High-level synthesis for micro-electrode-dot-array digital microfluidic biochips

2016 53nd ACM/EDAC/IEEE Design Automation Conference (DAC) Pub Date : 2016-06-05 DOI:10.1145/2897937.2898028

Zipeng Li, Kelvin Yi-Tse Lai, Po-Hsien Yu, Tsung-Yi Ho, K. Chakrabarty, Chen-Yi Lee

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引用次数: 53

Abstract

A digital microfluidic biochip (DMFB) is an attractive technology platform for automating laboratory procedures in biochemistry. However, today's DMFBs suffer from several limitations: (i) constraints on droplet size and the inability to vary droplet volume in a fine-grained manner; (ii) the lack of integrated sensors for real-time detection; (iii) the need for special fabrication processes and reliability/yield concerns. To overcome the above problems, DMFBs based on a micro-electrode-dot-array (MEDA) architecture have recently been demonstrated. However, due to the inherent differences between today's DMFBs and MEDA, existing synthesis solutions cannot be utilized for MEDA-based biochips. We present the first biochip synthesis approach that can be used for MEDA. The proposed synthesis method targets operation scheduling, module placement, routing of droplets of various sizes, and diagonal movement of droplets in a two-dimensional array. Simulation results using benchmarks and experimental results using a fabricated MEDA biochip demonstrate the effectiveness of the proposed co-optimization technique.

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微电极点阵列数字微流控生物芯片的高水平合成

数字微流控生物芯片(DMFB)是生物化学实验室自动化的一个有吸引力的技术平台。然而，今天的dmfb有几个局限性:(1)液滴大小的限制和无法以细粒度的方式改变液滴体积;(ii)缺乏用于实时检测的集成传感器;(iii)需要特殊的制造工艺和可靠性/良率问题。为了克服上述问题，基于微电极点阵列(MEDA)结构的dmfb最近得到了证明。然而，由于今天的dmfb和MEDA之间的内在差异，现有的合成方案不能用于基于MEDA的生物芯片。我们提出了第一个可用于MEDA的生物芯片合成方法。所提出的综合方法以操作调度、模块放置、不同尺寸液滴的路由以及液滴在二维阵列中的对角移动为目标。基于基准的仿真结果和基于自制MEDA生物芯片的实验结果证明了所提出的协同优化技术的有效性。

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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2016 53nd ACM/EDAC/IEEE Design Automation Conference (DAC)

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