IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
UP-0633446
(2003-08-01)
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등록번호 |
US-7515953
(2009-07-01)
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발명자
/ 주소 |
- Madar, Igal
- Murphy, John C.
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출원인 / 주소 |
- The Johns Hopkins University
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
65 인용 특허 :
6 |
초록
▼
Techniques for detecting fluorescence emitted by molecular constituents in a wall of a body lumen include introducing an autonomous solid support into the body lumen. Cells in a lumen wall of the body lumen are illuminated by a light source mounted to the solid support with a wavelength that excites
Techniques for detecting fluorescence emitted by molecular constituents in a wall of a body lumen include introducing an autonomous solid support into the body lumen. Cells in a lumen wall of the body lumen are illuminated by a light source mounted to the solid support with a wavelength that excites a particular fluorescent signal. A detector mounted to the solid support detects whether illuminated cells emit the particular fluorescent signal. If the particular fluorescent signal is detected from the illuminated cells, then intensity or position in the lumen wall of the detected fluorescent signal, or both, is determined. These techniques allow the information collected by the capsule to support diagnosis and therapy of GI cancer and other intestinal pathologies and syndromes. For example, these techniques allow diagnostic imaging using endogenous and exogenous fluoroprobes, treating diseased sites by targeted release of drug with or without photoactivation, and determining therapeutic efficacy.
대표청구항
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What is claimed is: 1. A method for detecting fluorescence emitted by cells in a wall of a body lumen, comprising the steps of: a. introducing a capsule swallowable by a human into a body lumen; b. illuminating cells in a lumen wall of the body lumen from a light source mounted in the capsule with
What is claimed is: 1. A method for detecting fluorescence emitted by cells in a wall of a body lumen, comprising the steps of: a. introducing a capsule swallowable by a human into a body lumen; b. illuminating cells in a lumen wall of the body lumen from a light source mounted in the capsule with a wavelength that excites a particular fluorescent signal; c. introducing to cells in the lumen wall including the illuminated cells, an exogenous fluorescent-labeled probe that binds to or is internalized by certain cells in the lumen wall comprising releasing the exogenous fluorescent-labeled probe from a first reservoir in the capsule and the particular fluorescent signal is emitted by the exogenous probe; d. generating an electric field from an electrode in the capsule to enhance uptake of the exogenous probe; e. detecting at a detector mounted in the capsule whether illuminated cells illuminated during step b emit the particular fluorescent signal; f. if the particular fluorescent signal is detected from the illuminated cells, then determining at least one of an intensity and a position in the lumen wall of the detected fluorescent signal; g. releasing a drug from a second reservoir in the capsule for killing abnormal cells indicated by the detected particular fluorescent signal; and h. controlling the movement of the capsule to keep it in place to monitor the efficacy of treatment by the released drug. 2. The method as recited in claim 1, wherein the particular fluorescent signal is emitted by a molecule that is endogenous to certain cells in the lumen wall. 3. The method as recited in claim 1, wherein the detected fluorescent signal indicates the presence or absence of abnormal cells. 4. The method as recited in claim 1, wherein the lumen wall is an intestinal wall and the abnormal cells are at least one of cancer cells, colon polyps and precancerous cells. 5. The method as recited in claim 1, said step of introducing the exogenous fluorescent-labeled probe comprising selecting the exogenous probe from a group comprising 2-deoxyglucose, Annexin V, phosphonium cations, rhodamine-123, JC1, and TMRE. 6. The method as recited in claim 1, said step of introducing the exogenous fluorescent-labeled probe comprising labeling an exogenous probe with a fluorescent marker that is a member of a group comprising 5-carboxyfluorescein diacetate, succinimidyl ester (CFDA/SE), 6-carboxyfluorescein diacetate, Aequorea green fluorescent protein (GFP), a two-photon fluorophore (C625), red fluorescent protein (dsRed) from discosoma (coral), cyanine dye, 3,3-diethylthiadicarbocyanine, carboxyfluorescein diacetate succinimidyl ester (CFSE), intrinsically fluorescent proteins Coral red (dsRed) and yellow (Citrine), fluorocein, rhodamine 123, Sulforhodamine (red), Dinitrophenyl (yellow), Dansyl (yellow) and safranin O. 7. The method as recited in claim 1, said step of introducing the exogenous fluorescent-labeled probe to cells in the lumen wall further comprising injecting the exogeneous probe into the human. 8. The method as recited in claim 1, further comprising, before said step of illuminating the cells in the lumen wall, performing the step of emitting ultrasonic waves from a sound source in the capsule to enhance uptake of the exogenous probe. 9. The method as recited in claim 1, wherein the abnormal cells are at least one of cancer cells, colon polyps or precancerous cells. 10. The method as recited in claim 1, said step of releasing the drug that kills the abnormal cells comprises releasing the drug from a reservoir in a different capsule introduced into the lumen of the intestine. 11. The method as recited in claim 1, further comprising the step of emitting ultrasonic waves from a sound source in the capsule to enhance uptake of the drug. 12. A capsule swallowable by a human for detecting fluorescence emitted by cells in a wall of a body lumen in the human, comprising: a solid support that fits inside a body lumen; a light source mounted to the solid support for generating light with a wavelength that excites a particular fluorescent signal in certain molecules; a first optical element mounted to the solid support for illuminating a section of a lumen wall of the body lumen with light from the light source; a detector mounted to the solid support for generating measurements based on the particular fluorescent signal; a second optical element mounted to the solid support for directing onto the detector the particular fluorescent signal emitted from the section illuminated; a processor for controlling the operation of the other components in the capsule, for collecting data based on measurements from the detector, and for generating pixals for an image based on the measurements; a data transfer system for transferring data based on the measurements to a monitoring unit outside the human; a first reservoir mounted to the solid support for storing an exogenous fluorescent-labeled probe; a second reservoir mounted to the solid support for storing a drug for killing abnormal cells; a release mechanism to release contents of the first and second reservoirs upon command; an electrode mounted to the solid support for generating an electric field to enhance uptake of the contents of the first and second reservoirs by cells in the lumen wall after release of the contents; a communications system; a wireless power transfer system; and a position control system for working against peristaltic action by the walls of the lumen on the solid support. 13. The capsule as recited in claim 12, the second optical element further comprising a filter to block out light at wavelengths not part of the particular fluorescent signal. 14. The capsule as recited in claim 12, the second optical element further comprising a shutter to block out light at times when the light source is illuminated. 15. The capsule as recited in claim 12, wherein the illuminated section is a band along an inner circumference of the body lumen. 16. The capsule as recited in claim 15, the first optical element further comprising a transparent band in an outer cover of the solid support. 17. The capsule as recited in claim 16, the first optical element further comprising an axicon to convert a light pulse on an axial beam from the light source into a radial band of light that passes through the transparent band. 18. The capsule as recited in claim 16, the first optical element further comprising a coherent bundle of optical fibers that cause a light pulse on an axial beam from the light source to diverge to multiple radial beams of light that pass through the transparent band. 19. The capsule as recited in claim 16, the first optical element further comprising a rotating mirror that reflects a light pulse on an axial beam from the light source to a rotating radial beam that passes through the transparent band. 20. The capsule as recited in claim 12, wherein the first optical element prevents light of the light source from impinging on the detector. 21. The capsule as recited in claim 16, the second optical element further comprising an axicon to convert a band of light that passes through the transparent band from the illuminated section of lumen wall to one or more beams of light that strike the detector. 22. The capsule as recited in claim 16, the second optical element further comprising a coherent bundle of optical fibers that causes multiple radial beams of light that pass through the transparent band from the illuminated section of the lumen wall to converge on the detector. 23. The capsule as recited in claim 16, the second optical element further comprising a rotating mirror that reflects in turn multiple radial beams of light that pass through the transparent band from the illuminated section of the lumen wall onto the detector. 24. The capsule as recited in claim 12, the detector further comprising a single sensor that integrates light in the particular fluorescent signal over the whole illuminated section. 25. The capsule as recited in claim 12, the detector further comprising an array of sensors that distinguishes light intensity in the particular fluorescent signal among different portions of the illuminated section. 26. The capsule as recited in claim 12, the detector further comprising a sensor that distinguishes light intensity in the particular fluorescent signal from the illuminated section among different times after the light source has stopped illuminating the section. 27. The capsule as recited in claim 12, each pixel representing an intensity of the particular fluorescent signal integrated over the illuminated section. 28. The capsule as recited in claim 12, each pixel representing an intensity of the particular fluorescent signal for one portion of the illuminated section. 29. The capsule as recited in claim 12, further comprising an acoustic transducer for generating acoustic waves to enhance uptake of the contents of the reservoir by cells in the lumen wall after release of the contents. 30. A monitoring unit for presenting fluorescence emitted by cells in a wall of a body lumen in a human, comprising: a receiver for receiving data from the capsule as recited in claim 12, a monitoring unit processor to generate an image of the illuminated section of the lumen wall based on the data; and a display for presenting the image to a user. 31. The monitoring unit as recited in claim 30, wherein: the receiver is configured to obtain position measurements based on a position of the capsule in the body lumen; and the monitoring unit processor is configured to determine the position of the capsule based on the position measurements from the receiver. 32. The monitoring unit as recited in claim 30, wherein: the monitoring unit processor is configured to determine when to release the contents of the first and second reservoirs; and the monitoring unit further comprises a transmitter to transmit the command to a receiver in the capsule communications system.
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