Dermal ISF Collection Using a Si Microneedle Array

2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS) Pub Date : 2020-01-01 DOI:10.1109/MEMS46641.2020.9056394

Caleb A. Berry, Zachary R. Smith, S. Collins, Rosemary L. Smith

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引用次数: 3

Abstract

Microfabricated needle arrays for minimally invasive bioassay and drug delivery have been the subject of a great deal of excitement and research for nearly two decades. In particular, the application of microneedles to accessing and analyzing dermal interstitial fluid, in lieu of venous blood, could greatly facilitate point-of-care diagnosis and health monitoring in austere environments. However, there have been only a few successful demonstrations of in vivo collection of ISF from human skin using a microfabricated needle array. In this paper we present an empirically determined requisite feature of microfabricated hollow silicon needles that enable collection of ISF from human skin during in vivo testing. Success was only achieved by microneedles with this specific geometric feature, or shape. To inform microneedle design and fabrication, a silicon etch simulation program was developed to predict 3D shape evolution. The microfabrication process, a simulation example and in vivo test results are presented.

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利用硅微针阵列采集皮肤ISF

近二十年来，用于微创生物检测和药物输送的微制造针阵列一直是许多令人兴奋和研究的主题。特别是，应用微针来获取和分析皮肤间质液，代替静脉血，可以极大地促进在恶劣环境下的即时诊断和健康监测。然而，只有少数成功的演示使用微制造针阵列从人体皮肤中收集ISF。在本文中，我们提出了一个经验确定的微制造空心硅针的必要特征，该特征能够在体内测试期间从人体皮肤收集ISF。只有具有这种特定几何特征或形状的微针才能取得成功。为了指导微针的设计和制造，开发了一个硅蚀刻模拟程序来预测三维形状的演变。给出了微加工工艺、仿真实例和体内实验结果。

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2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS)

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