3D生物打印
3D打印
再生医学
活力测定
纳米技术
从长凳到床边
细胞存活
生物医学工程
生物相容性材料
高分辨率
材料科学
生化工程
计算机科学
移植
结构完整性
生物加工
喷墨打印
细胞功能
组织工程
作者
Bowen Li,Zhen Wang,Chuanzhen Huang,Longhua Xu,Shuiquan Huang,Meina Qu,Zhengkai Xu,Dijia Zhang,Baosu Guo,Tianye Jin,Chao Ji
标识
DOI:10.1016/j.medengphy.2025.104448
摘要
Three-dimensional (3D) bioprinting demonstrates significant potential for advancing regenerative medicine through precise fabrication of functional tissue constructs via controlled deposition of cells, biomaterials, and bioactive factors. However, balancing key parameters-printing efficiency, resolution, and cell viability-remains challenging for replicating native tissue complexity. This review comprehensively examines recent advancements in three prominent bioprinting modalities: inkjet, extrusion-based, and digital light processing (DLP). Analysis reveals inherent performance trade-offs among these technologies. Inkjet bioprinting achieves high resolution (10-80 μm) at moderate speeds but exhibits limited cell viability (74-85%). Extrusion-based methods enable higher fabrication rates (0.00785-62.83 mm³/s) with variable viability (40-90%) at reduced resolution (100-2000 μm). DLP offers superior efficiency (0.648-840 mm³/s) and ultra-high resolution (2-50 μm) with favorable viability (75-95%), although limitations persist regarding photoinitiator toxicity and light penetration depth. Critical examination identifies energy-induced cell damage as a significant factor, with shear stress and UV exposure representing key detrimental influences. Bioink properties also emerge as crucial determinants of printing outcomes. The review further integrates modeling approaches for extrusion-based bioprinting and discusses preliminary computational modeling attempts. Future directions should focus on developing low-viscosity cell-compatible bioinks, advancing hybrid printing strategies, and establishing predictive models to harmonize printing parameters with biological outcomes. Interdisciplinary collaboration remains essential to fully realize the clinical potential of bioprinted tissues and organoids.
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