Geometrically adaptive porous shape memory polymers towards personalized biomedical devices

•An easy yet effective method to realize post-regulation of the permanent shape of porous SMPs via emulsion lyophilization.•Allowing wide range of adjustable porosity for a large volume expansion rate during shape recovery.•Enabling customization of biomedical devices such as shoe insoles, earplugs...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-03, Vol.484, p.149394, Article 149394
Main Authors: Chen, Xiaolan, Zhang, Naiding, Ni, Chujun, Cao, Ruijue, Hu, Lanting, Chen, Jinyi, Zhao, Qian, Xie, Tao, Liu, Zhenjie
Format: Article
Language:English
Subjects:
Biomedical devices
Polymer emulsion
Porous polymer
Shape memory polymer
Shape reconfiguration
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Summary:•An easy yet effective method to realize post-regulation of the permanent shape of porous SMPs via emulsion lyophilization.•Allowing wide range of adjustable porosity for a large volume expansion rate during shape recovery.•Enabling customization of biomedical devices such as shoe insoles, earplugs and embolic sponges for aneurysms treatment. Porous shape memory polymers (SMPs) can execute large volume expansion from their compressed temporary shapes to porous permanent shapes, which present promising practical potentials in biomedical and aerospace fields. While constructing sophisticated geometries are essential for achieving the corresponding functions of the foams, the original shapes which are typically determined by molds cannot be post-tuned in a customized fashion. Here we propose an easy but effective emulsion lyophilization method to fabricate porous SMPs, the original shapes of which can be post-regulated via a two-stage curing mechanism. A thermo-curable acrylate emulsion and a photo-curable polyurethane emulsion were prepared individually and then mixed in proportion. After lyophilization of the mixed emulsion, porous SMPs were prepared due to the first thermo-curing stage between epoxy and amine groups from the acrylate emulsion. The foams can be temporarily programmed into alternative shapes with relatively complex geometries which can afterwards be permanently fixed through the secondary photo-curing stage. In this way, simple permanent shapes of the porous SMPs determined by planar molds were converted into customized three-dimensional ones taking advantage of various deformation such as bending, imprinting, and twisting. Accordingly, customized biomedical devices were fabricated via the two-stage curing process, inspiring further application opportunities for porous SMPs.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2024.149394