Swelling via Impedimetry Using Specifically Adhered Hydrogels on Co-Planar Microfabricated Electrodes

Lauren V. Whitney, Sara Abasi, John R. Aggas, Anthony Guiseppi-Elie
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Abstract

Responsive hydrogels adhered to microfabricated electrodes find applicability as chemical or biological sensors and in electro-stimulated drug delivery. A well-defined method of cleaning, surface modification, and surface functionalization of microlithographically-fabricated biochips composed of heterogeneous, abio surfaces (gold and glass) is presented for the reproducible adhesion of responsive hydrogels. The method uses cleaning approaches adapted from the semiconductor electronics industry and combines these with reactive organosilane chemistry to achieve the specific (covalent) attachment of UV cross-linked, poly(HEMA-co-PEGMA-co-HMMA)-based hydrogels. Specific attachment of hydrogels via acryloyl-poly(ethylene glycol)-3500 n-hydroxysuccinimide (APNHS)-functionalized surfaces and subsequent hydrogel hydration resulted in the strongest adhesive force as determined by centrifugal adhesion testing. Comparison with substrates functionalized via hydroxyl-poly(ethylene glycol)-3500 n-hydroxysuccinimide (PNHS) confirmed the superiority of adhesion involving covalent bonding (APNHS) (4.48 kPa) versus hydrogen bonding (PNHS) (1.29 kPa). Adhered, fully hydrated and dehydrated hydrogels are characterized by Electrochemical Impedance Spectroscopy (EIS) and their hydration kinetics determined using impedimetry at a rationalized frequency. Impedimetry confirmed that p(HEMA-co-PEGMA-co-HMMA) hydrogels have an equilibration time of ≈30 min, a diffusion-dependent rate coefficient k1 = 0.311 s−0.5 and relaxation-dependent coefficient k2 = −0.022 s−1. Hydrogel swelling may be studied by impedimetry to fashion biomedical devices for co-joined, real-time biosensing with electro-stimulated drug delivery.

Abstract Image

在共平面微加工电极上使用特定粘附的水凝胶通过阻抗测量法测量膨胀情况
粘附在微加工电极上的反应性水凝胶适用于化学或生物传感器以及电刺激给药。本文介绍了一种清洁、表面改性和表面功能化微光刻制造生物芯片的明确方法,该芯片由异质、非生物表面(金和玻璃)组成,可重复粘附反应性水凝胶。该方法采用了半导体电子行业的清洁方法,并将其与反应性有机硅烷化学相结合,实现了紫外线交联聚(HEMA-co-PEGMA-co-HMMA)水凝胶的特异性(共价)附着。通过丙烯酰-聚(乙二醇)-3500 n-羟基琥珀酰亚胺(APNHS)官能化的表面特异性附着水凝胶,随后水凝胶水合,经离心附着力测试,可获得最强的附着力。与通过羟基-聚(乙二醇)-3500 n-羟基琥珀酰亚胺(PNHS)功能化的基底相比,共价键(APNHS)(4.48 kPa)与氢键(PNHS)(1.29 kPa)的粘附力更胜一筹。通过电化学阻抗谱(EIS)对粘附的、完全水合的和脱水的水凝胶进行了表征,并使用阻抗仪以合理的频率测定了它们的水合动力学。阻抗测量法证实 p(HEMA-co-PEGMA-co-HMMA)水凝胶的平衡时间≈30 分钟,扩散依赖性速率系数 k1 = 0.311 s-0.5 和弛豫依赖性系数 k2 = -0.022 s-1。可以通过阻抗测量法研究水凝胶的溶胀,从而设计出生物医学设备,用于实时生物传感和电刺激给药。
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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