A regenerable flow-through affinity sensor for label-free detection of proteins and DNA.

Label-free monitoring of biomolecular reactions in real-time is of great interest since it can provide valuable information about binding kinetics and equilibrium constants. In this report, a sensor based on White Light Reflectance Spectroscopy (WLRS) is presented that is capable of real-time monitoring of biomolecular reactions taking place on top of a polymer covered silicon dioxide reflective surface. The optical set-up consists of a visible-near infrared light source, a bifurcated optical fiber and a spectrometer. The outer part of the optical fiber guides the light vertically onto the surface where the biomolecular reactions occur, whereas the reflected light is driven from the central part of the fiber to the spectrometer. A microfluidic module in combination with a pump supplies the reagents at a constant rate. The biomolecular interactions are monitored as shifts of the wavelength of the interference minimum. The proposed methodology was applied for real-time and label-free monitoring mouse gamma-globulins binding onto immobilized anti-mouse IgG antibody. Mouse gamma-globulins at concentrations down to 150pM were detected in reaction times of 1-min. Regeneration of immobilized antibody was accomplished up to seven times without loss of its activity. In addition, real-time monitoring of hybridization reaction between complementary oligonucleotides was accomplished. The proposed sensor provides a simple, fast, low cost approach for label-free monitoring of biomolecular interactions and therefore it should by suitable for a wide range of analytical applications.

Real-time detection of BRCA1 gene mutations using a monolithic silicon optocoupler array.

The monolithic silicon optocoupler presented here offers a platform for a new generation of fully integrated devices fabricated through the mature and inexpensive silicon technology. Using the developed optocoupler, real-time detection of the most common mutations in BRCA1 gene related to predisposition to hereditary breast/ovarian cancer was accomplished. For this purpose, oligonucleotides corresponding to wild- and mutant-type sequences were immobilized onto different optocouplers and the hybridization with fluorescently labeled complementary or non-complementary sequences was monitored in real time. Hybridization of fluorescently labeled oligonucleotides to the immobilized ones modulated the coupling efficiency between the light emitting diode and the detector in a concentration-dependent manner. Using as label the AlexaFluor 647 dye (whose absorption maximum fits the emission maximum of the light source) a detection limit of 0.9 nM (9 fmol) was achieved. Real-time signal monitoring, especially during dehybridization, improved considerably the discrimination between wild-type and mutant sequences due to the ability to calculate dissociation kinetics upon washing independently for each one mutation. The bioanalytical capabilities of the transducer along with the fact that dense transducer arrays can be fabricated on a single chip open new frontiers in the manufacturing of microsystems appropriate for point-of-care analysis.