Ultra-high frequency IC design for intelligent genetic analysis systems

2011 IEEE Topical Conference on Biomedical Wireless Technologies, Networks, and Sensing Systems Pub Date : 2011-03-07 DOI:10.1109/BIOWIRELESS.2011.5724353

M. Hella, A. Kempitiya, H. Mohamed, D. Borca-Tasciuc

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Abstract

This paper outlines the intelligence and portability requirements for future genetic analysis systems tailored to fast, low cost, and large scale population studies. Methods used in current research for DNA amplification and detection are discussed. The most significant shortcomings of current practises are their lack of the programmability required to generate different heating profiles to detect the correlation between different genetic components and specific diseases. In addition, none of the existing systems have the capability to quickly compare detected DNA with a bank of DNA signatures particular to a specific disease in a low cost, portable, and label-free process. Promising techniques relying on the advances in CMOS RF and sub-THz IC design are discussed wihin the context of programmable and parallel DNA amplification and detection platforms. The availability of such platforms can transform the field of genetic analysis, leading to personalized medicine and therapy.

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智能遗传分析系统的超高频集成电路设计

本文概述了未来基因分析系统的智能和便携性要求，以适应快速、低成本和大规模的种群研究。讨论了目前DNA扩增和检测的研究方法。目前做法的最大缺点是缺乏可编程性，无法产生不同的加热剖面，以检测不同遗传成分与特定疾病之间的相关性。此外，现有的系统都没有能力在低成本、便携和无标签的过程中将检测到的DNA与特定疾病的DNA特征库进行快速比较。在可编程和并行DNA扩增和检测平台的背景下，讨论了依赖于CMOS RF和亚太赫兹IC设计进步的有前途的技术。这些平台的可用性可以改变基因分析领域，导致个性化的医疗和治疗。

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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2011 IEEE Topical Conference on Biomedical Wireless Technologies, Networks, and Sensing Systems

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