Optical waveguides – Optical waveguide sensor
Reexamination Certificate
2001-12-06
2003-06-10
Palmer, Phan T. H. (Department: 2874)
Optical waveguides
Optical waveguide sensor
C385S030000, C385S050000, C250S227250
Reexamination Certificate
active
06577780
ABSTRACT:
FIELD OF THE INVENTION
This invention relates generally to fiber-optic, evanescent-wave biosensors and, in particular, to improved cell design for such sensors.
BACKGROUND OF THE INVENTION
Optical fibers are being used in a variety of biosensor applications. For example, as discussed in U.S. Pat. No. 5,494,798, an optical fiber may be used without cladding to exploit the evanescent field present immediately outside the fiber/air interface. If a monoclonal or polyclonal antibody is attached to the exposed surface of the bare fiber, the evanescent field envelopes the molecule. But since there is little or no absorption or other phenomena to alter the amount of the light carried by the fiber, no attenuation or detectable characteristics are developed.
However, when an appropriately labeled antigen is attached to the antibody, the evanescent field can cause the antigen to fluoresce, resulting in an optically detectable characteristic such as a reduction in light intensity or fluorescence. Alternatively, by first binding the antigen, the sensor can be used to detect unknown targets, including toxins or immunogenic agents.
Whereas previous fiber-optic evanescent-wave sensors utilized multi-mode fibers, the '798 patent improved on the technique by employing a pair of single-mode optical fibers in a coupler arrangement. Light is introduced into one of the fibers to produce an evanescent region surrounding the coupling area, and the magnitude of light emitted from the pair of fibers is compared for detection purposes.
FIG. 1
, taken from the '798 patent, shows the overall fiber optic system generally at
10
. Light from laser diode
14
is inserted into a first leg
17
of a fiber optic coupler
18
, and exits on the same fiber at
19
(input channel). A second fiber
20
provides an output channel for light from the first leg
17
. A first photo diode detector
21
is connected to the input channel and a second photo diode detector
22
is connected to the output channel.
Each detector feeds its own transimpedance amplifier. The outputs of the transimpedance amplifiers
23
,
24
are applied to A/D converters
25
and
26
which provide digital electrical signals along wires
27
and
28
to an instrumentation board
29
. The instrumentation board
29
is then connected to a personal computer
30
which provides outputs to a printer or a monitor.
The finished probe includes the coupler and attached antibodies, which yields a baseline ratio for the sensor. The finished probe is then exposed to a material of interest, and the ratio of the light through the two sides of the coupler changes as a function of the way in which the target attaches. That is, the localized index of refraction at the coupling region and the determination of the ratio is a function of the binding in the coupler region.
In terms of the coupler itself, existing designs use off-the-shelf components intended for multiplexers and demultiplexers in telecommunications applications. Corning, for instance, makes these couplers by twisting together two or more 1300-nm, single-mode type 9-125 optical fibers, heating up the twisted area and pulling the ends apart to create a necked-down, nearly fused union. The number of fibers and other factors such as the proportion of each fiber in the twisted region determines the coupling ratio.
FIG. 2
depicts a typical commercially available cell. The device includes a central coupler section
202
, about 4 inches long and ¼-inch in diameter, from which leads
204
emerge from either end. The total length is on the order of 18″ or thereabouts. Often in multiple cells of this kind must be interconnected, in arrays, trees and other configurations. As the number of interconnected cells grows, the layout can become unwieldy. The need remains, therefore, for a more organized way of interconnecting multiple optical couplers, regardless of the end application.
SUMMARY OF THE INVENTION
This invention resides in an improved biosensor cell of the type used with a source of light such as a laser and an optical detector operative to sense changes in the light which might be indicative of a chemical or biological material. The apparatus 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 optical path for routing the source of light to one end of one of the optical waveguides, and a second optical path for routing the other end of the optical waveguide to the optical detector, such that the fluid-carrying chamber may be removed and replaced with the alignment of the ends of the waveguide and the optical paths being physically maintained.
In the preferred embodiment the waveguide is a fiber-optic coupler having a necked-down, fused region generating an evanescent field that extends into the fluid. The fluid-carrying chamber preferably includes an inlet and outlet to establish a flow around the optical waveguide. A chemical or biological constituent is disposed on the necked-down region within the evanescent field, such that binding alters the light exiting from the coupler for detection purposes. However, the invention is not limited in terms of the optical waveguide, in that single fibers, capillaries, integrated optical circuits and other conduits may be used.
The preferred embodiment also includes a plurality of optical waveguides, with partitions to establish a serpentine path around the waveguides for comprehensive exposure to the fluid. The fixture is also preferably configured to simultaneously receive a plurality of the fluid-carrying chambers, whether in a planar 1-by-X array or stacked to achieve an X-Y configuration.
REFERENCES:
patent: 4950885 (1990-08-01), Kershaw
patent: 5494798 (1996-02-01), Gerdt et al.
patent: 6078705 (2000-06-01), Neuschafer et al.
Gifford Krass Groh Sprinkle Anderson & Citkowski PC
Palmer Phan T. H.
Veridian Systems
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