Abstract: Coupled fiber-optic, evanescent-wave biosensors are improved through the use of configurations which adjust certain optical characteristics for enhanced sensitivity. In the preferred embodiment, this is carried out by inputting light into the coupler at either a different wavelength or multiple wavelengths simultaneously. In alternative embodiments, different modulation schemes and/or interferometric schemes are utilized. For example, at each of the inputs, different carrier frequencies may be used and modulated at lower frequencies, including prime-number frequencies. As the refractive index is changed in the vicinity of the coupling, a shift in the wavelength will induce a phase shift in the baseline signal such that, during data collection, the sensor is able to detect more refined changes. In general, through appropriate choice of input wavelength, fewer operational points will fall in an inefficient local maximum or minimum, thereby affording much greater sensitivity.

Abstract: Coupled fiber-optic, evanescent-wave biosensors are improved through the use of configurations which detect changes in polarization for enhanced sensitivity. In contrast to existing techniques, wherein the fibers are twisted while pulled to disrupt polarization orientation, the inventive approach forms the necked-down region by heating and pulling the fibers without twisting them. As such, when polarized light is introduced, including randomly polarized light, the outputs will exhibit a split based upon polarization orientation as well. One or more bindings partners are then attached to the necked-down region and within the evanescent field for very specific and direct detection of minute concentrations of an analyte of interest. The invention is applicable to any type of organic/inorganic material, so long as the interaction of one component causes a change in any optical property detectable by the apparatus.

Abstract: An improved biosensor cell comprises a fluid-carrying chamber and a fixture configured to receive the chamber. The chamber includes one or more optical waveguides immersed in the fluid, each waveguide having an input end and an output end, both of which are optically accessible from outside the chamber. The fixture includes a first coupling or optical path for routing the source of light to one end of one of the optical waveguides, and a second coupling or optical path for routing the other end of the optical waveguide to the optical detector. The relationship between the fluid-carrying chamber and the fixture is such that the fluid-carrying chamber may be removed and replaced with the alignment of the ends of the waveguide and the optical coupling being physically maintained. The preferred embodiment uses a plurality of optical couplers, with partitions to establish a serpentine path around the couplers for comprehensive exposure to the fluid.

Abstract: Single-mode and multi-mode fibers to achieve modal splitting and greater sensitivity in an optical fiber coupler for evanescent-wave biosensor applications. A source of light having multiple modes is coupled to the input to one of the multi-mode fibers, with the geometry of necked-down section being such that a limited number of modes may be carried by the multi-mode fiber as the light emerges from the coupler. At least one of the single-mode fibers is supported adjacent the multi-mode fiber to receive and carry one of the limited modes. A biomolecule enveloped by the evanescent field, exhibits a direct or indirect affinity to a binding partner, such that attachment of the binding partner is at least partially responsible for the limited number of modes carried by the multi-mode fiber as the light emerges from the coupler.