动物疫苗连续分体式无针注射系统的设计与分析。

Q3 Medicine
Open Biomedical Engineering Journal Pub Date : 2017-06-30 eCollection Date: 2017-01-01 DOI:10.2174/1874120701711010059
Kai Chen, Min Pan, Tingting Liu
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引用次数: 5

摘要

背景:液体无针注射装置(NFIDs)采用高速液体射流通过透皮注射输送药物和疫苗。用于动物疫苗接种的NFIDs比用于人类的NFIDs更复杂,因为它们的电源更大、更灵活,并且具有快速、重复和连续注射的特点。方法:设计用于动物疫苗注射的弹簧动力NFID。为方便起见,该设备分为电源和手持式注射器。考虑弹性变形引起的压力损失和应变能损失,提出了计算注射压力的数学模型。建立了实验装置,对计算结果进行了验证。结果与结论:在相同的系统条件下,动态喷射压力的计算结果与实验结果吻合。研究发现,劈裂式NFID的可弯曲管对注射压力分布有显著影响。初始峰值压力小于无弯曲管NFID的初始峰值压力,且峰值压力存在时间滞后。该数学模型首次揭示了劈裂式NFID喷射压力与系统变量之间的关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Design and Analysis of a Continuous Split Typed Needle-Free Injection System for Animal Vaccination.

Design and Analysis of a Continuous Split Typed Needle-Free Injection System for Animal Vaccination.

Design and Analysis of a Continuous Split Typed Needle-Free Injection System for Animal Vaccination.

Design and Analysis of a Continuous Split Typed Needle-Free Injection System for Animal Vaccination.

Background: Liquid needle-free injection devices (NFIDs) employ a high-velocity liquid jet to deliver drugs and vaccine through transdermal injection. NFIDs for animal vaccination are more complicated than those used for human beings for their much larger and more flexible power sources, as well as rapid, repetitive and continuous injection features.

Method: In the paper, spring-powered NFID is designed for animal vaccine injection. For convenience, the device is a split into a power source and handheld injector. A mathematical model is proposed to calculate the injection pressure, taking into the account pressure loss and the strain energy loss in the bendable tube due to elastic deformation. An experimental apparatus was build to verify the calculation results.

Results and conclusion: Under the same system conditions, the calculation results of the dynamic injection pressure match the experimental results. It is found that the bendable tube of the split typed NFID has significant impact on the profile of the injection pressure. The initial peak pressure is less than the initial peak pressure of NFID without bendable tube, and there is occurrence time lag of the peak pressure. The mathematical model is the first attempt to reveal the relationship between the injection pressure and the system variables of split typed NFID.

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来源期刊
Open Biomedical Engineering Journal
Open Biomedical Engineering Journal Medicine-Medicine (miscellaneous)
CiteScore
1.60
自引率
0.00%
发文量
4
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