The compressive strength and static biodegradation rate of chitosan-gelatin limestone-based carbonate hydroxyapatite composite scaffold

Dental journal Pub Date : 2023-06-09 DOI:10.20473/j.djmkg.v56.i3.p160-165

Devi Rianti, Alqomariyah Eka Purnamasari, Rifayinqa Ruyani Putri, Noor Zain Salsabilla, Faradillah, E. Munadziroh, Titien Hary Agustantina, Asti Meizarini, A. Yuliati, A. Syahrom

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Abstract

Background: One of the main components in tissue engineering is the scaffold, which may serve as a medium to support cell and tissue growth. Scaffolds must have good compressive strength and controlled biodegradability to show biological activities while treating bone defects. This study uses Chitosan-gelatin (C–G) with good flexibility and elasticity and high-strength carbonate hydroxyapatite (CHA), which may be the ideal scaffold for tissue engineering. Purpose: To analyze the compressive strength and static biodegradation rate within various ratios of C–G and CHA (C–G:CHA) scaffold as a requirement for bone tissue engineering. Methods: The scaffold is synthesized from C–G:CHA with three ratio variations, which are 40:60, 30:70, and 20:80 (weight for weight [w/w]), made with a freeze-drying method. The compressive strengths are then tested. The biodegradation rate is tested by soaking the scaffold in simulated body fluid for 1, 3, 7, 14, and 21 days. Data are analyzed with a one-way ANOVA parametric test. Results: The compressive strength of each ratio of C–G:CHA scaffold 40:60 (w/w), 30:70 (w/w), and 20:80 (w/w), consecutively, are 4.2 Megapascals (MPa), 3.3 MPa, 2.2 MPa, and there are no significant differences with the p= 0.069 (p>0.05). The static biodegradation percentage after 21 days on each ratio variation of C–G:CHA scaffold 40:60 (w/w), 30:70 (w/w), and 20:80 (w/w) is 25.98%, 24.67%, and 20.64%. One-way ANOVA Welch test shows the result of the p-value as p<0.05. Conclusion: The compressive strength and static biodegradation of the C–G:CHA scaffold with ratio variations of 40:60 (w/w), 30:70 (w/w), and 20:80(w/w) fulfilled the requirements as a scaffold for bone tissue engineering.

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壳聚糖-明胶-石灰石-碳酸盐-羟基磷灰石复合支架的抗压强度和静态生物降解率

背景:组织工程的主要组成部分之一是支架，它可以作为支持细胞和组织生长的介质。支架必须具有良好的抗压强度和可控的生物降解性，才能在治疗骨缺损的同时显示出生物活性。本研究选用具有良好柔韧性和弹性的壳聚糖明胶(C-G)和高强度的碳酸盐羟基磷灰石(CHA)作为组织工程理想的支架材料。目的:分析骨组织工程所需的C-G与CHA (C-G:CHA)支架在不同配比下的抗压强度和静态生物降解率。方法:以C-G:CHA为原料，以40:60、30:70、20:80(重量对重量[w/w])三种比例变化，采用冷冻干燥法制备支架。然后测试抗压强度。通过将支架浸泡在模拟体液中1、3、7、14和21天来测试生物降解率。数据分析采用单因素方差分析参数检验。结果:C-G:CHA支架各配比40:60 (w/w)、30:70 (w/w)、20:80 (w/w)的抗压强度分别为4.2兆帕(MPa)、3.3兆帕、2.2兆帕，p= 0.069 (p < 0.05)差异无统计学意义。40:60 (w/w)、30:70 (w/w)和20:80 (w/w)的C-G:CHA支架各配比变化后21 d的静态生物降解率分别为25.98%、24.67%和20.64%。单因素方差分析Welch检验显示p值为p<0.05。结论:C-G:CHA支架的抗压强度和静态生物降解性能分别为40:60 (w/w)、30:70 (w/w)和20:80(w/w)，满足骨组织工程支架的要求。

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Dental journal

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