In vitro degradation profiles and in vivo biomaterial–tissue interactions of microwell array delivery devices

To effectively apply microwell array cell delivery devices their biodegradation rate must be tailored towards their intended use and implantation location. Two microwell array devices with distinct degradation profiles, either suitable for the fabrication of retrievable systems in the case of slow d...

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Bibliographic Details
Published in:Journal of biomedical materials research. Part B, Applied biomaterials Applied biomaterials, 2021-01, Vol.109 (1), p.117-127
Main Authors: Hadavi, Elahe, Vries, Rick H.W., Smink, Alexandra M., Haan, Bart, Leijten, Jeroen, Schwab, Leendert W., Karperien, Marcel H.B.J., Vos, Paul, Dijkstra, Pieter J., Apeldoorn, Aart A.
Format: Article
Language:English
Subjects:
Animals
Arrays
Biocompatibility
Biocompatible Materials - chemistry
Biodegradation
Biodegradation, Environmental
Biomaterials
Biomedical materials
cell–material interactions
Ethyl carbamate
Fabrication
Fibrosis
foreign body reactions (response)
Fragmentation
Humans
implant design
Implantation
In Vitro Techniques
Materials research
Materials science
Mechanical Phenomena
Mechanical Tests
Models, Animal
Multilayers
Original Research Report
Original Research Reports
Polybutylene terephthalates
Polyesters - chemistry
Polyethylene glycol
Polyethylene Glycols - chemistry
Polyethylene Terephthalates - chemistry
Polymers
Polyurethanes - chemistry
Prostheses and Implants
Rats
Regeneration
regenerative medicine
Surgical implants
Tensile Strength
Terephthalate
Thin films
Tissue Engineering
Tissue Scaffolds - chemistry
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Summary:To effectively apply microwell array cell delivery devices their biodegradation rate must be tailored towards their intended use and implantation location. Two microwell array devices with distinct degradation profiles, either suitable for the fabrication of retrievable systems in the case of slow degradation, or cell delivery systems capable of extensive remodeling using a fast degrading polymer, were compared in this study. Thin films of a poly(ethylene glycol)‐poly(butylene terephthalate) (PEOT‐PBT) and a poly(ester urethane) were evaluated for their in vitro degradation profiles over 34 weeks incubation in PBS at different pH values. The PEOT‐PBT films showed minimal in vitro degradation over time, while the poly(ester urethane) films showed extensive degradation and fragmentation over time. Subsequently, microwell array cell delivery devices were fabricated from these polymers and intraperitoneally implanted in Albino Oxford rats to study their biocompatibility over a 12‐week period. The PEOT‐PBT implants shown to be capable to maintain the microwell structure over time. Implants provoked a foreign body response resulting in multilayer fibrosis that integrated into the surrounding tissue. The poly(ester urethane) implants showed a loss of the microwell structures over time, as well as a fibrotic response until the onset of fragmentation, at least 4 weeks post implantation. It was concluded that the PEOT‐PBT implants could be used as retrievable cell delivery devices while the poly(ester urethane) implants could be used for cell delivery devices that require remodeling within a 4–12 week period.
ISSN:1552-4973
1552-4981
DOI:10.1002/jbm.b.34686