3D-printed tool for creating standardized burn wounds in ex vivo skin tissues

Q3 Medicine

Annals of 3D printed medicine Pub Date : 2024-06-22 DOI:10.1016/j.stlm.2024.100162

Mojtaba Javid , Fahimeh Tabatabaei

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引用次数: 0

Abstract

Introduction

The development of biomaterials and medical devices for burn wound treatment necessitates thorough investigation through in vitro/ex vivo models before transitioning to animal studies. Establishing a standardized and high-throughput burn wound model in ex vivo skin presents a considerable challenge. Our objective was to address this challenge by developing a practical and cost-effective 3D-printed burn wound tool capable of uniformly inducing burns in 12 skin samples simultaneously.

Material and methods

Utilizing Autodesk Inventor software, we designed a 3D model comprising a plate-base component (PBC) and a rod-base component (RBC). The design was exported as a Standard Triangulation Language (STL) file, processed through "Slicer" software to generate a G-code file tailored for 3D printing.

Results

The Rod-Base component underwent iterative design modifications to optimize weight, airflow, and material consumption, resulting in a final design featuring a unique star shape for enhanced airflow. Simultaneously, the Plate-Base component design evolved to enable easy and secure plate placement, demonstrating compatibility with 12-well plates. The average production time for the model was 14.5 h, with a production cost of approximately $20 (USD), covering printing material and steel rods.

Conclusion

In conclusion, this study provides valuable insights into the required equipment and software, empowering researchers to efficiently produce their accurate and cost-effective 3D-printed tool for controlled and reproducible burn wound creation in ex vivo viable skin tissues.

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用于在体外皮肤组织中创建标准化烧伤创面的 3D 打印工具

导言用于烧伤创面治疗的生物材料和医疗器械的开发需要通过体外/体内模型进行彻底研究，然后再过渡到动物实验。在体外皮肤中建立标准化、高通量的烧伤创面模型是一项巨大的挑战。我们的目标是通过开发一种实用且具有成本效益的三维打印烧伤工具来应对这一挑战，该工具能够同时在 12 个皮肤样本中均匀地诱导烧伤。设计以标准三角测量语言 (STL) 文件的形式导出，通过 "Slicer "软件进行处理，生成专为三维打印量身定制的 G 代码文件。结果杆基组件经过反复设计修改，优化了重量、气流和材料消耗，最终设计成独特的星形，增强了气流。与此同时，平板底座组件的设计也得到了改进，使平板放置更加方便、安全，并证明了与 12 孔板的兼容性。该模型的平均生产时间为 14.5 小时，生产成本约为 20 美元，其中包括打印材料和钢棒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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