Summary
Diabetes mellitus is a chronic disease characterised by high blood glucose due to inadequate insulin production and/or insulin resistance which affects 382 million people worldwide. Pancreatic islet transplantation is an extremely promising cure for insulin-sensitive diabetes mellitus (ISDM), but side effects of lifelong systemic immunosuppressive therapy, short supply of donor islets and their poor survival and efficacy in the portal vein limit the application of the current clinical procedure to the most at-risk brittle Type I diabetes (T1D) sufferers. The DRIVE consortium will develop a novel suite of bio-interactive hydrogels (β-Gel) and on-demand drug release systems to deliver islets in a protective macrocapsule (β-Shell) to the peritoneum with targeted deposition using a specialised injection catheter (β-Cath). Pancreatic islets will be microencapsulated in β-Gels; biofunctionalised injectable hydrogels containing immunosuppressive agents and polymeric microparticles with tuneable degradation profiles for localised delivery of efficacy cues. These β-Gels will be housed in a porous retrievable macrocapsule, β-Shell, for added retention, engraftment, oxygenation, vascularisation and immunoprotection of the islets. A minimally invasive laparoscopic procedure (O-Fold) will be used to create an omental fold and at the same time deliver β-Shell. An extended residence time in β-Gel will enhance long-term clinical efficacy of the islets and result in improved glycemic control. The novel β-Gels will also be developed as human three-dimensional in-vitro models of in-vivo behaviour. Islet harvesting and preservation technologies will be developed to facilitate their optimised yield, safe handling and transport, and ease of storage. DRIVE will also enable the future treatment of a broader range of T1 and insulin-sensitive T2 diabetics by working with induced pluripotent stem cell experts to ensure the compatibility of our system with future stem cell sources of β-cells.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/645991 |
| Start date: | 01-06-2015 |
| End date: | 31-05-2019 |
| Total budget - Public funding: | 8 832 062,75 Euro - 8 832 061,00 Euro |
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Original description
Diabetes mellitus is a chronic disease characterised by high blood glucose due to inadequate insulin production and/or insulin resistance which affects 382 million people worldwide. Pancreatic islet transplantation is an extremely promising cure for insulin-sensitive diabetes mellitus (ISDM), but side effects of lifelong systemic immunosuppressive therapy, short supply of donor islets and their poor survival and efficacy in the portal vein limit the application of the current clinical procedure to the most at-risk brittle Type I diabetes (T1D) sufferers. The DRIVE consortium will develop a novel suite of bio-interactive hydrogels (β-Gel) and on-demand drug release systems to deliver islets in a protective macrocapsule (β-Shell) to the peritoneum with targeted deposition using a specialised injection catheter (β-Cath). Pancreatic islets will be microencapsulated in β-Gels; biofunctionalised injectable hydrogels containing immunosuppressive agents and polymeric microparticles with tuneable degradation profiles for localised delivery of efficacy cues. These β-Gels will be housed in a porous retrievable macrocapsule, β-Shell, for added retention, engraftment, oxygenation, vascularisation and immunoprotection of the islets. A minimally invasive laparoscopic procedure (O-Fold) will be used to create an omental fold and at the same time deliver β-Shell. An extended residence time in β-Gel will enhance long-term clinical efficacy of the islets and result in improved glycemic control. The novel β-Gels will also be developed as human three-dimensional in-vitro models of in-vivo behaviour. Islet harvesting and preservation technologies will be developed to facilitate their optimised yield, safe handling and transport, and ease of storage. DRIVE will also enable the future treatment of a broader range of T1 and insulin-sensitive T2 diabetics by working with induced pluripotent stem cell experts to ensure the compatibility of our system with future stem cell sources of β-cells.Status
CLOSEDCall topic
NMP-10-2014Update Date
27-10-2022
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Organisations
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| NATIONAL UNIVERSITY OF IRELAND GALWAY (NUI Galway) (Coördinator)
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| ABIEL SOCIETA A RESPONSABILITA LIMITATA
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| BOSTON SCIENTIFIC LIMITED
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| CONSORCIO CENTRO DE INVESTIGACION BIOMEDICA EN RED M.P. (CIBER)
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| CONTIPRO AS
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| Dublin City University
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| EBERHARD KARLS UNIVERSITAET TUEBINGEN (EKUT)
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| EXPLORA SRL
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| INNOVA SRL
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| InnoCore Technologies BV
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| L'AZIENDA SOCIO SANITARIA TERRITORIALE (ASST) GRANDE OSPEDALE METROPOLITANO NIGUARDA
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| ROYAL COLLEGE OF SURGEONS IN IRELAND
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| THE CHANCELLOR, MASTERS AND SCHOLARS OF THE UNIVERSITY OF OXFORD
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| UNIVERSITEIT UTRECHT
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| Universidad del País Vasco