Opto-electronic DNA chip-based integrated card for clinical diagnostics.

Clinical diagnostics is one of the most promising applications for microfluidic lab-on-a-chip or lab-on-card systems. DNA chips, which provide multiparametric data, are privileged tools for genomic analysis. However, automation of molecular biology protocol and use of these DNA chips in fully integrated systems remains a great challenge. Simplicity of chip and/or card/instrument interfaces is amongst the most critical issues to be addressed. Indeed, current detection systems for DNA chip reading are often complex, expensive, bulky and even limited in terms of sensitivity or accuracy. Furthermore, for liquid handling in the lab-on-cards, many devices use complex and bulky systems, either to directly manipulate fluids, or to ensure pneumatic or mechanical control of integrated valves. All these drawbacks prevent or limit the use of DNA-chip-based integrated systems, for point-of-care testing or as a routine diagnostics tool. We present here a DNA-chip-based protocol integration on a plastic card for clinical diagnostics applications including: (1) an opto-electronic DNA-chip, (2) fluid handling using electrically activated embedded pyrotechnic microvalves with closing/opening functions. We demonstrate both fluidic and electric packaging of the optoelectronic DNA chip without major alteration of its electronical and biological functionalities, and fluid control using novel electrically activable pyrotechnic microvalves. Finally, we suggest a complete design of a card dedicated to automation of a complex biological protocol with a fully electrical fluid handling and DNA chip reading.

Aryldiazomethanes for universal labeling of nucleic acids and analysis on DNA chips.

DNA and RNA labeling and detection are key steps in nucleic acid-based technologies, used in medical research and molecular diagnostics. We report here the synthesis, reactivity, and potential of a new type of labeling molecule, m-(N-Biotinoylamino)phenylmethyldiazomethane (m-BioPMDAM), that reacts selectively and efficiently with phosphates in nucleotide monomers, oligonucleotides, DNA, and RNA. This molecule contains a biotin as detectable unit and a diazomethyl function as reactive moiety. We demonstrate that this label fulfills the requirements of stability, solubility, reactivity, and selectivity for hybridization-based analysis and especially for detection on high-density DNA chips.

A new generation of scanners for DNA chips.

Today, most of the DNA chips are used with fluorescent markers. Associated with fluorescence confocal scanners, this technology achieves remarkable performances in terms of sensitivity and accuracy. The main technical issues related to these scanners have already been reviewed. However, these scanners are costly, especially when high density chips are used. In this case, a mechanical precision of 1 microm or less is required to achieve the measurement precision required. This cost level prevents the spread of this technology in the diagnostic market. We will present a new concept for scanners with equivalent or superior performances, with a cost cut of 5-10. This concept is inspired from the field of optical disk and reader. Basically, an optical format is added to the chip, before DNA deposition. This format contains tracks which are superimposed to the DNA features. These tracks define the path that an optical head of a CD player must follow in order to scan the surface of the DNA chip. Such a head is a very cheap component, and has a precision of less than 100 nm thanks to real-time focus and tracking. These functions are fulfilled by electromagnetic actuators mounted on the support of the frontal lens. We show here that it is possible to use such a head to build a fluorescence confocal scanner with equivalent or even better performances than conventional scanners.