M. Kovarik, Douglas M. Ornoff, Adam T. Melvin
Jan 15, 2013
Citations
1
Influential Citations
186
Citations
Quality indicators
Journal
Analytical chemistry
Abstract
Applications of micro total analysis systems (μTAS) span basic-science research, clinical medicine, and field work. Assay devices designed for these applications offer improvements to existing methods or provide fundamentally new strategies. Both mature methods and novel techniques have benefited from the increased throughput, integration and miniaturization afforded by μTAS. Traditional assays such Western blots and binding assays are recapitulated in a μTAS format but with reduced reagent usage, decreased performance times and added capabilities. An increasingly vibrant area is the performance of drug screening and toxicology assays on-chip, enabling the efficient screening of very large numbers of molecules. Similarly, recent μTAS reactors demonstrate greater chemical synthetic yields and novel product synthesis compared to macro-systems, often as a result of accurate control over reaction conditions including precision reagent dispensing. These exciting systems are now enabling on-site production of short-lived radioactive compounds for medical applications. The greatest impact of μTAS may very well be the ability to perform massively parallel laboratory experiments, for example, the use millions of reaction vessels or the analysis of hundreds of thousands of single cells. Another strength of μTAS lies in the creation of multicellular communities, for example, the combination of many cell types into an interacting system to explore intercellular communication. Devices with multiple layers of co-cultured tissues benefit from precise placement of molecules, such as extracellular matrices or growth factors, in both space and time. Similarly, the complexity and variety of organ-on-chip and organism-on-chip technologies continues to escalate rapidly. Impressively, the types of organisms cultured on-chip now range from the simplest bacteria to complex animals such as fish. Automation, reliability, and integration must all increase as a device moves from the specialist environment of a lab to usage by non-expert personnel in the outside world, for example, at a clinical point-of-care or in environmental monitoring. Key innovations in recent months result in devices that operate with minimal external equipment, error-free operation, and unambiguous readouts, all critical for operation by untrained personnel. Lightweight, portable devices are increasingly used to identify chemical and biological toxins in water, air and soil with applications in public health, defense, and homeland security. Perhaps most exciting is the development of μTAS with sufficient robustness for operation in challenging environments, such as the ocean and outer space. A central component of these systems is the ability to withstand the unexpected. These systems push the boundaries of current integration principles and spur rapid growth of new design philosophies. This review focuses on advances in the area of μTAS or “lab-on-a-chip” systems over the time span of May 2011 through September 2012 with a focus on applications in basic research, clinical medicine and field usage. A range of journals with 2011 impact factors from 2.0 to 36.3 were screened to cover publications with highly specialized content as well as those directed at multidisciplinary audiences. These publications included discipline-specific journals such as Analytical Chemistry and Lab on a Chip as well as general scientific publications, e.g. Science and Nature. To identify material beyond the individually examined journals, extensive key word searches in databases such as PubMed, SciFinder, and Web of Science were performed. Recent reviews in the area of μTAS were also examined for appropriate references. Care was taken to identify impactful and exciting work from across the globe. Well over a thousand papers in the three target areas were identified and discussed. Due to space limitations, we were unable to include all papers but instead incorporated those most fitting into the review scheme and those reporting innovations in basic microdevice technology as well as in applications to biological, physical and engineering sciences. We apologize in advance for omitted papers and welcome feedback regarding any oversights on our part.