Future trends in diagnosis using laboratory-on-a-chip technologies

M. S. TALARY; J. P. H. BURT; R. PETHIG

doi:10.1017/S0031182099004126

Abstract

There has been an enormous growth in the development of biotechnological applications, where advances in the techniques of microelectronic fabrication and the technologies of miniaturization and integration in semiconductor industries are being applied to the production of Laboratory-on-a-Chip devices. The aim of this development is to create devices that will perform the same processes that are currently carried out in the laboratory in reduced timescales, at a lower cost, requiring less reagents, and with a greater resolution of detection and specificity. The expectations of this Laboratory-on-a-Chip revolution is that this technology will facilitate rapid advances in gene discovery, genetic mapping and gene expression with broader applications ranging from infectious diseases and cancer diagnostics to food quality and environmental testing. A review of the current state of development in this field reveals the scale of the ongoing revolution and serves to highlight the advances that can be perceived in the development of Laboratory-on-a-Chip technologies. Since miniaturization can be applied to such a wide range of laboratory processes, some of the sub-units that can be used as building blocks in these devices are described, with a brief description of some of the fabrication processes that can be used to create them.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Chiu, Daniel T 2001. A microfluidics platform for cell fusion. Current Opinion in Chemical Biology, Vol. 5, Issue. 5, p. 609.

JORDAN, BERTRAND 2002. Historical Background and Anticipated Developments. Annals of the New York Academy of Sciences, Vol. 975, Issue. 1, p. 24.

Cunningham, Carey O 2002. Molecular diagnosis of fish and shellfish diseases: present status and potential use in disease control. Aquaculture, Vol. 206, Issue. 1-2, p. 19.

Ng, Jocelyn H. and Ilag, Leodevico L. 2002. Biomedical applications of protein chips. Journal of Cellular and Molecular Medicine, Vol. 6, Issue. 3, p. 329.

Verpoorte, Elisabeth 2002. Microfluidic chips for clinical and forensic analysis. ELECTROPHORESIS, Vol. 23, Issue. 5, p. 677.

Sancho, Miguel Martı́nez, Genoveva and Martı́n, Carla 2003. Accurate dielectric modelling of shelled particles and cells. Journal of Electrostatics, Vol. 57, Issue. 2, p. 143.

Hoy, Marjorie A. 2003. Insect Molecular Genetics. p. 178.

Ng, Jocelyn H and Ilag, Leodevico L 2003. Vol. 9, Issue. , p. 1.

CrossRef

Cen, Esther G. Dalton, Colin Li, Youlan Adamia, Sophia Pilarski, Linda M. and Kaler, Karan V.I.S. 2004. A combined dielectrophoresis, traveling wave dielectrophoresis and electrorotation microchip for the manipulation and characterization of human malignant cells. Journal of Microbiological Methods, Vol. 58, Issue. 3, p. 387.

Dalton, C. Goater, A.D. Burt, J.P.H. and Smith, H.V. 2004. Analysis of parasites by electrorotation. Journal of Applied Microbiology, Vol. 96, Issue. 1, p. 24.

Ewis, Ashraf A Zhelev, Zhivko Bakalova, Rumiana Fukuoka, Satoshi Shinohara, Yasuo Ishikawa, Mitsuru and Baba, Yoshinobu 2005. A history of microarrays in biomedicine. Expert Review of Molecular Diagnostics, Vol. 5, Issue. 3, p. 315.

Hayden, Chris 2006. MEMS/NEMS. p. 880.

Lin, J. T. Y. and Yeow, J. T. W. 2007. Enhancing dielectrophoresis effect through novel electrode geometry. Biomedical Microdevices, Vol. 9, Issue. 6, p. 823.

Patel, Pareshkumar and Markx, Gerard H. 2008. Dielectric measurement of cell death. Enzyme and Microbial Technology, Vol. 43, Issue. 7, p. 463.

Fernández Morales, Flavio Humberto Duarte, Julio Enrique and Samitier Martí, Joseph 2008. Non-uniform electric field-induced yeast cell electrokinetic behavior. Ingeniería e Investigación, Vol. 28, Issue. 3, p. 116.

Kanyal, Supriya Jensen, David Dadson, Andrew Vanfleet, Richard Davis, Robert and Linford, Matthew 2014. Atomic layer deposition of aluminum-free silica onto patterned carbon nanotube forests in the preparation of microfabricated thin-layer chromatography plates. Journal of Planar Chromatography – Modern TLC, Vol. 27, Issue. 3, p. 151.

Jivani, Rishad R. Lakhtaria, Gaurang J. Patadiya, Dhaval D. Patel, Laxman D. Jivani, Nurrudin P. and Jhala, Bhagyesh P. 2016. RETRACTED: Biomedical microelectromechanical systems (BioMEMS): Revolution in drug delivery and analytical techniques. Saudi Pharmaceutical Journal, Vol. 24, Issue. 1, p. 1.

Mendes, Flávia Maria Lins Castor, Kamaiaji Monteiro, Roseli Mota, Fabio Batista and Rocha, Leonardo Fernandes Moutinho 2019. Mapping the lab-on-a-chip patent landscape through bibliometric techniques. World Patent Information, Vol. 58, Issue. , p. 101904.

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Future trends in diagnosis using laboratory-on-a-chip technologies

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