Hydrogel-Composited Laminate for Islet Immune-Isolation to Treat Type 1 Diabetes.
Yi WangKai WangXi WangYing LuoHaifeng ChenPublished in: ACS applied materials & interfaces (2024)
Challenges remain to be solved for the clinical translation of β-cell encapsulation technology in the treatment of type 1 diabetes (T1D). Successful delivery of β cells urgently needs the development of an encapsulation device with a thin dimension and rapid mass transport that offers stable immune isolation and complete retrieval. In this study, we focus on a laminate in which an islet-embedding alginate hydrogel layer (Alg) is sandwiched between two polymer layers (polyether sulfone, PES). Mechanical support by the PES layer protects the alginate from disintegrating after implantation and allows complete retrieval. The multilayered device has a thin membrane configuration (∼1 mm), and the edge of the laminate and the gaps between Alg and PES offer a semiopen structure that could be more permeable to molecules compared with the closed pocket of conventional macroencapsulation. Islets are suspended in the alginate solution and then encapsulated in the hydrogel layer in the middle of the laminate after gelation. Encapsulating syngeneic or xenogeneic islets in the laminate device corrected chemically induced T1D in mice for over 90 days in both the intraperitoneal space and the epididymal fat pad. The multilayered membrane system may therefore provide a translatable solution in β cell-transplantation therapy in T1D.
Keyphrases
- wound healing
- tissue engineering
- type diabetes
- drug delivery
- cell therapy
- single cell
- hyaluronic acid
- induced apoptosis
- adipose tissue
- cardiovascular disease
- glycemic control
- diabetic rats
- fatty acid
- cell proliferation
- metabolic syndrome
- high fat diet induced
- endoplasmic reticulum stress
- cell death
- replacement therapy
- sensitive detection