Your search keyword '"Suenens, Krista G."' showing total 4 results

1. Functional Beta Cell Mass from Device-Encapsulated hESC-Derived Pancreatic Endoderm Achieving Metabolic Control

Author

Robert, Thomas, De Mesmaeker, Ines, Stangé, Geert M., Suenens, Krista G., Ling, Zhidong, Kroon, Evert J., and Pipeleers, Daniel G.

Published

2018

2. Comparison of Omentum and Subcutis as Implant Sites for Device-Encapsulated Human iPSC-Derived Pancreatic Endoderm in Nude Rats.

Author

Nijns, Jolien R., De Mesmaeker, Ines, Suenens, Krista G., Stangé, Geert M., De Groot, Kaat, Marques de Lima, Maria, Kraus, Marine R. C., Keymeulen, Bart, Waelput, Wim, Jacobs-Tulleneers Thevissen, Daniel, and Pipeleers, Daniel G.

Subjects

PANCREATIC beta cells, ENDODERM, OMENTUM, XENOGRAFTS, RATS, CELL differentiation

Abstract

Subcutaneous implants of device-encapsulated stem cell-derived pancreatic endoderm (PE) can establish a functional beta cell mass (FBM) with metabolic control in immune-compromised mice. In a study with human-induced pluripotent stem cell-PE, this outcome was favored by a preformed pouch which allowed lesion-free insertion of devices in a pre-vascularized site. This was not reproduced in nude rats, known to exhibit a higher innate reactivity than mice and therefore relevant as preclinical model: a dense fibrotic capsule formed around subcutis (SC) implants with virtually no FBM formation. Placement in omentum (OM) of nude rats provided a less fibrous, better vascularized environment than SC. It resulted in less donor cell loss (56% recovery at post-transplant-PT week 3 versus 16% in SC) allowing FBM-formation. At PT week 30, 6/13 OM-recipients exhibited glucose-induced plasma hu-C-peptide to 0.1-0.4 ng/ml, versus 0/8 in SC-recipients. These levels are more than 10-fold lower than in a state of metabolic control. This shortcoming is not caused by inadequate glucose responsiveness of the beta cells but by their insufficient number. The size of the formed beta cell mass (0.4 ± 0.2 µl) was lower than that reported in mice receiving the same cell product subcutaneously; the difference is attributed to a lower expansion of pancreatic progenitor cells and to their lower degree of differentiation to beta cells. This study in the nude rat model demonstrates that OM provides a better environment for formation of beta cells in device-encapsulated PE-implants than SC. It also identified targets for increasing their dose-efficacy. [ABSTRACT FROM AUTHOR]

Published

2023

3. Cell Mass Increase Associated with Formation of Glucose‐Controlling β‐Cell Mass in Device‐Encapsulated Implants of hiPS‐Derived Pancreatic Endoderm.

Author

Robert, Thomas, De Mesmaeker, Ines, Van Hulle, Freya O., Suenens, Krista G., Stangé, Geert M., Ling, Zhidong, Haller, Corinne, Bouche, Nicolas, Keymeulen, Bart, Kraus, Marine R.C., and Pipeleers, Daniel G.

Published

2019

4. Increase Functional β-Cell Mass in Subcutaneous Alginate Capsules With Porcine Prenatal Islet Cells but Loss With Human Adult Islet Cells.

Author

De Mesmaeker, Ines, Robert, Thomas, Suenens, Krista G., Stangé, Geert M., Van Hulle, Freya, Ling, Zhidong, Tomme, Peter, Jacobs-Tulleneers-Thevissen, Daniel, Pipeleers, Bart Keymeulen and Daniel G., Keymeulen, Bart, and Pipeleers, Daniel G

Subjects

ALGINIC acid, ISLANDS of Langerhans, METABOLIC regulation, DNA replication, PERITONEUM, ISLANDS of Langerhans transplantation, ALGINATES, ANIMAL experimentation, C-peptide, PHARMACEUTICAL encapsulation, COMPARATIVE studies, INSULIN, RESEARCH methodology, MEDICAL cooperation, MICE, RESEARCH, SWINE, EVALUATION research

Abstract

Alginate (Alg)-encapsulated porcine islet cell grafts are developed to overcome limitations of human islet transplantation. They can generate functional implants in animals when prepared from fetal, perinatal, and adult pancreases. Implants have not yet been examined for efficacy to establish sustained, metabolically adequate functional β-cell mass (FBM) in comparison with human islet cells. This study in immune-compromised mice demonstrates that subcutaneous implants of Alg-encapsulated porcine prenatal islet cells with 4 × 105 β-cells form, over 10 weeks, a FBM that results in glucose-induced plasma C-peptide >2 ng/mL and metabolic control over the following 10 weeks, with higher efficiency than nonencapsulated, while failing in peritoneum. This intracapsular FBM formation involves β-cell replication, increasing number fourfold, and maturation toward human adult β-cells. Subcutaneous Alg-encapsulated human islet cells with similar β-cell number establish implants with plasma C-peptide >2 ng/mL for the first 10 weeks, with nonencapsulated cells failing; their β-cells do not replicate but progressively die (>70%), explaining C-peptide decline and insufficient metabolic control. An Alg matrix thus helps establish β-cell functions in subcutis. It allows formation of sustained metabolically adequate FBM by immature porcine β-cells with proliferative activity but not by human adult islet cells. These findings define conditions for evaluating its immune-protecting properties. [ABSTRACT FROM AUTHOR]

Published

2018