Automated liquid dispensing pin for DNA microarray applications

Document Type

Article

Publication Date

4-1-2006

Abstract

This paper describes a new liquid dispensing/aspirating system that is capable of producing micron-size spots/droplets for molecular biology research and analysis. In particular, the application is focused on deoxyribonucleic-acid microarray fabrication with the goals of uniform spot morphology, smaller spot size, higher yield, more efficient use of biological materials, and the capacity to handle high viscosity liquids. The new system is based on active sensing and control and it is part of a fully integrated robotic microarray system for genomic and proteomic applications. The prototype system handles thick liquids such as 100% glycerol as well as aqueous solutions and generates uniform spots in a contactless manner with controllable spot size ranging from 80 microns to 200 microns. Note to Practitioners-Microarraying is a powerful tool that enables the expression profiling of a vast quantity genetic/proteomic materials in parallel. Current printing technology includes photolithography, impact pins, InkJet, etc. Although these designs have been successful in printing spot size down to 100 microns, a new approach is needed to handle the order of magnitude increase in density while reducing cost. The SmartPin described in this paper is a sensor-based motion-controlled print head created for printing the next-generation microarrays. It is capable of depositing any aqueous samples (e.g., deoxyribonucleic acid, protein, etc.) and has the flexibility and cost advantage of the printing approach and yet possesses high performance and telepresence accessibility. The system utilizes an optical-fiber-based sensor probe for both sensing and sample delivery. Sensing is then integrated with computer control so that it can generate the microarray with fully controllable spot density and size. By maintaining a uniform gap distance between the pin tip and the target slide, performance and reliability are enhanced. The current work is at the prototype development state and will need further refinement for commercialization. © 2006 IEEE.

Identifier

33645695592 (Scopus)

Publication Title

IEEE Transactions on Automation Science and Engineering

External Full Text Location

https://doi.org/10.1109/TASE.2006.871481

ISSN

15455955

First Page

187

Last Page

191

Issue

2

Volume

3

Grant

0243302

Fund Ref

National Science Foundation

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