PLA/PCL/HA可生物降解骨关节抗菌性能的体外研究与评价

Journal of Clinical Research in Paramedical Sciences Pub Date : 2022-06-20 DOI:10.5812/jcrps-124080

Farnaz Dehghani Firoozabadi, A. Ramazani Saadatabadi, Azadeh Asefnejad

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引用次数: 2

摘要

背景:由于使用永久植入物的历史和聚合物适应生理环境(如身体环境)的能力，需要设计一种具有新配方的聚合物植入物用于骨科应用。方法:采用溶剂铸造法制备聚合物接头。通过弯曲试验研究了试样在模拟体液中浸泡前后的力学性能。利用场发射扫描电镜(FESEM)观察了纳米复合材料的形貌、生物活性和降解过程。通过毒性试验评价纳米复合材料的毒性。通过测定抑菌带和光度浓度来考察样品的抑菌性能。通过生物降解性试验验证了聚合物接头的生物降解性。结果:随着纳米粒子的加入，纳米结构的力学性能有所提高。此外，氧化物和石墨烯纳米颗粒的存在影响了复合纳米结构的抗菌性能。浸泡在SBF溶液中表明纳米结构具有生物降解性和生物活性。研究结果表明，最佳的PLA-PCL-HA-1% ZNO-1% GR纳米复合材料的杨氏模量接近海绵骨，减少了应力屏蔽现象。PLA-PCL-HA纳米复合材料的弯曲杨模量为2139.037±381.312 MPa。氧化锌和石墨烯纳米颗粒的存在使杨氏模量增加到4363.636±127.498 MPa。最佳样品对革兰氏阳性和革兰氏阴性细菌的两种菌株具有必要的致病性，并且由于其生物活性，是海绵骨组织中使用的合适选择。在本研究中，与最佳基质相比，聚合物基质附近成纤维细胞的存活率在72小时后从22.14±0.623增加到82.96±1.101%。结论:与聚合物基质相比，细胞活力的提高表明最佳基质毒性的降低。

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In Vitro Studies and Evaluation of Antibacterial Properties of Biodegradable Bone Joints Based on PLA/PCL/HA

Background: Due to the history of using permanent implants and the ability of adaptations of polymers to physiological environments such as the body environment, the need to design a polymer implant with a new formulation for orthopedic applications was felt. Methods: Polymer joints in this study were made by solvent casting method. The mechanical properties of the samples were investigated by bending tests, before and after immersion in simulated body fluid (SBF). Morphology of nanocomposites, bioactivity of samples and initiation of degradation process were performed by field emission scanning electron microscope (FESEM). Toxicity test was performed to evaluate the toxicity of nanocomposites. The antibacterial properties of the samples were investigated by examining the zone of inhibition and measuring the photometric concentration. Biodegradability test was performed to prove the biodegradability of polymer joints. Results: It was found that the mechanical properties of nanostructures increased with the addition of nanoparticles. Also, the presence of oxide and graphene nanoparticles affected the antibacterial properties of the composite nanostructure. Immersion in SBF solution showed that the nanostructures were biodegradable and bioactive. The results of this study indicate that the optimal nanocomposite PLA-PCL-HA-1% ZNO-1% GR has a Young’s modulus close to spongy bone and reduces the stress shielding phenomenon. The flexural Yang modulus of the PLA-PCL-HA nanocomposite was 2139.037 ± 381.312 MPa. The presence of zinc oxide and graphene nanoparticles increased the Young’s modulus to 4363.636 ± 127.498 MPa. The optimal sample has the necessary lethality against two strains of gram-positive and gram-negative bacteria and due to its bioactivity is a suitable option for use in spongy bone tissue. In this study, the viability of fibroblast cells in the vicinity of the polymer matrix versus the optimal matrix increased from 22.14 ± 0.623 to 82.96 ± 1.101% after 72 hours. Conclusions: Improving cell viability indicates a reduction in the optimal matrix toxicity compared to the polymer matrix.

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Journal of Clinical Research in Paramedical Sciences

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