IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0966364
(2013-08-14)
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등록번호 |
US-8743369
(2014-06-03)
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발명자
/ 주소 |
- Ran, Boaz
- Notcovich, Ariel G.
- Lipson, Ariel
- Nimri, Shay
- Lipson, Stephen G.
- Lipson, Doron
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출원인 / 주소 |
- Bio-Rad Laboratories Inc.
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
33 |
초록
▼
An SPR sensor comprising a thin conducting layer comprising at least one conductive element formed on a surface of a transparent substrate, a light source that illuminates an interface between the conducting layer and the substrate, a photosensitive surface that generates signals from light reflecte
An SPR sensor comprising a thin conducting layer comprising at least one conductive element formed on a surface of a transparent substrate, a light source that illuminates an interface between the conducting layer and the substrate, a photosensitive surface that generates signals from light reflected from the interface, a flow cell formed with at least one flow channel having a lumen defined by a wall formed from an elastic material and from a region of the conducting layer, and at least one hollow fluid-providing flow control apparatus having a lumen and an orifice communicating with its lumen. Fluid flow is enabled between the flow channel and the lumen of the flow control apparatus by forcing an end of the flow control apparatus through the elastic material so that the orifice communicates with the flow channel lumen.
대표청구항
▼
1. A surface plasmon resonance (SPR) system using a ligand, the system comprising: a) a thin conducting layer suitable for SPR formed on a transparent substrate, the conducting layer comprising a plurality of electrodes;b) at least one flow channel crossing the electrodes at crossover regions;c) a p
1. A surface plasmon resonance (SPR) system using a ligand, the system comprising: a) a thin conducting layer suitable for SPR formed on a transparent substrate, the conducting layer comprising a plurality of electrodes;b) at least one flow channel crossing the electrodes at crossover regions;c) a power supply connected to the electrodes, and differently electrifying the electrodes at two different cross-over regions, such that the ligand flowing through the flow channel is attracted to and immobilized on the electrode at one of the cross-over regions, and repelled by and substantially prevented from immobilizing on the electrode at the other of the cross-over regions; andd) a photosensitive surface that generates SPR signals in response to light reflected from the crossover region at which the ligand is immobilized, that can be used to determine an SPR parameter, and generates reference SPR signals in response to light reflected from the crossover region at which the ligand is prevented from immobilizing, that can be used to normalize and correct the SPR signals from the crossover region at which the ligand is immobilized. 2. A system according to claim 1, wherein the at least one flow channel comprises a plurality of flow channels. 3. A system according to claim 2, wherein the electrodes comprise a strip electrode crossed by the plurality of flow channels. 4. A system according to claim 2, wherein the electrodes comprise a pixel electrode crossed by only one of the flow channels. 5. A method for characterizing an interaction of a target material with a ligand on an SPR surface, the method comprising: a) electrifying a first electrode comprising a conducting layer suitable for SPR formed on a transparent substrate, so that it attracts the ligand;b) electrifying a second electrode differently from the first electrode, so that it repels the ligand, the second electrode also comprising a conducting layer suitable for SPR formed on a transparent substrate;c) passing a fluid containing the ligand through a flow channel crossed by the first and second electrodes while electrifying them, immobilizing the ligand on the first electrode and substantially not on the second electrode;d) passing the target material through the flow channel after the ligand has been immobilized;e) detecting light reflected from the first and second electrodes, after passing at least some of the target material through the flow channel;f) generating SPR signals from the detected light reflected from the first electrode, and SPR reference signals from the detected light reflected from the second electrode; andg) determining an SPR parameter that characterizes the interaction from the SPR signals, normalized and corrected by the SPR reference signals. 6. A method according to claim 5, also comprising: a) electrifying a third electrode, comprising a conducting layer suitable for SPR formed on a transparent substrate, that also crosses the fluid channel, after the ligand is immobilized on the first electrode, while passing fluid containing a second ligand through the flow channel, so that the second ligand is attracted to and immobilized on the third electrode, and electrifying the first and second electrodes differently so that the second ligand is repelled by and substantially not immobilized on the first and second electrodes;b) detecting light reflected from the third electrode, after passing at least some of the target material through the flow channel;c) generating additional SPR signals from the detected light reflected from the third electrode; andd) determining an SPR parameter characterizing an interaction of the target material with the second ligand from the additional SPR signals. 7. A system according to claim 3, wherein the strip electrode is about 100 μm in width. 8. A system according to claim 3, wherein the electrodes comprise a plurality of substantially parallel strip electrodes repeating at a pitch of about 200 μm. 9. A system according to claim 3, wherein the electrodes comprise about 100 substantially parallel strip electrodes. 10. A method according to claim 5, wherein the first electrode is a strip electrode crossed also by a second flow channel, the method also comprising: a) passing a fluid containing a second ligand, which has a polarity charge of a same sign as the first ligand, through the second flow channel while the first electrode is electrified so that it attracts the first and second ligands, immobilizing the second ligand on the first electrode where it is crossed by the second flow channel;b) passing a second target material, the same as or different from the first target material, through the second flow channel after the second ligand has been immobilized;c) detecting light reflected from the first electrode where it is crossed by the second flow channel, after passing at least some of the second target material through the second flow channel;d) generating second SPR signals from the detected light reflected from the first electrode where it is crossed by the second flow channel; ande) determining a second SPR parameter that characterizes an interaction of the second target material with the second ligand, from the SPR signals. 11. A method according to claim 10, wherein the second electrode is also a strip electrode crossed also by the second flow channel, the second ligand being repelled by the second electrode and substantially not immobilized on it when it is electrified differently from the first electrode, and the method also comprises detecting light reflected from the second electrode where it is crossed by the second flow channel and generating second SPR reference signals from said detected light, and determining a second SPR parameter that characterizes the interaction of the second target material with the second ligand comprises normalizing and correcting the second SPR parameter from the second reference signals. 12. A method according to claim 5, wherein the first electrode is a strip electrode crossed also by a second flow channel, the method also comprising: a) electrifying the first electrode so it repels the first ligand, at a different time than when the first electrode is electrified so it attracts the first ligand;b) passing a fluid containing a second ligand, which has a polarity charge of an opposite sign to the first ligand, through the second flow channel while the first electrode is electrified so that it repels the first ligand and attracts the second ligand, immobilizing the second ligand on the first electrode where it is crossed by the second flow channel;c) passing a second target material, the same as or different from the first target material, through the second flow channel after the second ligand has been immobilized;d) detecting light reflected from the first electrode where it is crossed by the second flow channel, after passing at least some of the second target material through the second flow channel;e) generating second SPR signals from the detected light reflected from the first electrode where it is crossed by the second flow channel; andf) determining a second SPR parameter that characterizes an interaction of the second target material with the second ligand, from the SPR signals. 13. A method according to claim 12, wherein, after one of the two ligands is immobilized on the first electrode, and it is electrified so it repels the already immobilized ligand and attracts the other ligand, the first electrode is not electrified so strongly that the already immobilized ligand is removed from it. 14. A surface plasmon resonance (SPR) system comprising: a) a thin conducting layer suitable for SPR formed on a transparent substrate, the conducting layer comprising a number of conducting strips about 100 μm in width;b) a plurality of flow channels crossing the conducting strips at crossover regions;c) an illumination system configured to illuminate an interface of the conducting layer and the substrate at the crossover regions, and at other regions of the conducting strips that are not crossover regions, at a plurality of different angles of incidence or different wavelengths; andd) a photosensitive surface that generates SPR signals in response to light reflected from the illuminated crossover regions that can be used to determine an SPR parameter, and generates reference SPR signals in response to light reflected from the other regions, that can be used to normalize or correct the SPR signals from the crossover regions.
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