METHOD AND DEVICE FOR SUPPORTING AN IMAGE-AIDED MEDICAL PROCEDURE

Abstract

In a method and a device for supporting the implementation of a medical procedure on a patient, the progress of the procedure is visibly indicated for the patient with an optical display. The stress associated with the procedure is thereby subjectively reduced for the patient.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a device according to the invention using a tomosynthesis-capable mammography apparatus in a schematic representation,

FIG. 2 shows an exemplary embodiment illustrating how the progress of the measure in a mammography method is visualized.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

According to FIG. 1, the device has, for example, an imaging x-ray system (a tomosynthesis-capable mammography apparatus in the exemplary embodiment), including an x-ray tube 2 for generation of x-rays that pass through an examination subject 4. The examination subject 4 is a female breast that is composed between a compression plate 6 and a support plate 8. The x-rays 3 passing through the examination subject 4, the compression plate 6 and the support plate 8 are received by a large-surface digital x-ray detector 10 that is composed of a number of individual detectors 12 arranged in a matrix-like array, and whose acquisition surface 11 is parallel to the plates 6, 8.

The x-ray tube 2 is arranged so as to be positionally variable in a limited range relative to the examination subject and can be pivoted, for example, in different angle positions j=1 . . . n in a limited angle range φ1, φ2 around an axis M perpendicular to the plane of the drawing such that individual images of the examination subject 4 can be generated at projection angles α_j relative to the normal 13 of the acquisition surface 11 of the x-ray detector 10. The angle range (φ1, φ2 does not have to be symmetrical to the normal 13. These 2D x-ray images or the projection data P_αj respectively associated therewith are supplied to a control and evaluation device 14 (an image computer) that performs a reconstruction into a tomosynthetic 3D image data set composed of a number of slice images, shown on a monitor 18. The x-ray detector 10 is stationary during the pivot movement of the x-ray tube 2. In principle it is also possible to mutually pivot the x-ray detector 10 as well or to linearly displace the x-ray detector 10 following the pivot movement of the x-ray tube 2.

A movement of the x-ray tube 2 on a limited, linear track instead of the pivot is also allowable so that the height difference between x-ray detector 10 and x-ray tube remains constant. This linear track likewise does not necessarily have to proceed symmetrical to the normal 1. Given this linear movement an alignment of the x-ray tube 2 on the examination subject 4 ensues so that in this case individual images of the examination subject 4 are also acquired from different projection angles α_j, however in a limited angle range.

The control of the angle position j or (in the case of a linear displacement) of the linear position and the alignment of the x-ray tube 2 as well as its operating parameters ensues using control signals S that are generated by the control and evaluation device 14. The mammography apparatus can be controlled with the aid of input elements (symbolically illustrated by a keyboard 16 in the example) and different operating modes can be selected and implemented by the operating personnel.

During the acquisition of the multiple 2D x-ray images (individual images or projection data P_α) required for such a tomosynthetic 3D x-ray image T, the patient is in an uncomfortable and necessarily also painful situation. In order to provide at least subjective relief for the patient, an optical display 20 is arranged in the range of vision of the patient, with which optical display 20 the progress of the procedure (in the shown example information about the progress of the procedure required to generate a tomosynthetic 3D image data set T—pivoting of the x-ray tube 2 into the desired angle positions j and respective generation of a 2D x-ray image) is indicated. In the example of FIG. 1, this is a progress bar 24 traveling from left to right in the direction of the arrow 22. The travel speed and the length of the remaining portion provide the patient with information about the progress of the procedure and the likely end. An acoustic signal emitter 26 is additionally provided with which the progress of the procedure is indicated by an acoustic signal, for example when the progress bar 25 jumps forward by an increment.

In the illustrated exemplary embodiment the optical display 20 is shown as a separate apparatus that can be placed in the field of vision of the patient by the operating personnel. In principle it is also possible to integrate the optical display into the device, for example in the screen surface of the monitor 18 provided for image reproduction.

Instead of the illustrated running or progress bar, other geometric representation forms are also conceivable, for example a progress ring, a progress circle or a progress triangle. The progress indication can also ensue using a number of light-emitting diodes arranged side by side. The progress of the medical procedure can likewise be visualized by numbers, for example between 0 and 100%, or by numeric specification of the remaining time.

A further possibility for the optical presentation of the progress of the procedure is shown in FIG. 2. There the optical display 20 for the progress is visualized by a degree of filling 20 of an area rendered on a monitor in the shape of a breast.

Although modifications and changes may be suggested by those skilled in the art, it is the intention of the inventors to embody within the patent warranted hereon all changes and modifications as reasonably and properly come within the scope of their contribution to the art.

Claims

1. A method for supporting implementation of a medical procedure on a patient, comprising the steps of: conducting a medical procedure by interacting with a patient; andduring said medical procedure, presenting a visual display to the patient within the patient's field of view that optically indicates progress of the procedure toward an end of the procedure.

2. A method as claimed in claim 1 comprising, in said display, visibly presenting an indication of a temporal progress of the procedure relative to a total duration of the procedure.

3. A method as claimed in claim 1 comprising, in said display, visibly indicating a remaining duration of the procedure.

4. A method as claimed in claim 1 comprising additionally providing an acoustical indication of said progress of said procedure.

5. A method as claimed in claim 1 comprising conducting said medical procedure by generating a plurality of 2D x-ray images at respectively different projection angles, from which a 3D image data set is reconstructed.

6. A method as claimed in claim 5 comprising reconstructing a tomosynthetic 3D image data set from said plurality of 2D x-ray images.

7. An apparatus for implementing a medical procedure on a patient, comprising: a medical device that interacts with a patient to implement a medical procedure on a patient; andan optical display within the patient's field of view; anda display generator that generates and presents an optical indication at said display indicating progress of the procedure toward an end of the procedure.

8. An apparatus as claimed in claim 7 comprising an acoustic signal emitter that emits an acoustic signal indicating said progress.

9. An apparatus as claimed in claim 7 wherein said medical device is an x-ray imaging device that acquires a plurality of 2D x-ray images of the patient respectively from different projection angles, and an image computer that reconstructs a 3D image data set from said plurality of 2D x-ray images.

10. An apparatus as claimed in claim 9 wherein said medical device is a mammography device that generates a tomosynthetic 3D image data set from said plurality of 2D x-ray images.