Novel patient-specific gingival soft-tissue expander development for large bone defects using silicone 3D-printing technology

IF 6.8 3区医学 Q1 ENGINEERING, BIOMEDICAL

International Journal of Bioprinting Pub Date : 2024-05-10 DOI:10.36922/ijb.2918

Tzu-Huan Huang, Shao-Fu Huang, Lu-Yi Yu, Chun-Liang Lo, Yu-Ping Chang, Chun-Li Lin

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Abstract

The current hydrogel self-inflating expander is limited by its volume and linear expansion rate, making it unsuitable for correcting patient-specific large mandibular bone defects in soft-tissue surgeries. This study devised a novel approach for crafting patient-specific gingival tissue expanders for large mandibular bone defects by employing silicone 3D-printing technology. The biocompatible and swellable polymer tablet was compressed and placed into a 3D-printed silicone membrane to evaluate its expansion capability. Two patient-specific large left and right mandibular bone defects with complex geometries were selected to generate defect expander models in a computer-aided design (CAD) software. The swellable tablets were enveloped in the 3D-printed silicone membranes to form soft-tissue expanders, which were then immersed in phosphate-buffered saline (PBS) for 6 weeks to observe their expansion. Results demonstrated that a slot-shaped silicone soft-tissue tablet attained an expansion volume of 1960 mm³. A fourth-degree polynomial fitting curve illustrated slower expansion rates in the initial 2 weeks and achieved complete expansion in about 6 weeks. Patient-specific silicone expander testing indicated less than 2% error in the average expanded volumes of compared to CAD models. The cross-sectional profile of the soft-tissue expanders closely resembled the CAD model. This study demonstrated that biocompatible polymer could be utilized as swellable tablet material and enveloped within a 3D-printed silicone membrane to generate a novel soft-tissue expander that adhered to clinical standards. Additionally, the study validated the feasibility of expanding patient-specific silicone expanders within 6 weeks for repairing large left and right mandibular bone defects.

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利用硅胶三维打印技术为大面积骨缺损开发新型患者特制牙龈软组织扩张器

目前的水凝胶自充气扩张器受限于其体积和线性扩张率，不适合在软组织手术中矫正患者特异性大面积下颌骨缺损。本研究采用硅胶三维打印技术，设计了一种新方法，用于制作患者特异性牙龈组织扩张器，以治疗大面积下颌骨缺损。将具有生物相容性和可膨胀性的聚合物片剂压缩并放入 3D 打印的硅胶膜中，以评估其膨胀能力。研究人员选择了两个具有复杂几何形状的患者特异性左右下颌骨大缺损，在计算机辅助设计（CAD）软件中生成缺损扩张器模型。将可膨胀药片包裹在 3D 打印的硅胶膜中，形成软组织扩张器，然后将其浸泡在磷酸盐缓冲盐水（PBS）中 6 周，观察其扩张情况。结果表明，槽形硅胶软组织片的膨胀体积达到了 1960 立方毫米。四度多项式拟合曲线显示，最初两周的膨胀速度较慢，大约 6 周后膨胀完全。针对患者的硅胶扩张器测试表明，与 CAD 模型相比，平均扩张体积误差小于 2%。软组织扩张器的横截面轮廓与 CAD 模型非常相似。这项研究表明，生物相容性聚合物可用作膨胀片剂材料，并包裹在三维打印的硅胶膜中，生成符合临床标准的新型软组织扩张器。此外，该研究还验证了在 6 周内将患者特制的硅胶扩张器扩张用于修复左右下颌骨大面积缺损的可行性。

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来源期刊

International Journal of Bioprinting Multiple-

CiteScore

6.90

自引率

4.80%

发文量

期刊介绍： The International Journal of Bioprinting is a globally recognized publication that focuses on the advancements, scientific discoveries, and practical implementations of Bioprinting. Bioprinting, in simple terms, involves the utilization of 3D printing technology and materials that contain living cells or biological components to fabricate tissues or other biotechnological products. Our journal encompasses interdisciplinary research that spans across technology, science, and clinical applications within the expansive realm of Bioprinting.