., Bornstein, Stefan R., Rotem, Avi, Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Neufeld, Tova, Ludwig, Barbara, Barkai, Uriel, Weir, Gordon C., Evron, Yoav, Balyura, Maria, Yavriyants, Karina, Zimermann, Baruch, Azarov, Dmitri, Maimon, Shiri, Shabtay, Noa, Rozenshtein, Tania, Lorber, Dana, Steffen, Anja, Willenz, Udi, Bloch, Konstantin, Vardi, Pnina, Taube, Ran, de Vos, Paul, Lewis, Eli C., Bornstein, Stefan R., and Rotem, Avi

Abstract

Developing a device that protects xenogeneic islets to allow treatment and potentially cure of diabetes in large mammals has been a major challenge in the past decade. Using xenogeneic islets for transplantation is required in light of donor shortage and the large number of diabetic patients that qualify for islet transplantation. Until now, however, host immunoreactivity against the xenogeneic graft has been a major drawback for the use of porcine islets. Our study demonstrates the applicability of a novel immunoprotective membrane that allows successful xenotransplantation of rat islets in diabetic minipigs without immunosuppressive therapy. Rat pancreatic islets were encapsulated in highly purified alginate and integrated into a plastic macrochamber covered by a poly-membrane for subcutaneous transplantation. Diabetic Sinclair pigs were transplanted and followed for up to 90 days. We demonstrated a persistent graft function and restoration of normoglycemia without the need for immunosuppressive therapy. This concept could potentially offer an attractive strategy for a more widespread islet replacement therapy that would restore endogenous insulin secretion in diabetic patients without the need for immunosuppressive drugs and may even open up an avenue for safe utilization of xenogeneic islet donors.

Published

2013

15. Improvement of islet function in a bioartificial pancreas by enhanced oxygen supply and growth hormone releasing hormone agonist

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Ludwig, Barbara, Rotem, Avi, Schmid, Janine, Weir, Gordon C., Brendel, Mathias D., Neufeld, Tova, Block, Norman L., Yavriyants, Karina, Steffen, Anja, Ludwig, Stefan, Chavakis, Triantafyllos, Reichel, Andreas, Azarov, Dmitri, Zimermann, Baruch, Maimon, Shiri, Balyura, Maria, Rozenshtein, Tania, Shabtay, Noa, Vardi, Pnina, Bloch, Konstantin, de Vos, Paul, Schally, Andrew V., Bornstein, Stefan R., Barkai, Uriel, Massachusetts Institute of Technology. Department of Chemical Engineering, Colton, Clark K., Ludwig, Barbara, Rotem, Avi, Schmid, Janine, Weir, Gordon C., Brendel, Mathias D., Neufeld, Tova, Block, Norman L., Yavriyants, Karina, Steffen, Anja, Ludwig, Stefan, Chavakis, Triantafyllos, Reichel, Andreas, Azarov, Dmitri, Zimermann, Baruch, Maimon, Shiri, Balyura, Maria, Rozenshtein, Tania, Shabtay, Noa, Vardi, Pnina, Bloch, Konstantin, de Vos, Paul, Schally, Andrew V., Bornstein, Stefan R., and Barkai, Uriel

Published

2012

16. The Efficacy of an Immunoisolating Membrane System for Islet Xenotransplantation in Minipigs

Author

Neufeld, Tova, primary, Ludwig, Barbara, additional, Barkai, Uriel, additional, Weir, Gordon C., additional, Colton, Clark K., additional, Evron, Yoav, additional, Balyura, Maria, additional, Yavriyants, Karina, additional, Zimermann, Baruch, additional, Azarov, Dmitri, additional, Maimon, Shiri, additional, Shabtay, Noa, additional, Rozenshtein, Tania, additional, Lorber, Dana, additional, Steffen, Anja, additional, Willenz, Udi, additional, Bloch, Konstantine, additional, Vardi, Pnina, additional, Taube, Ran, additional, de Vos, Paul, additional, Lewis, Eli C., additional, Bornstein, Stefan R., additional, and Rotem, Avi, additional

Published

2013

17. Effect of Nitrogen on Polysaccharide Production in a Porphyridium sp

Author

Arad, Shoshana (Malis), primary, Friedman, Orit (Dahan), additional, and Rotem, Avi, additional

Published

1988

18. Long-term viability and function of transplanted islets macroencapsulated at high density are achieved by enhanced oxygen supply.

Author

Evron Y, Colton CK, Ludwig B, Weir GC, Zimermann B, Maimon S, Neufeld T, Shalev N, Goldman T, Leon A, Yavriyants K, Shabtay N, Rozenshtein T, Azarov D, DiIenno AR, Steffen A, de Vos P, Bornstein SR, Barkai U, and Rotem A

Subjects

Alginates metabolism, Animals, Blood Glucose metabolism, Blood Glucose physiology, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Experimental physiopathology, Glucose Tolerance Test methods, Graft Survival physiology, Immunosuppression Therapy methods, Male, Oxygen Consumption physiology, Rats, Rats, Inbred Lew, Cell Survival physiology, Islets of Langerhans metabolism, Islets of Langerhans physiology, Islets of Langerhans Transplantation physiology, Oxygen metabolism

Abstract

Transplantation of encapsulated islets can cure diabetes without immunosuppression, but oxygen supply limitations can cause failure. We investigated a retrievable macroencapsulation device wherein islets are encapsulated in a planar alginate slab and supplied with exogenous oxygen from a replenishable gas chamber. Translation to clinically-useful devices entails reduction of device size by increasing islet surface density, which requires increased gas chamber pO 2. Here we show that islet surface density can be substantially increased safely by increasing gas chamber pO 2 to a supraphysiological level that maintains all islets viable and functional. These levels were determined from measurements of pO 2 profiles in islet-alginate slabs. Encapsulated islets implanted with surface density as high as 4,800 islet equivalents/cm 3 in diabetic rats maintained normoglycemia for more than 7 months and provided near-normal intravenous glucose tolerance tests. Nearly 90% of the original viable tissue was recovered after device explantation. Damaged islets failed after progressively shorter times. The required values of gas chamber pO 2 were predictable from a mathematical model of oxygen consumption and diffusion in the device. These results demonstrate feasibility of developing retrievable macroencapsulated devices small enough for clinical use and provide a firm basis for design of devices for testing in large animals and humans.

Published

2018