Implantable sensor

US 9,532,738 B2
Filed: 03/08/2012
Issued: 01/03/2017
Est. Priority Date: 09/09/2009
Status: Active Grant

First Claim

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1. A sensor configured to sense glucose, urea, or lactate, the sensor being implantable in the body of a living creature or an object and configured for sensing in tissue or bodily fluids, the sensor comprising:

an integrated radiation source configured for coupling radiation generated by said source into a silicon photonics integrated circuit for irradiating said tissue or bodily fluids having at least one of glucose, urea, or lactate in said tissue or bodily fluid,a silicon photonics integrated circuit configured to spectrally process the radiation interacting with the glucose or urea or lactate, wherein the silicon photonics integrated circuit comprises at least an integrated optical waveguide, an optical demultiplexer, and a detection element,said integrated optical waveguide being configured for receiving radiation from said integrated radiation source and to send the radiation to the demultiplexer, said waveguide comprising a part configured for evanescent sensing within a measurement region from which the radiation interacting with the glucose, urea, or lactate is captured by said waveguide and senses the glucose, urea, or lactate by an evanescent tail of the radiation,said optical demultiplexer being configured for spectrally processing the radiation to obtain spectrally resolved radiationsaid integrated detection element being configured to detect different absorption or reflection bands of the glucose or urea or lactate from the spectrally resolved radiation to sense the glucose or urea or lactate, wherein the silicon photonics integrated circuit and the measurement region are configured for sampling free spectral measurements so that sensing can be performed without the need for extracting a sample or guiding a substrate of interest in a forced manner to the measurement region, andwherein the radiation source and the silicon photonics integrated circuit form an integrated spectrometer, andwherein said sensor is configured to be implantable in the body of a living creature or an object to sense glucose, urea, or lactate.

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Abstract

A sensor is described for sensing a substance such as for example glucose. The sensor is implantable in the body of a living creature. The sensor comprises a photonic integrated circuit, e.g. silicon-photonics, based radiation processor for spectrally processing radiation interacting with the sample. A continuous monitoring system also is described using such a sensor.

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21 Claims

1. A sensor configured to sense glucose, urea, or lactate, the sensor being implantable in the body of a living creature or an object and configured for sensing in tissue or bodily fluids, the sensor comprising:
- an integrated radiation source configured for coupling radiation generated by said source into a silicon photonics integrated circuit for irradiating said tissue or bodily fluids having at least one of glucose, urea, or lactate in said tissue or bodily fluid,a silicon photonics integrated circuit configured to spectrally process the radiation interacting with the glucose or urea or lactate, wherein the silicon photonics integrated circuit comprises at least an integrated optical waveguide, an optical demultiplexer, and a detection element,said integrated optical waveguide being configured for receiving radiation from said integrated radiation source and to send the radiation to the demultiplexer, said waveguide comprising a part configured for evanescent sensing within a measurement region from which the radiation interacting with the glucose, urea, or lactate is captured by said waveguide and senses the glucose, urea, or lactate by an evanescent tail of the radiation,said optical demultiplexer being configured for spectrally processing the radiation to obtain spectrally resolved radiationsaid integrated detection element being configured to detect different absorption or reflection bands of the glucose or urea or lactate from the spectrally resolved radiation to sense the glucose or urea or lactate, wherein the silicon photonics integrated circuit and the measurement region are configured for sampling free spectral measurements so that sensing can be performed without the need for extracting a sample or guiding a substrate of interest in a forced manner to the measurement region, andwherein the radiation source and the silicon photonics integrated circuit form an integrated spectrometer, andwherein said sensor is configured to be implantable in the body of a living creature or an object to sense glucose, urea, or lactate.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
- - 2. A sensor according to claim 1, wherein the measurement region is an open-space measurement region so that the measurement region is not enclosed by sensor walls.
  - 3. A sensor according to claim 1, wherein the radiation source is a radiation source monolithically integrated with the radiation processor or heterogeneously integrated with the radiation processor or hybridly integrated with the radiation processor.
  - 4. A sensor according to claim 3, wherein the radiation source is fibre-coupled to the radiation processor.
  - 5. A sensor according to claim 1, wherein the photonics integrated circuit based sensor is adapted for operating in at least a wavelength region of 1560 nm to 1850 nm and/or is adapted for operating in at least a wavelength region of 2080 nm to 2325 nm.
  - 6. A sensor according to claim 1, wherein the sensor is adapted for performing said spectrally processing radiation prior to interaction of the radiation with the glucose or urea or lactate to be sensed or wherein the sensor is adapted for performing said spectrally processing radiation after interaction of the radiation with the glucose or urea or lactate.
  - 7. A sensor according to claim 1, wherein the sensor has a sensor configuration such that a measurement region of the sensor is surrounded by components of the sensor or such that a measurement region of the sensor lies substantially at one side of all components of the sensor.
  - 8. A sensor according to claim 1, the sensor being configured for obtaining depth-related information regarding a sample or wherein the sensor is configured for spatially resolved detection and for deriving said depth-resolved information regarding the sample based thereon.
  - 9. A sensor according to claim 1, wherein the silicon photonics integrated circuit is adapted for spatially resolved detection of scattered or reflected radiation and/or wherein the silicon photonics integrated circuit comprises a plurality of cascading wavelength multiplexers configured to increase a number of channels for spectrally processing radiation and/or wherein the silicon photonics integrated circuit comprises a plurality of tuneable filters configured to increase a number of channels for spectrally processing radiation.
  - 10. A sensor according to claim 1, wherein frequency or time-domain multiplexing is used for increasing a number of channels for spectrally processing radiation and/or wherein a Vernier-shifted spectral response is used for increasing a number of channels for spectrally processing radiation.
  - 11. A sensor according to claim 1, the sensor comprising an electronics component stacked with the sensing element and radiation source.
  - 12. A sensor according to claim 1, said sensor being implantable in a bioreactor.
  - 13. A continuous monitoring system comprising an implantable sensor according to claim 1, anda readout system configured to wirelessly receive data sensed by the sensor.
  - 14. The sensor according to claim 1, wherein the sensor being waveguide based comprises waveguide components having submicron dimensions.
  - 15. A sensor according to claim 1, the sensor further comprising:
    - a coil antenna configured to provide power and transfer signals.
  - 16. The sensor according to claim 15, wherein the sensor is circular having a diameter between 1 and 1.5 cm.
  - 17. A sensor according to claim 1, wherein the sensor is configured for performing transmission measurements.
  - 18. A sensor according to claim 1, wherein the sensor is adapted for operating in single mode condition.
  - 19. A sensor according to claim 1, wherein said sensor is configured for subcutaneous, intramuscular, or ocular implantation.

20. A sensor configured to sense glucose, urea, or lactate, the sensor being implantable in the body of a living creature or an object and configured for sensing in tissue or bodily fluids, the sensor comprising:
- an integrated radiation source configured for coupling radiation generated by said source into a silicon photonics integrated circuit for irradiating said tissue or bodily fluids having at least one of glucose, urea, or lactate in said tissue or bodily fluid,a silicon photonics integrated circuit configured to spectrally process the radiation interacting with the glucose or urea or lactate, wherein the silicon photonics integrated circuit comprises at least an integrated optical waveguide, an optical multiplexer, and a detection element,said optical multiplexer configured to combine radiation into a single path in said integrated optical waveguide,said integrated optical waveguide being configured for receiving radiation from said integrated radiation source via said optical multiplexer and said integrated optical waveguide being configured for sending the radiation to the tissue or bodily fluid, said waveguide comprising a part configured for evanescent sensing within a measurement region from which the radiation interacting with the glucose, urea or lactate is captured by said waveguide and senses the glucose, urea or lactate by the evanescent tail of the radiation, andsaid integrated detection element to detect different absorption bands of the glucose or urea or lactate from the spectrally processed radiation received from said integrated optical waveguide to sense the glucose or urea or lactate,wherein the silicon photonics integrated circuit and the measurement region are being configured for sampling free spectral measurements so that sensing can be performed without the need for extracting sample or guiding the substance of interest in a forced manner to the measurement region, andwherein the radiation source and the silicon photonics integrated circuit form an integrated spectrometer, andwherein said sensor is configured to be implantable in the body of a living creature or an object.
- View Dependent Claims (21)
- - 21. A sensor according to claim 20, wherein said sensor is configured for subcutaneous, intramuscular, or ocular implantation.

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Current Assignee
Indigo Diabetes NV
Original Assignee
IMEC International, Universiteit Gent Vzw
Inventors
Ryckeboer, Eva Maria Paula, Delbeke, Dana, Baets, Roel, Bogaerts, Wim
Primary Examiner(s)
Chen, Tse
Assistant Examiner(s)
Liu, Chu Chuan (J J)

Application Number

US13/415,392
Publication Number

US 20120226118A1
Time in Patent Office

1,762 Days
Field of Search

600/310, 600/316, 600/317, 600/319, 600/321, 600/322, 600/326, 600/329, 600/332, 600/333, 600/340, 600/341, 600/342, 600/473, 600/476, 356/39
US Class Current

1/1
CPC Class Codes

A61B 2562/028   Microscale sensors, e.g. el...

A61B 5/0031   Implanted circuitry

A61B 5/14532   for measuring glucose, e.g....

A61B 5/1459   invasive, e.g. introduced i...

G02B 2006/12061   Silicon

G02B 2006/12123   Diode

G02B 2006/12138   Sensor

G02B 6/12021   Comprising cascaded AWG dev...

Implantable sensor

First Claim

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Abstract

Citations

21 Claims

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Implantable sensor

First Claim

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Abstract

Citations

21 Claims

Specification

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Solutions

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