Chemical apparatus and process disinfecting – deodorizing – preser – Analyzer – structured indicator – or manipulative laboratory... – Means for analyzing liquid or solid sample
Reexamination Certificate
1999-10-05
2002-02-26
Alexander, Lyle A. (Department: 1743)
Chemical apparatus and process disinfecting, deodorizing, preser
Analyzer, structured indicator, or manipulative laboratory...
Means for analyzing liquid or solid sample
C422S082050, C436S150000, C436S164000, C385S012000
Reexamination Certificate
active
06350413
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to apparatus for solid-state biochemical binding assays, and especially to optical structures utilizing evanescent sensing principles for use in such apparatus and assays.
2. State of the Art
Immunoassays exploiting the properties of an optical technique known as total internal reflection (abbreviated TIR) are proving to be a valuable tool for detection of analytes at concentrations of 10
−10
to 10
−13
molar or below, without a wash step. When a light beam traveling in a waveguide is totally internally reflected at the interface between the waveguide and an adjacent medium having a lower refractive index, a portion of the electromagnetic field of the TIR light penetrates shallowly into the adjacent medium. This phenomenon is termed an “evanescent penetration” or “evanescent light”. The intensity of evanescent light drops off exponentially with distance from the waveguide surface.
Binding assays in general are based on the strong affinity of a selected “capture” molecule to specifically bind a desired analyte. The capture molecule/analyte pair can be an antibody/antigen pair or its converse, a receptor/ligand pair or its converse, etc, as known in the art. In a fluorescent binding assay, the binding of the analyte to the antibody is monitored by a tracer molecule which emits fluorescent light in response to excitation by an input light beam.
One of several possible schemes for exploiting the properties of evanescent light fields for fluorescence measurements is as follows. If an antibody is immobilized on an optical structure in which a light beam is being propagated by TIR, the resulting evanescent light can be used to selectively excite tracer molecules that are bound (whether directly or indirectly) to the immobilized antibody. Tracer molecules free in solution beyond the evanescent penetration depth are not excited, and therefore do not emit fluorescence. For silica-based optical materials or optical plastics such as polystyrene, with the adjacent medium being an aqueous solution, the evanescent penetration depth is generally about 1000 to 2000 A (angstroms). The amount of fluorescence is thus a measure of the amount of tracer bound to the immobilized capture molecules. The amount of bound tracer in turn depends on the amount of analyte present, in a manner determined by the specifics of the immunoassay procedure.
U.S. Pat. No. RE 33,064 to Carter, U.S. Pat. No. 5,081,012 to Flanagan et al, U.S. Pat. No. 4,880,752 to Keck, U.S. Pat. No. 5,166,515 to Attridge, and U.S. Pat. No. 5,156,976 to Slovacek and Love, and EP publications Nos. O 517 516 and 0 519 623, both by Slovacek et al, all disclose apparatus for immunoassays utilizing evanescent sensing principles.
Desirably, an immunosensor should be capable of accurately and repeatably detecting analyte molecules at concentrations of 10
−13
M (molar) to 10
−15
M and preferably below. At present, such sensitivity is not believed to be available in a commercially practical and affordable immunosensor. Also desirably, an immunosensor should provide multiple “channels”, that is, the capacity for measuring multiple analytes and multiple measurements of the same analyte, on the same waveguide substrate. Such an immunosensor would allow both self-calibration with known standards, and screening for a panel of different analytes selected for a particular differential diagnostic procedure.
One approach to improving the sensitivity (lowering the detection limits) of fluorescent immunosensors, proposed by Ives et al. (Ives, J. T.; Reichert, W. M.; Lin, J. N.; Hlady, V.; Reinecke, D.; Suci, P. A.; Van Wagenen, R. A.; Newby, K.; Herron, J.; Dryden, P. and Andrade, J. D. “Total Internal Reflection Fluorescence Surface Sensors” in A. N. Chester, S. Martellucci and A. M. Verga Scheggi Eds.
Optical Fiber Sensors
, NATO ASI Series E, Vol 132, 391-397, 1987), is to use waveguides which are very thin, perhaps about 1 &mgr;m in thickness. Such thin waveguides may provide higher evanescent intensity and a reflection density of 500-1000 reflections/cm or more. However, the potential lowering of the detection limit by use of thin-film waveguides is achievable only if the waveguide material is nonfluorescent and low-loss. Most present evanescent immunosensing technology (“thick” waveguides) utilizes silica glass (SiO
2
), which is intrinsically nonfluorescent. Only the purest grades of silica, for example UV grade quartz which is rather expensive, lack the additives and impurities that fluoresce (Dierker, et al., 1987).
Further, one cannot simply fabricate silica-on-silica waveguides by depositing SiO
2
onto a quartz substrate because there would be no refractive index difference. Instead one must either (1) fabricate a glass waveguide of higher refractive index than the underlying silica substrate, or (2) deposit a silica waveguide onto a transparent substrate of a lower refractive index. Therefore, other materials must be employed.
Thin film waveguides have been described by Sloper et al. (“A planar indium phosphate monomode waveguide evanescent field immunosensor,
Sensors and Actuators
B
1
:589-591, 1990) and Zhou et al. (“An evanescent fluorescence biosensor using ion-exchanged buried waveguides and the enhancement of peak fluorescence”,
Biosensors and Bioelectronics
6:595-607, 1991. However, neither of these devices was capable of achieving detection of analyte concentrations significantly below 10
−10
molar. The waveguide structure of Sloper was of the gradient-index type, formed by diffusion of a dopant into the silica base, which results in a drop-off of dopant concentration with distance from the interface. The waveguide of Zhou had only a single “channel” (measurement region).
Therefore, a need exists for an optical structure useful in an evanescent sensing immunoassay, which provides increased levels of propagated TIR light and increased evanescent field intensity, as well as multiple measurement regions. Such an optical structure should desirably be capable of detection of analyte concentrations of 10
−13
M and preferably below 10
−15
M. A need also remains for an immunosensor including such an optical structure, which is sufficiently inexpensive and practical to be produced as a commercial device, and which provides accurate and repeatable results in the hands of non-skilled persons. Still further, a need also remains for an biosensor capable of detecting ions, as opposed to hormones or other biological molecules.
SUMMARY
The invention comprises a step gradient waveguide, also described as a composite waveguide, useful for performing evanescent sensing assays. The waveguide includes a thick substrate formed of a first optical material of refractive index n
1
and having a first surface, and a thin film formed of a second optical material having a refractive index n
2
which is greater than n
1
, the thin film being disposed adjacent and in operative contact with the substrate. The optical substrate has a thickness which may be from about 0.3 &mgr;m up to 10 mm or more, depending on the material used, while the thin film has a thickness which is generally between about 0. 3 &mgr;m and about 5 &mgr;m. Highly preferably, the waveguide thickness is selected to provide for internal propagation in from one to four modes only.
The invention further encompasses a kit comprising the composite waveguide, and at least one specific binding molecule immobilized to said thin film and constructed to bind with specificity an analyte. The kit may be further constructed for use in either a competition assay or a sandwich type assay. The tracer molecule is further constructed to be excited by evanescent light penetrating from the thin film into an adjacent aqueous environment, and to respond thereto by emitting a photodetectable tracer signal.
In a preferred embodiment, the composite waveguide comprises the substrate with a plurality of thin strips of the thin film disposed in parallel array thereon, and the kit further includes
Christensen Douglas A.
Herron James N.
Reichert W. Monty
Wang Hsu-Kun
Alexander Lyle A.
TraskBritt
University of Utah Research Foundation
LandOfFree
Integrated optic waveguide immunosensor does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Integrated optic waveguide immunosensor, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Integrated optic waveguide immunosensor will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2949588