Fabricating high-performance biomedical PLLA/PVDF blend micro bone screws through in situ structuring of oriented PVDF submicron fibers in microinjection molding

Poly(l-lactide) (PLLA) is regarded as a polymer with excellent biocompatibility, but its inherent brittleness property greatly restricts its application in the biomedical engineering field. Blending PLLA with other polymers is one of the sufficiently viable methods of property improvement. In this p...

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Bibliographic Details
Published in:Composites. Part B, Engineering Engineering, 2024-07, Vol.281, p.111567, Article 111567
Main Authors: Tan, Jiayu, Li, Tao, Xie, Yeping, Chen, Meiqiong, Li, Li, Zhang, Chuhong, Chen, Yinghong, Pang, Long, Zhang, Chunsen, Li, Yinghao, Tang, Xin
Format: Article
Language:English
Subjects:
In situ fibrillation
Mechanical properties
Microinjection molding
Piezoelectricity
Polylactic acid
Polyvinylidene fluoride
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Summary:Poly(l-lactide) (PLLA) is regarded as a polymer with excellent biocompatibility, but its inherent brittleness property greatly restricts its application in the biomedical engineering field. Blending PLLA with other polymers is one of the sufficiently viable methods of property improvement. In this paper, the Poly(l-lactide) (PLLA)/Polyvinylidene fluoride (PVDF) blend was first prepared by melt-compounding, and then microinjection molded into the blend micro bone screw with high strength and toughness. The experimental results show that the PVDF dispersed phases could in situ form the highly oriented fibers with shish-kebab structures under the effect of strong shear stress field of microinjection molding along flow direction. These parallelly aligning PVDF fibers could simultaneously realize the significant enhancement in both toughness and strength of the micro bone screw. Specifically, in the bending test the blend micro bone screw with oriented PVDF fibers can withstand the compression displacement of nearly 2 mm, while the neat PLLA one would break within only 0.5 mm displacement. In addition, a bending recovery phenomenon was observed in the load-displacement curve of the blend, demonstrating the mechanical transition from brittle fracture to ductile fracture. Moreover, with addition of 30 % PVDF, the elongation at break increases from 7.8 % to 57.8 %, while the tensile strength increases from 60.9 MPa to 74.3 MPa. The PLLA/PVDF micro screws possess better toughness and excellent biocompatibility compared to pure PLLA products. They also exhibit great potential for stimulating the proliferation of cells through piezoelectric output, opening up new possibilities for the development of next-generation fracture fixation materials. Combing melt-compounding and microinjection molding strategy achieves the in situ formation of highly oriented PVDF dispersed phase fibers with shish-kebab structure in PLLA/PVDF blend, resulting in high performance of the fabricated biomedical micro bone screw for bone repair. [Display omitted] •Highly oriented PVDF fibers with shish-kebab structures were in situ formed in the PLLA matrix during microinjection molding.•The PLLA/PVDF microparts exhibit the synchronously improved strength and toughness, as well as piezoelectric output property.•Microinjection molding is used to manufacture the PLLA/PVDF blend micro bone screws with exceptionally high toughness.•The biological experiments have demonstrated the excellent biocompat
ISSN:1359-8368
1879-1069
DOI:10.1016/j.compositesb.2024.111567