用生物指示剂评估40°C以下等离子体工艺的灭菌效果

Q4 Computer Science

International Journal of Automation and Smart Technology Pub Date : 2018-11-30 DOI:10.5875/AUSMT.V8I4.1831

C. Huang, Chao-Tang Chuang, C. Weng, Chi‐Hung Liu, Yizheng Li, Li-Cheng Pana, Chih-Kuang Wang

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引用次数: 0

摘要

可生物降解的生物聚合物已广泛应用于组织工程的生物材料中。杀菌是一种使产品免受细菌、酵母和病毒等微生物污染的过程。在对可生物降解支架进行灭菌时，所选择的灭菌技术必须保持支架的结构和生物化学特性，以确保支架在灭菌后能够达到预期目的。此外，为了通过3D打印生物材料开发定制、快速和准确的医疗设备，通过低温过氧化氢（H2O2）气体等离子体（HPGP）对此类设备进行灭菌，不仅将为快速制造定制医疗设备提供新的能力，还将为生产无菌最终用途部件提供新的功能。该设备使用温度低于40°C的等离子体，通过紫外线照射过程激活H2O2，用生物指示剂评估灭菌效果。结果表明，HPGP的几个参数组合可以在40°C以下的温度下实现灭菌。因此，与该HPGP装置相关的参数有可能提供适用于通过3D打印制造的生物聚合物装置的未来开发的灭菌过程。本作品根据知识共享署名非商业NoDerivatives 4.0国际许可证获得许可。

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Sterilization Efficacy of a Below 40°C Plasma Processes Assessed by a Biological Indicator

Biodegradable biopolymers have been widely used in biomaterials for tissue engineering. Sterilization is a process by which a product can be made free of contamination from microorganisms such as bacteria, yeasts, and viruses. When sterilizing biodegradable scaffolds, the sterilization technique chosen must maintain the structural and biochemical properties of the scaffolds to ensure that the scaffolds can fulfill their intended purposes post-sterilization. In addition, in response to the development of customized, rapid and accurate medical devices via 3D printed biomaterials, sterilization of such devices by low-temperature hydrogen peroxide (H2O2) gas plasma (HPGP) will provide new capabilities not only for rapidly manufacturing customized medical devices but also for producing sterile end-use parts. This device uses a below 40°C temperature plasma with H2O2 activated by ultraviolet light irradiation processes to evaluate the sterilization efficacy with a biological indicator. The results demonstrated several parameter combinations for HPGP that can achieve sterilization at temperatures below 40°C. Therefore, the parameters associated with this HPGP device have the potential to provide a sterilization process applicable for future development of biopolymer devices manufactured by 3D printing. This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License .

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来源期刊

International Journal of Automation and Smart Technology Engineering-Electrical and Electronic Engineering

CiteScore

0.70

自引率

0.00%

发文量

审稿时长

16 weeks

期刊介绍： International Journal of Automation and Smart Technology (AUSMT) is a peer-reviewed, open-access journal devoted to publishing research papers in the fields of automation and smart technology. Currently, the journal is abstracted in Scopus, INSPEC and DOAJ (Directory of Open Access Journals). The research areas of the journal include but are not limited to the fields of mechatronics, automation, ambient Intelligence, sensor networks, human-computer interfaces, and robotics. These technologies should be developed with the major purpose to increase the quality of life as well as to work towards environmental, economic and social sustainability for future generations. AUSMT endeavors to provide a worldwide forum for the dynamic exchange of ideas and findings from research of different disciplines from around the world. Also, AUSMT actively seeks to encourage interaction and cooperation between academia and industry along the fields of automation and smart technology. For the aforementioned purposes, AUSMT maps out 5 areas of interests. Each of them represents a pillar for better future life: - Intelligent Automation Technology. - Ambient Intelligence, Context Awareness, and Sensor Networks. - Human-Computer Interface. - Optomechatronic Modules and Systems. - Robotics, Intelligent Devices and Systems.