Microfluidic devices with SPR sensing capabilities

US 20060188401A1
Filed: 02/23/2005
Published: 08/24/2006
Est. Priority Date: 02/23/2005
Status: Active Grant

First Claim

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1. A SPR system comprising a sensor substrate and an optical detector, said optical detector configured to generate non-visible radiation in a predetermined wavelength detection range and to direct said radiation towards the sensor substrate, at least a portion of the sensor substrate containing a surface plasmon generating film, the sensor substrate being made from a material that is not transparent to visible light but allowing for penetration of the non-visible radiation to the surface plasmon generating film.

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Abstract

A microfluidic system including a chip sensor and an SPR optical detector. The chip sensor may be made a non-transparent material, such as polyimide or silicon, allowing non-visible radiation produced by the SPR optical detector to pass through and interact with a surface plasmon generating layer on the chip sensor.

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26 Claims

1. A SPR system comprising a sensor substrate and an optical detector, said optical detector configured to generate non-visible radiation in a predetermined wavelength detection range and to direct said radiation towards the sensor substrate, at least a portion of the sensor substrate containing a surface plasmon generating film, the sensor substrate being made from a material that is not transparent to visible light but allowing for penetration of the non-visible radiation to the surface plasmon generating film.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
- - 2. The SPR system of claim 1, wherein said sensor substrate comprising a sensor chip including at least one channel, at least a portion of the sensor chip in or adjacent the channel containing the surface plasmon generating film.
  - 3. The SPR system of claim 1, further comprising affinity media connected to the surface plasmon generating film.
  - 4. The SPR system of claim 2, further comprising chromatographic separation media at least one of (i) adjacent the surface plasmon generating film and (ii) downstream from the surface plasmon generating film.
  - 5. The SPR system of claim 1, wherein the sensor substrate is made from polyimide.
  - 6. The SPR system of claim 5, wherein the optical detector is configured to generate radiation having a wavelength greater than or equal to approximately 700 nm.
  - 7. The SPR system of claim 1, wherein the sensor substrate is made from silicon.
  - 8. The SPR system of claim 7, wherein the optical detector is configured to generate radiation having a wavelength greater than or equal to approximately 1100 nm.
  - 9. The SPR system of claim 1, wherein the optical detector further includes a detector configured to detect the radiation after it has reflected from the surface plasmon generating film.
  - 10. The SPR system of claim 9, wherein the detector is a silicon based detector.
  - 11. The SPR system of claim 10, wherein the silicon based detector includes one of a PIN diode, CMOS chip and a CCD array.
  - 12. The SPR system of claim 9, wherein the detector is an infrared photodetector.
  - 13. The SPR system of claim 12, wherein the infrared photodetector comprises an InGaAs sensor.
  - 14. The SPR system of claim 2, further including a pump for pumping sample for analysis through the channel.

15. A sensor chip comprising a substrate, at least a portion of said substrate containing a surface plasmon generating film, said sensor chip at least partially being made from a material that is not transparent to visible radiation but allowing radiation having a predetermined wavelength in at least a portion of the non-visible wavelength range to pass through the sensor chip to the film.
- View Dependent Claims (16, 17, 18, 19, 20, 21, 26)
- - 16. The sensor chip of claim 15, wherein the substrate includes at least one channel and the surface plasmon generating film is located in or adjacent said channel.
  - 17. The sensor chip of claim 15, wherein the substrate includes multiple layers adhered together.
  - 18. The sensor chip of claim 15, further comprising affinity media connected to the surface plasmon generating film.
  - 19. The sensor chip of claim 16, further comprising chromatographic separation media in the at least one channel connected to the surface plasmon generating film.
  - 20. The sensor chip of claim 15, wherein the substrate is made from polyimide.
  - 21. The sensor chip of claim 15, wherein the substrate is made from silicon.
  - 26. The method of claim 21, wherein the sensor chip is made from one of polyimide and silicon and a lower value of the predetermined wavelength range is 1100 nm.

22. A method for using a microfluidic system for SPR analysis, said microfluidic system comprising a sensor chip and an optical detector, said sensor chip comprising at least one channel, at least a portion of said channel containing a surface plasmon generating film, said optical detector generating non-visible radiation in a predetermined wavelength detection range and being configured to direct said radiation towards the sensor chip, the sensor chip being made from a material that is not transparent but allowing radiation in the predetermined wavelength detection range to pass through to the surface plasmon generating film, said method comprising the steps of:
- passing a solution of interest through the channel; and
  
  passing non-visible radiation generated by the optical detector through the sensor chip towards the surface plasmon generating film.
- View Dependent Claims (23, 24, 25)
- - 23. The method of claim 22, wherein the sensor chip includes an affinity media attached to the surface plasmon generating film.
  - 24. The method of claim 22, wherein the sensor chip includes chromatographic separation media connected to the surface plasmon generating film.
  - 25. The method of claim 22, wherein the sensor chip is made from polyimide and a lower value of the predetermined wavelength range is 700 nm.

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Current Assignee
Bruker Daltonics GmbH and Co KG (Bruker Corporation)
Original Assignee
Sierra Sensors GmbH (Bruker Corporation)
Inventors
Killeen, Kevin, Roitman, Daniel B., Robotti, Karla

Granted Patent

US 8,178,046 B2
Time in Patent Office

Days
Field of Search
US Class Current

422/82.50
CPC Class Codes

B01L 2300/0654   Lenses; Optical fibres

B01L 2400/0475   specific mechanical means a...

B01L 2400/0622   distribution valves, valves...

B01L 2400/0644   rotary valves

B01L 3/502715   characterised by interfacin...

G01N 21/553   and using surface plasmons ...

Microfluidic devices with SPR sensing capabilities

First Claim

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Abstract

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26 Claims

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Microfluidic devices with SPR sensing capabilities

First Claim

4 Assignments

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Abstract

Citations

26 Claims

Specification

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