AI Article Synopsis
- Nanofiber membranes are promising materials for biomedical use due to their beneficial properties like high surface-to-volume ratios and permeability, resembling natural extracellular structures.
- A new thermal bonding method is introduced to securely attach these membranes to thermoplastic polymer platforms without compromising their structure, using localized preheating.
- This technique has been validated through experiments showing stable bonding for up to 3 weeks, enabling its use in various biomedical applications such as building intestinal barrier models and adapting to different material combinations and shapes.
Article Abstract
Nanofiber (NF) membranes have been highlighted as functional materials for biomedical applications owing to their high surface-to-volume ratios, high permeabilities, and extracellular matrix-like biomimetic structures. Because many platforms for biomedical applications are made of thermoplastic polymers (TP), a simple and leak-free method for bonding NF membranes onto TP platforms is essential. Here, we propose a facile but leak-free localized thermal bonding method for integrating 2D or 3D-structured NF membrane onto a TP supporting substrate while preserving the pristine nanofibrous structure of the membrane, based on localized preheating of the substrate. A methodology for determining the optimal preheating temperature was devised based on a numerical simulation model considering the melting temperature of the NF material and was experimentally validated by evaluating bonding stability and durability under cell culture conditions. The thermally-bonded interface between the NF membrane and TP substrate was maintained stably for 3 weeks allowing the successful construction of an intestinal barrier model. The applicability of the localized thermal bonding method was also demonstrated on various combinations of TP materials (e.g., polystyrene and polymethylmethacrylate) and geometries of the supporting substrate, including a culture insert and microfluidic chip. We expect the proposed localized thermal bonding method to contribute toward broadening and realizing the practical applications of functional NF membranes in various biomedical fields.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10192924 | PMC |
| http://dx.doi.org/10.1016/j.mtbio.2023.100648 | DOI Listing |
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