Cell, biomaterial prepared cells scaffold and formation of tissues and organs are three main factors for the tissue engineering.
细胞、生物材料制备的细胞支架,以及组织和器官的构建是组织工程的三大要素。
Porous magnesium has obvious advantages as bone tissue engineering biomaterial.
多孔镁作为骨组织工程材料具有明显的优势。
Summarized four kinds of artificial implants surface design methods based on the related theories of biomaterial surface engineering.
以生物材料表面工程的相关理论为基础,总结出人工植入体表面设计的四种基本思路。
This novel biomaterial shows good stability, and is a scaffold for attachment, growth and differentiation of cells. It is a prospective biomaterial for tissue repair and tissue engineering.
这种膜具有很好的稳定性,能使细胞在其上附着、生长和分化,从而为组织修复、组织工程提供了一个极有前景的生物材料。
The traditional tissue-engineering paradigm combines isolated cells with appropriate bioactive agents in a biomaterial scaffold.
传统的组织工程的模式是使孤立的细胞在生物材料支架中与适当的生物活性因子相结合。
Conclusions NHAC has good biocompatibility and can be used as ideal biomaterial in bone tissue engineering.
结论纳米组织工程骨有良好的生物相容性,可作为骨组织工程理想的载体材料。
Conclusions: NHAC has good biocompatibility and can be used as ideal biomaterial in bone tissue engineering.
结论:纳米组织工程骨有良好的生物相容性,可以作为骨组织工程理想的载体材料。
Conclusions: NHAC has good biocompatibility and can be used as ideal biomaterial in bone tissue engineering.
结论:纳米组织工程骨有良好的生物相容性,可以作为骨组织工程理想的载体材料。
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