电纺丝PVDF膜包埋BaTiO3微粒子和纳米粒子生物复合材料的表征

Macromol Pub Date : 2022-11-17 DOI:10.3390/macromol2040034
S. Almeida, J. Silva, J. Borges, M. Lança
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引用次数: 0

摘要

骨组织损伤是一种常见的健康问题,其严重程度往往随着年龄和其他潜在条件的增加而增加。为了利用压电效应进行骨重建,可以使用压电材料填充患者的骨缺损。聚偏氟乙烯(PVDF)和钛酸钡(BaTiO3)分别是众所周知的聚合物和陶瓷生物材料,并且在室温下具有压电性。为了模拟细胞外基质,PVDF膜是通过静电纺丝在旋转鼓上产生的,以促进纤维的排列,微纳米尺寸的四边形BaTiO3颗粒被嵌入这些膜中,以试图增强压电响应,从而提高生物活性。在确定了制备纯PVDF膜的最佳沉积参数后,将相同的沉积参数用于嵌入膜,并对两者进行了表征,表明通过静电纺丝获得β相PVDF(压电系数最高的聚合物相)的方法是可行的,可以生产出直径一致且排列一致的纤维。钛酸钡的存在使膜具有生物活性,并导致纤维直径和表面电荷密度的减小。
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Characterization of a Biocomposite of Electrospun PVDF Membranes with Embedded BaTiO3 Micro- and Nanoparticles
Damage to bone tissue is a common health issue that tends to increase in severity with age and other underlying conditions. To take advantage of the piezoelectric effect on bone remodulation, piezoelectric materials can be used to fill patients bone defects. Polyvinylidene fluoride (PVDF) and barium titanate (BaTiO3) are both well-known polymeric and ceramic biomaterials, respectively, as well as piezoelectric at room temperature. To mimic the extracellular matrix, PVDF membranes were produced by electrospinning onto a rotating drum to promote the alignment of fibers and micro- and nano-sized tetragonal BaTiO3 particles were embedded into these membranes to try to enhance the piezoelectric response and, therefore, bioactivity. After defining the best deposition parameters to produce pure PVDF membranes, the same parameters were carried over for the embedded membranes and both were characterized, revealing that the proposed method for obtaining β-phase PVDF (the polymer phase with highest piezoelectric coefficient) through electrospinning is viable, producing fibers with coherent diameters and alignment. The presence of barium titanate conferred bioactivity to the membranes and caused a decrease in fibers’ diameter and in superficial charge density.
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