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Biocompatible polymers with tunable mechanical properties and conductive functionality on two-photon 3D printing

Lijun Men, Kemin Wang, Ningning Hu, Fule Wang, Yucheng Deng, Wenjun Zhang, Ruixue Yin

2023RSC Advances17 citationsDOIOpen Access PDF

Abstract

Two-photon polymerization (TPP)-based 3D printing technology utilizes the two-photon absorption process of near-infrared radiation, enabling the fabrication of micro- and nano-scale three-dimensional structures with extremely high resolution. It has been widely applied in scientific fields closely related to living organisms, such as tissue engineering, drug delivery, and biosensors. Nevertheless, the existing photoresist materials have poor mechanical tunability and are hardly able to be doped with functional materials, resulting in constraints on the preparation of functional devices with micro-nano structures. In this paper, TPP printable polymer formulas with good mechanical tunability, high resolution, strong functional scalability, and excellent biocompatibility are proposed, by using the synergistic effects of a hydroxyl group-containing photocurable resin prepolymer, UV acrylate monomer, long-chain hydrophilic crosslinking monomer and photo-initiator. This can ensure the printability and help to improve the flexibility of the printed polymer, thereby solving the problem the photosensitive materials suitable for two-photon 3D printing in previous research had in balancing the formability and flexibility. The results of nanoindenter analysis showed that the Young's modulus of the printed structure can be adjusted between 0.3 GPa and 1.43 GPa, realizing mechanical tunability. Also, complex structures, such as micro-scaffold structures and high aspect ratio hollow microneedles were printed to explore the structural stability as well as the feasibility of biodevice application. Meanwhile, the proposed polymer formula can be functionalized to be conductive by doping with functional nanomaterial MXene. Finally, the biocompatibility of the proposed polymer formula was studied by culturing with human normal lung epithelial cells. The results indicated a good potential for biodevice applications.

Topics & Concepts

FabricationElectrical conductorBiocompatible materialMaterials science3D printingNanotechnologyPolymerTwo-photon excitation microscopyConductive polymerComposite materialOpticsPhysicsBiomedical engineeringPathologyAlternative medicineMedicineFluorescence3D Printing in Biomedical ResearchNeuroscience and Neural EngineeringAdvanced Sensor and Energy Harvesting Materials
Biocompatible polymers with tunable mechanical properties and conductive functionality on two-photon 3D printing | Litcius