Physically cross-linked scaffold composed of hydroxyapatite-chitosan-alginate-polyamide has potential to trigger bone regeneration in craniofacial defect

IF 1.7 4区工程技术 Q4 POLYMER SCIENCE

Journal of Polymer Engineering Pub Date : 2024-02-14 DOI:10.1515/polyeng-2022-0205

Md. Masud Rana, Md. Arifuzzaman, Naznin Akhtar, Md. Raziul Haque, Swapan Kumar Sarkar, Md. Nurunnobi, Md. Aliuzzaman Sarder, Sikder M. Asaduzzaman

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Abstract

Recently, the fabrication of a scaffold from biomaterials has been increased due to the lack of adequate natural bone for grafting. In this study, hydroxyapatite-chitosan-alginate-polyamide (HCAP) synthetic scaffold was fabricated using the thermally induced phase separation (TIPS) technique. The scaffold was cross-linked with either a chemical cross-linker (calcium chloride, 2-hydroxyethyl methacrylate (HEMA), or glutaraldehyde (GTA)) or a physical cross-linker (gamma irradiation (IR)) resulting in scaffolds HCAP-CaCl2, HCAP-HEMA, HCAP-GTA, and HCAP-IR, respectively. The cross-linked scaffolds were characterized based on physicochemical properties, cytotoxicity, and biocompatibility. HCAP-GTA showed the highest density and the lowest swelling ratio and biodegradation rate closely matching with those of the HCAP-IR. Porosity and density of the HCAP, HCAP-IR, and HCAP-GTA scaffolds were 92.14, 87.26, and 83.33 %, and 0.241, 0.307, and 0.335 g/cm3, respectively. The swelling ratio for the same scaffolds was 149, 110, and 108 % after 72 h of observation. Brine shrimp cytotoxicity and RBC biocompatibility assay confirmed the non-toxic nature of HCAP-IR and HCAP-GTA scaffolds. The HCAP-IR scaffold was tested for bone regeneration in the rabbit mandible defect model. Histological analysis revealed the regeneration of new bone and restoration of bone defect at the site of injury. These findings indicate that radiation induced physically cross-linked HCAP scaffold could be used as an alternative in bone defect replacement therapy.

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由羟基磷灰石-壳聚糖-精氨酸-聚酰胺组成的物理交联支架有望促进颅面缺损的骨再生

最近，由于缺乏足够的天然骨作为移植材料，用生物材料制作支架的做法越来越多。本研究采用热诱导相分离（TIPS）技术制作了羟基磷灰石-壳聚糖-精氨酸-聚酰胺（HCAP）合成支架。用化学交联剂（氯化钙、甲基丙烯酸羟乙酯（HEMA）或戊二醛（GTA））或物理交联剂（伽马辐照（IR））对支架进行交联，分别得到 HCAP-CaCl2、HCAP-HEMA、HCAP-GTA 和 HCAP-IR。根据理化性质、细胞毒性和生物相容性对交联支架进行了表征。HCAP-GTA 密度最高，膨胀率最低，生物降解率与 HCAP-IR 接近。HCAP、HCAP-IR和HCAP-GTA支架的孔隙率和密度分别为92.14%、87.26%和83.33%，以及0.241、0.307和0.335 g/cm3。观察 72 小时后，相同支架的膨胀率分别为 149%、110% 和 108%。盐水虾细胞毒性和红细胞生物相容性检测证实了 HCAP-IR 和 HCAP-GTA 支架的无毒性。在兔子下颌骨缺损模型中对 HCAP-IR 支架进行了骨再生测试。组织学分析表明，新骨再生并修复了损伤部位的骨缺损。这些研究结果表明，辐射诱导的物理交联 HCAP 支架可作为骨缺损替代疗法的一种选择。

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来源期刊

Journal of Polymer Engineering 工程技术-高分子科学

CiteScore

3.20

自引率

5.00%

发文量

审稿时长

2.5 months

期刊介绍： Journal of Polymer Engineering publishes reviews, original basic and applied research contributions as well as recent technological developments in polymer engineering. Polymer engineering is a strongly interdisciplinary field and papers published by the journal may span areas such as polymer physics, polymer processing and engineering of polymer-based materials and their applications. The editors and the publisher are committed to high quality standards and rapid handling of the peer review and publication processes.