Literature DB >> 16518374

Lab-on-a-chip: microfluidics in drug discovery.

Petra S Dittrich1, Andreas Manz.   

Abstract

Miniaturization can expand the capability of existing bioassays, separation technologies and chemical synthesis techniques. Although a reduction in size to the micrometre scale will usually not change the nature of molecular reactions, laws of scale for surface per volume, molecular diffusion and heat transport enable dramatic increases in throughput. Besides the many microwell-plate- or bead-based methods, microfluidic chips have been widely used to provide small volumes and fluid connections and could eventually outperform conventionally used robotic fluid handling. Moreover, completely novel applications without a macroscopic equivalent have recently been developed. This article reviews current and future applications of microfluidics and highlights the potential of 'lab-on-a-chip' technology for drug discovery.

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Year:  2006        PMID: 16518374     DOI: 10.1038/nrd1985

Source DB:  PubMed          Journal:  Nat Rev Drug Discov        ISSN: 1474-1776            Impact factor:   84.694


  232 in total

1.  Complex three-dimensional high aspect ratio microfluidic network manufactured in combined PerMX dry-resist and SU-8 technology.

Authors:  Robert Ch Meier; Vlad Badilita; Jens Brunne; Ulrike Wallrabe; Jan G Korvink
Journal:  Biomicrofluidics       Date:  2011-08-05       Impact factor: 2.800

2.  Microfluidic droplet encapsulation of highly motile single zoospores for phenotypic screening of an antioomycete chemical.

Authors:  Haifeng Yang; Xuan Qiao; Madan K Bhattacharyya; Liang Dong
Journal:  Biomicrofluidics       Date:  2011-10-13       Impact factor: 2.800

3.  Endothelial Cell Vascular Smooth Muscle Cell Co-Culture Assay For High Throughput Screening Assays For Discovery of Anti-Angiogenesis Agents and Other Therapeutic Molecules.

Authors:  George A Truskey
Journal:  Int J High Throughput Screen       Date:  2010-10-01

4.  Cell analysis using a multiple internal reflection photonic lab-on-a-chip.

Authors:  Jordi Vila-Planas; Elisabet Fernández-Rosas; Bergoi Ibarlucea; Stefanie Demming; Carme Nogués; Jose A Plaza; Carlos Domínguez; Stephanus Büttgenbach; Andreu Llobera
Journal:  Nat Protoc       Date:  2011-09-29       Impact factor: 13.491

5.  A "place n play" modular pump for portable microfluidic applications.

Authors:  Gang Li; Yahui Luo; Qiang Chen; Lingying Liao; Jianlong Zhao
Journal:  Biomicrofluidics       Date:  2012-03-09       Impact factor: 2.800

6.  Expanding the available assays: adapting and validating In-Cell Westerns in microfluidic devices for cell-based assays.

Authors:  Amy L Paguirigan; John P Puccinelli; Xiaojing Su; David J Beebe
Journal:  Assay Drug Dev Technol       Date:  2010-07-26       Impact factor: 1.738

7.  Prediction and control of number of cells in microdroplets by stochastic modeling.

Authors:  Elvan Ceyhan; Feng Xu; Umut Atakan Gurkan; Ahmet Emrehan Emre; Emine Sumeyra Turali; Rami El Assal; Ali Acikgenc; Chung-an Max Wu; Utkan Demirci
Journal:  Lab Chip       Date:  2012-11-21       Impact factor: 6.799

8.  In Vitro Platform for Studying Human Insulin Release Dynamics of Single Pancreatic Islet Microtissues at High Resolution.

Authors:  Patrick M Misun; Burçak Yesildag; Felix Forschler; Aparna Neelakandhan; Nassim Rousset; Adelinn Biernath; Andreas Hierlemann; Olivier Frey
Journal:  Adv Biosyst       Date:  2020-01-29

9.  Soft lithography fabrication of index-matched microfluidic devices for reducing artifacts in fluorescence and quantitative phase imaging.

Authors:  Diane N H Kim; Kevin T Kim; Carolyn Kim; Michael A Teitell; Thomas A Zangle
Journal:  Microfluid Nanofluidics       Date:  2017-12-01       Impact factor: 2.529

10.  Tissue engineering toward organ-specific regeneration and disease modeling.

Authors:  Christian Mandrycky; Kiet Phong; Ying Zheng
Journal:  MRS Commun       Date:  2017-07-31       Impact factor: 2.566
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