Chemical apparatus and process disinfecting – deodorizing – preser – Analyzer – structured indicator – or manipulative laboratory...
Reexamination Certificate
1999-10-22
2003-12-30
Marschel, Ardin H. (Department: 1631)
Chemical apparatus and process disinfecting, deodorizing, preser
Analyzer, structured indicator, or manipulative laboratory...
C422S068100, C435S006120, C435S007100
Reexamination Certificate
active
06669906
ABSTRACT:
BACKGROUND AND SUMMARY OF THE INVENTION
The invention relates to a new principle of measurement for constructing sensors and for use in bioinformatics. The technology is based on a new plasmon optical measurement setup applying clusters, by means of which nucleic acids, proteins or their ligands can be detected. The analytes cited above induce the binding or dissociation of metallic clusters, which have been or will be bound at a defined distance to a reflecting, preferentially electron-conducting surface. The binding or dissociation is transduced into a clearly detectable optical signal through resonant enhancement of clusters interacting with their mirror dipols. Nowadays there is a strong demand for fast, simple and cheap test procedures in medical diagnostics, food and environmental analysis. Sensitivity, selectivity and reliability are absolutely required. At the same time, ever increasing requirements for sensitivity, selectivity and reliability combined with maximal simplicity of the measurement process are demanded. The present invention aims on reducing technical restrictions of established measurement procedures through a novel one step test setup. Rapid and secure test-kits for clinical and lab use can be set up based on this technology. As possible fields of application, the diagnosis of urinary tract infections, screening of allergens, quantification of bacterial contamination of food, blood-glucose can be cited.
The parts of the invention provided with reference signs are to be assigned as follows:
1
=support material,
2
=reflecting layer (preferentially electron-conducting metal or cluster layer),
3
=0-500 nm distance layer,
4
=nanometric, non-conducting particles,
5
=chemically reactive surface attachment,
6
=linker (e.g. DNA, proteins, . . . ),
7
=cluster,
8
=analyte,
9
=split linker (e.g. split by the analyte),
10
=non-split linker,
11
=after coupling of the catalytically reactive analyte,
12
=sensor setup after splitting of the linker,
13
=dissociation of the cluster with an attached part of the linker,
14
=free split cluster-linker-conjugates,
15
=electrodes at or near the chip or magnet,
16
=analyte-binding molecule, e.g., DNA, protein, . . . ,
17
=analog to the analyte.
The sensor is formed of a metal layer, on a substrate material, an inert distance layer e.g., deposited by spin coating or chemical vapor deposition, on top of which individual linker molecules with bound clusters are coupled. The diameter of the clusters is preferentially chosen to be smaller than 40 nm. If the analyte interacts with the linker, it induces either changes in the extent of surface coverage of the cluster layer on a molecular scale or changes in the spatial arrangement of the bound clusters, both leading to characteristic changes of the optical appearance of the sensor surface. The surface colored by the abnormal optical effect is changed because of the catalytic or biorecognitive activity of an analyte or the addition of an enzymatically active component. Metal clusters layers with a cluster diameter smaller than 500 nm preferentially smaller than 40 nm (to suppress multipol peaks in the spectrum) possess strong and narrow reflection minima. Their spectral position is extremely dependent on their spatial arrangement, especially the distance of the cluster layer to the electron conducting surface.
The sensor setup can transduce even minute changes in the extent of surface coverage with clusters into a clearly visible optical signal, either a strong change in absorption at a defined wavelength or a spectral shift of the absorption maximum. According to the invention it is possible to convert biorecognitive binding processes and catalytic activity of proteins by the application of surface enhanced clusters into an optical signal (=color change of sensor surface).
The sensitivity of the chip can roughly be estimated as follows: Clusters of a diameter of 25 nanometers are arranged in a two dimensional lattice of 100 nanometers and where each cluster is bound via one analyte to the surface. At an optical resolution of {fraction (1/10)} mm (observation of a field of 100×100 micrometers gives a meaningfull signal) a change of 10% of the maximum signal equals 2×10e
5
molecules. This sensitivity has been proved with an antigen—antibody setup. The application of catalytically active analytes increases the sensitivity several orders of magnitude and allows single molecule detection.
Nanoclusters (preferenually silver, aluminum or gold cluster) can be bound by means of so-called biochemical linkers at a defined distance to the metallized surface. A detectable signal will result if these linker are either formed or cut by biochemical recognition or by catalysis, or if their spatial arrangement is altered. According to the invention, i.e., oligonucleotides are applied as linkers which can then be cut by the analyte (e.g. restriction enzymes from microorganisms) (see FIGS.
1
and
2
). Many pathogenic microorganisms express specific restriction endonucleases and can therefore be detected by means of the new sensor without expensive instrumentation at the local physician or in the laboratory. This enables, e.g., the differential diagnosis of urinary tract infections through direct detection of
E. coli
(responsible for 60% of all urinary tract infections). A fast and reliable screening method for bacterial contamination of foods can also be constructed.
The technology is based on enhanced cluster plasmons, which transduce in a very simple and reproducible manner the activity of a chemically reactive species into an optical signal.
The sensor setup essentially is built in a way that:
1. at a distance of less than 1 &mgr;m to
2. a reflecting surface, preferentially an electron conducting layer
3. linkers are immobilized, onto which
4. directly or indirectly electrically conducting clusters are bound.
Metal clusters can therefore be coupled to the surface of an inert (non-reactive) polymer and can be arranged on the polymer surface via biochemical linkers in a defined distance to the metal surface. The linkers can either be cut or their spatial arrangement can be altered through biochemical recognition or catalysis both leading to an optically detectable signal. In a DNA/RNA-test-system oligonucleotides can be used as linkers, which will consecutively be cut by restriction enzymes from microorganisms.
This invention differs substantially from the subject of the invention of the Austrian Patent No. 403,746 and U.S. Pat. No. 5,611,998 in substantial structural features: The invention does not involve a reactive matrix preferentially meant to perform volume changes. The setup described in this application is based on alterations of surface coverage with clusters bound via analyte-interactive linkers at a defined distance to an electron conducting layer.
The term “abnormal properties of a metal film” means a strong absorption maximum in the visible spectrum, resulting from localization of the conductivity electron plasma within the spatial boarders of nanometric particles. This spatial localization contrasts to the free mobility of electrons in a macroscopic piece of metal (the free mobility of electrons there is responsible for a strong unspecific reflection, generally called metallic luster).
A metal cluster at a defined distance from a metal surface interacts with the electron gas of the neighboring metal layer. At a certain distance of the absorbing cluster layer to the metal surface the electric field reflected from the metal surface has the same phase like the incoming fields. The resulting feedback mechanism enhances the effective coefficient of absorption of the cluster layer. Since at a given thickness of the distance layer the optimum phase enhancement depends only on the frequency of the radiated light, the system can be spectrally characterized by a very narrow reflection minimum. The intensity of the absorption band is directly
Bauer Georg
Pittner Fritz
Schalkhammer Thomas
Dykema Gossett PLLC
Marschel Ardin H.
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