Polycaprolactone strengthening gelatin/nano-hydroxyapatite composite biomaterial inks for potential application in extrusion-based 3D printing bone scaffolds

Chenxin Wang, Mao Yang, Li Chen, Yijing Stehle, Mingyue Lin, Rui Zhang, Huanshuo Zhang, Jiehui Yang, Min Huang, Yubao Li, Qin Zou
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Abstract

Extrusion-based three-dimensional (3D) printing of gelatin (Gel) is crucial for fabricating bone tissue engineering scaffolds via additive manufacturing. However, the thermal instability of Gel remains a persistent challenge, as it tends to collapse at mild temperatures. Current approaches often involve simply mixing Gel particles with various materials, resulting in biomaterial inks that lack uniformity and have inconsistent degradation characteristics. In this study, acetic acid was used to dissolve Gel and polycaprolactone (PCL) separately, producing homogeneous Gel/PCL dispersions with optimal pre-treatment performance. These dispersions were then combined and hybridized with nano-hydroxyapatite (n-HA) to create a composite printing ink. By evaluating the printability of the ink, the optimal conditions were identified: a n-HA concentration of 50% (w/w), a printing temperature of 10–15 ℃, a printing pressure of 2.5 bar, and a printing speed of 7 mm/s. The resulting biomaterial inks, with a composition of 25% Gel, 25% PCL, and 50% n-HA, demonstrated excellent printability and stability, along with significantly enhanced mechanical properties. As a result, 3D scaffolds with high printability and shape fidelity can be printed at room temperature, followed by deep freezing at -80 ℃ and cross-linking with vanillin. The Gel-based composite scaffolds demonstrated excellent biocompatibility, cell adhesion, cell viability and nano-hydroxyapatite absorption in vitro. Additionally, in vivo experiments revealed that the bioactive scaffold biodegraded during implantation and significantly promoted bone regeneration at the defect site. This provides a promising strategy for treating bone defects in clinical setting. In conclusion, the Gel/PCL/n-HA biomaterial inks presented here offer an innovative solution for extrusion bioprinting in the field of bone tissue engineering.

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聚己内酯强化明胶/纳米羟基磷灰石复合生物材料墨水在基于挤压的 3D 打印骨支架中的潜在应用
基于挤压的明胶(Gel)三维(3D)打印对于通过增材制造制造骨组织工程支架至关重要。然而,明胶的热不稳定性仍然是一个长期存在的难题,因为它往往会在温和的温度下坍塌。目前的方法通常是将凝胶颗粒与各种材料简单混合,结果制成的生物材料墨水缺乏均匀性,降解特性也不一致。在这项研究中,使用醋酸分别溶解凝胶和聚己内酯(PCL),生产出具有最佳预处理性能的均匀凝胶/聚己内酯分散体。然后将这些分散体与纳米羟基磷灰石(n-HA)混合并杂化,制成复合印刷油墨。通过评估油墨的可印刷性,确定了最佳条件:n-HA 浓度为 50%(重量比),印刷温度为 10-15 ℃,印刷压力为 2.5 巴,印刷速度为 7 毫米/秒。最终制成的生物材料墨水(成分为 25% 凝胶、25% PCL 和 50% n-HA)具有出色的打印性能和稳定性,同时机械性能也显著增强。因此,可在室温下打印出具有高打印性和形状保真度的三维支架,然后在-80 ℃下进行深冷,并用香兰素进行交联。凝胶基复合材料支架在体外表现出良好的生物相容性、细胞粘附性、细胞活力和纳米羟基磷灰石吸收性。此外,体内实验表明,生物活性支架在植入过程中会发生生物降解,并能显著促进缺损部位的骨再生。这为临床治疗骨缺损提供了一种前景广阔的策略。总之,本文介绍的凝胶/ PCL/n-HA 生物材料墨水为骨组织工程领域的挤压生物打印提供了一种创新的解决方案。
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来源期刊
Journal of Leather Science and Engineering
Journal of Leather Science and Engineering 工程技术-材料科学:综合
CiteScore
12.80
自引率
0.00%
发文量
29
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