Inkjet dispensing technology: applications in drug discovery.

The past year has seen significant advances in the reduction to practice of inkjet dispensing technology in drug discovery applications. Although much of the work in this area has been done by relatively few 'early innovators', broader acceptance of the feasibility of the use of inkjet dispensing is on the rise. Of the three main areas of drug discovery - genomics, high-throughput screening, and combinatorial chemistry - high-throughput screening has had the most applications to date. The burgeoning field of genomics has seen rapid incorporation of technologies that enable miniaturization of gene expression experiments. Inkjet dispensing has a clear role in this effort. Finally, as the miniaturization needs of combinatorial chemistry become more clear, inkjet dispensing technology will potentially play a role.

Two-dimensional separations of peptides and proteins by comprehensive liquid chromatography-capillary electrophoresis.

Analysis of biological samples is problematic because of their complex composition. Reversed phase liquid chromatography (RPLC), size exclusion chromatography (SEC), and, more recently, capillary zone electrophoresis (CZE) are routinely used for the analysis of these samples, but are eventually limited because they are one-dimensional (1-D) methods. As sample complexity increases, the separation efficiency necessary to resolve a large number of sample components in one dimension becomes prohibitively high. A solution to this problem has been to use a two-dimensional (2-D) approach. Each dimension in a 2-D separation relies on a different separating mechanism. By expanding the separation into two dimensions, sample components unresolved in the first dimension can often be separated in the second. This circumvents the requirement for extremely high efficiencies in either dimension. Two-dimensional slab gel electrophoresis has been used successfully in this area, but a more instrumental approach is desired. In this paper we describe three coupled-column approaches to 2-D separations. First, microcolumn SEC-CZE is explored as a means of 2-D protein analysis. Next, RPLC-CZE is investigated for analysis of peptides in tryptic maps. Finally, RPLC is coupled with fast CZE (FCZE), a unique form of CZE analysis, for fast 2-D analysis of peptides. Details of the instrumentation used in these 2-D systems will be presented along with the results of some typical 2-D analyses.