Method for localizing an invasive instrument, and an invasive instrument

Abstract

The invention is based on a new type of method which can be used to localize magnetizable small particles. According to the invention an invasive instrument, a catheter for example, is provided with a magnetizable marker, whereby a magnetic fluid is arranged in a fluid container. Such an invasive instrument can be localized during an invasive intervention on a patient by using a coil system which on the one hand generates an inhomogeneous basic magnetic field and on the other hand generates a superimposed temporally varying magnetic field. Previous localization methods, which are considerably more complex, can be dispensed with.

Description

Preferred embodiments of the invention will be described in the following with reference to the drawings, in which;

FIG. 1 gives a schematic illustration of the basic structure of the coil system which is used for the method according to the invention,

FIGS. 2A and 2B illustrate variants of catheters according to the invention,

FIGS. 3A and 3B illustrate catheters differing from one another on the basis of the spacings of markers, and

FIGS. 4A and 4B illustrate catheters with differing markers.

Claims

1.-12. (canceled)

13. A method for localizing an invasive instrument during an invasive intervention on a patient, comprising: arranging a magnetizable element in the invasive instrument;dividing an overall volume comprising a path of the invasive instrument from an entry point into the patient to a target point of the intervention into a plurality of subvolumes;selecting one of the subvolumes as a test volume;generating an inhomogeneous magnetic field that is temporally constant for a duration of a test step in the overall volume;setting up the inhomogeneous magnetic field so that a magnetization of the magnetizable element: enters a saturated state in all other subvolumes except for the test volume if the magnetizable element is located in one of the all other subvolumes, anddoes not enter a saturated state if the magnetizable element is located in the test volume;creating a temporally variable magnetic field in the overall volume;obtaining a measurement signal generated by a magnetization of the overall volume in response to the temporally variable magnetic field;evaluating the measurement signal to decide whether the magnetizable element is located in the test volume; andlocating the invasive instrument based on the evaluation.

14. The method as claimed in claim 13, wherein the steps of selecting, generating an inhomogeneous magnetic field, setting up the inhomogeneous magnetic field, creating a temporally variable magnetic field, obtaining a measurement signal, and evaluating the measurement signal are repeated until a subvolume where the magnetizable element is located has been found.

15. The method as claimed in claim 14, wherein the subvolume where the magnetizable element is located is selected as an initial test volume for a successive position of the invasive instrument moving along the path and adjacent subvolumes are selected successively as the test volume until a further subvolume where the magnetizable element is located has been found.

16. The method as claimed in claim 13, wherein the invasive instrument comprises a non-magnetizable basic body and the magnetizable element is arranged on or in the basic body.

17. The method as claimed in claim 16, wherein the magnetizable element is a magnetizable marker,wherein the magnetizable marker comprises a magnetic fluid contained in a closed container, andwherein the closed container is arranged on or in the basic body.

18. The method as claimed in claim 13, wherein the magnetization of the magnetizable element under a saturation level changes non-linearly with the temporally variable magnetic field.

19. The method as claimed in claim 13, wherein the temporally variable magnetic field comprises a constant basic frequency and a harmonics of the basic frequency in the measurement signal is captured and evaluated.

20. The method as claimed in claim 13, wherein the inhomogeneous magnetic field and the temporally variable magnetic field are generated by coils located in a fixed location arrangement with respect to an x-ray system.

21. The method as claimed in claim 13, wherein the x-ray system captures an x-ray image of the patient and a location of the magnetizable element is marked in the x-ray image.

22. An invasive instrument used in a medical procedure, comprising: a non-magnetizable basic body; anda magnetizable marker arranged on the basic body.

23. The invasive instrument as claimed in claim 22, wherein a magnetization of the magnetizable marker changes non-linearly in a magnetic field.

24. The invasive instrument as claimed in claim 22, wherein the magnetizable marker comprises a fluid contrast agent contained a closed container arranged on or in the basic body.

25. The invasive instrument as claimed in claim 24, wherein the fluid contrast agent comprises a plurality of magnetizable small particles.

26. The invasive instrument as claimed in claim 22, wherein a plurality of invasive instruments are used in the medical procedure.

27. The invasive instrument as claimed in claim 26, wherein each of the invasive instruments comprises a different size of a magnetizable marker.

28. The invasive instrument as claimed in claim 26, wherein each of the invasive instruments comprises two magnetizable markers with a different spacing between the two markers.

29. A medical system for performing an invasive intervention on a patient, comprising: an invasive instrument comprising a magnetizable element that inserts into the patient in an overall volume from an entry point into to a target point of the intervention;a first magnetic field generator that generates an temporally constant inhomogeneous magnetic field in the overall volume for a duration of a test step;a second magnetic field generator that generates a temporally variable magnetic field in the overall volume; andan evaluation device that evaluates a magnetization of the overall volume in response to the temporally variable magnetic field and locates the invasive instrument based on the evaluation.

30. The medical system as claimed in claim 29, wherein the temporally variable magnetic field comprises a constant basic frequency and a harmonics of the basic frequency in the measurement signal is captured and evaluated.

31. The medical system as claimed in claim 29, wherein the overall volume is divided into a plurality of subvolumes and one of the subvolumes is selected as a test volume,wherein the inhomogeneous magnetic field is generated so that a magnetization of the magnetizable element: enters a saturated state in all other subvolumes except for the test volume if the magnetizable element is located in one of the all other subvolumes, anddoes not enter a saturated state if the magnetizable element is located in the test volume,wherein the magnetization of the overall volume is evaluated to decide whether the magnetizable element is located in the test volume, andwherein a further subvolume is repeatedly selected as the test volume and the inhomogeneous magnetic field is repeatedly generated and the magnetization of the overall volume is repeatedly evaluated until a subvolume where the magnetizable element is located has been found.

32. The medical system as claimed in claim 31, wherein the subvolume where the magnetizable element is located is selected as an initial test volume for a successive position of the invasive instrument moving along a path and adjacent subvolumes are selected successively as the test volume until a subvolume where the magnetizable element is located at the successive position has been found.