Study on femoral 3D reconstruction and computer aid low-temperature deposition manufacturing / 生物医学工程学杂志

Serious femoral damages are a common human bone disease. Rebuilding the femur and studying its mechanical properties are a continuous medical research topic, but traditional femoral prosthesis often cause some problems such as prosthesis loosening. In this work, we selected a healthy male, took his femur scanning by CT, and rebuilt high-precision femur prototypes by Mimics10.0 software, then chose the material having good biocompatibility and biodegradable, utilizing low-temperature deposition manufacturing (LDM) technology for the femoral manufacturing. This approach, fabricating the femur via LDM technology, laid a foundation for the later research on the femoral implantation in the human body.

Design of a three-dimensionally controlled multi-cell-assembly system based on the control of a mixer nozzle / 生物医学工程学杂志

Three-dimensionally controlled cell-assembly technique makes fabricating tissues and organs in vitro to be possible. However, for real tissues and organs with complex structure and various cells, fabricating tissues and organs in vitro need a technique that could assemble and locate multi cells and materials precisely in the space. Facing the needs of multi-cell assembly, we designed a mixer nozzle and the matching pulse switching circuit which based on the single-nozzle cell assembly system, and developed a multi-cell-assembly system. We also carried out some assembly experiments with this system using materials that were similar to the multi-component extracellular matrix materials. The results demonstrated that the system could assemble various cells and materials into three-dimensional inhomogeneous structures precisely.

Study on computer-aided deposition manufacturing of vascular tissue engineering scaffolds at low temperature / 生物医学工程学杂志

Since there is a clinical need for the tissue-engineered vascular graft (TEVG), fabricating the vascular scaffold individually appears to be necessary. In this work, we have developed the traditional tubular scaffold and branch vascular scaffold utilizing low-temperature deposition manufacturing (LDM) technology. Then different tubular scaffolds were fabricated by changing the processing parameters, and the morphological properties of the scaffolds were assessed. The scaffolds reproduced the structure of 3D vascular model accurately. Wall thickness of the scaffold increased with the increase of velocity ratio (V(L)/V(s)) and nozzle temperature, and both the micropore size and wall roughness were positively correlated with the nozzle temperature. However, the porosity was barely affected by the nozzle temperature. This approach, fabricating vascular scaffold with special structure and appearance features via LDM technology, is potential for the individual fabrication of vascular scaffold.