Imaging apparatus and method for the operation thereof

An imaging apparatus has an examination space in which a region of an examination subject to be examined can be positioned as well as an optical image acquisition sensor, which is provided to acquire a surface of the examination subject in the examination space and which is linked with an evaluation unit such that acquired surface data are provided as control information for controlling an image acquisition unit, in particular an x-ray device.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention concerns an imaging apparatus suitable for medical or industrial purposes, in particular an apparatus operating with x-ray radiation or using magnetic resonance, as well as a method for adjustment of operating parameters of such an apparatus.

2. Description of the Prior Art

An imaging apparatus as well as a method of the above general type are described in DE 102 32 676 A1.

In the operation of imaging apparatuses that are provided for medical diagnostic or therapeutic purposes, the significance of the acquired diagnostic data and the therapeutic success generally require the patient to be positioned in an exactly-defined manner relative to the data requisition portion of the apparatus. A device for positioning a patient for this purpose is known, for example, known from DE 103 40 002 B3.

If a patient is examined by computed tomography, before the generation of the computed tomography exposure, an image known as a topogram is typically generated by means of x-rays as an overview exposure in the framework of the examination planning. For the generation of the topogram, the patient is located in a defined position while a gantry (carrying an x-ray source as well as an associated detector device) of the computed tomography apparatus is located at an established angular alignment. The gantry that rotates during a computed tomography acquisition must therefore be braked to the point of a stop before the generation of the topogram. Due to the typical rotation speed of the gantry of up to three revolutions per second and a mass of the gantry on the order of one metric ton, this entails a significant time expenditure of, for example, approximately one minute. The same time expenditure is incurred in order to accelerate the gantry to the original rotation speed again after the generation of the topogram. Furthermore, an unavoidable radiation exposure of the patient is associated with the generation of the topogram.

SUMMARY OF THE INVENTION

An object of the present invention is to enable operation of an imaging apparatus with particularly low exposure (in particular radiation exposure) for the patient.

The above object is achieved in accordance with the present invention in an imaging apparatus having an examination space in which a region of an examination subject to be examined can be positioned, and having an optical image acquisition sensor that acquires an optical image of a surface of the examination subject in the examination space. An evaluation unit generates control information from surface data of the subject obtained from the optical image, the control information being used to control an image data acquisition unit of the apparatus. The evaluation unit has access to a memory, in which the surface data are stored correlated with information acquired by the image data acquisition unit.

The inventive apparatus enables the acquisition of structures inside the examination subject, in particular the acquisition of a slice exposure of the examination subject, so that in principle a computed tomography modality operating with x-ray radiation as well as a magnetic resonance modality can be used. Computed tomography represents the preferred application field of the invention.

In addition to the (advantageously x-ray-related) transmission and detection devices of the imaging apparatus, it includes an optical image acquisition sensor that acquires an optical image of the surface of the examination subject in the examination space. The optical image acquisition sensor is arranged such that it enables a surface image acquisition of the examination subject when the subject is located in the same position as for a radiographic examination using the diagnosis unit (in particular an x-ray radiator and detector unit) of the imaging apparatus.

For linking the optical image acquisition sensor with the imaging diagnosis unit with regard to data therefrom, an evaluation unit is provided that makes the acquired surface data of the examination subject (in particular patients) usable as control information for activation of the imaging diagnosis unit. An automatic adoption of data acquired by means of the optical image acquisition sensor into an examination protocol of the imaging apparatus is provided, the examination protocol establishing the workflow of the radiographic examination. The surface data acquired by the optical image acquisition sensor are stored correlated with volume information acquired by means of the imaging diagnosis unit.

The optical acquisition of the position of the patient while the patient is located in the same position as for the computed tomography examination minimizes the risk of a mis-positioning of the patient as well as the risk of misinterpretation diagnostic data This is particularly the case for special examinations, for example of the hand, in which the arm is extended above the head of the patient and the image acquisition is implemented contrary to the otherwise-typical convention in radiology, which assumes a viewing direction from below through the patient.

Due to the correlated (and thereby logically linked) storage of the surface data acquired by the optical image acquisition sensor with the volume information acquired by the diagnosis unit, this linked information is also available for further purposes, such as for navigation purposes in medical interventions.

Various advantages result from the possibility to display information at a display device (the information having been acquired by the imaging diagnosis unit (in particular an x-ray radiator and detector device)) in correlation with data that have been acquired with the optical image acquisition sensor. The display device (for example a screen of the computed tomography apparatus also used in the examination planning) advantageously enables a representation of the surface of the examination subject in real time. A real time representation means a screen representation for which (unavoidable) delays (dependent on the system) are so slight in relation to the acquired subject matter that an observer detects no time offset of the screen display.

The surface of the examination subject acquired by means of the optical image acquisition sensor preferably is represented in three-dimensional form, in particular bordered or as a grid. Furthermore, the evaluation unit can enable a shift as well as an enlargement or shrinking of the surface region of the examination subject shown on the display device. In all types of representation of the surface, it can be shown in an advantageous manner together with regions to be examined (in particular slices) inside the examination subject.

The display, device, moreover offers the possibility to display an image or a representation of a surgical instrument simultaneously with a volume, section and/or surface representation of the examination subject. The images acquired by means of the imaging diagnosis unit as well as by means of the optical image acquisition sensor can then be used for navigation purposes in medical inventions.

In a preferred embodiment, a CMOS sensor that interacts with a pulsed laser beam as a light source is provided as the optical image acquisition sensor. The CMOS sensor acquires information from a number of individual light flashes. Independent of the embodiment of the image acquisition sensor, it is supported or mounted in a spatially variable manner (in particular pivotable relative to the examination subject) in the imaging apparatus.

An advantage of the invention is the dose reduction that is achieved in computed tomography examinations, this dose reduction being achieved by the combination of optical light methods for shape recognition with x-ray methods.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A gantry2that is rotatable around an axis perpendicular to the plane of the drawing is shown inFIG. 1in a schematic section. The gantry is a component of an imaging apparatus1, namely a computed tomography apparatus. A patient bed3on which the patient4is located is arranged within the circular cross-section of the gantry2. The space within the cross-section of the gantry2above the patient bed3, in which space the patient4is located, is designated as examination space5. For optical monitoring of this examination space5, a CMOS sensor is provided as an optical image acquisition sensor6that occupies a position defined relative to the gantry2as well as relative to the patient bed3and can be pivoted around the cited axis of the gantry2such that, for example, a 0° position (also designated as a 12:00 position), a +90° position (3:00 position) and a −90° position (9:00 position) can be set.

The image acquisition sensor6enables at least one portion of the surface of the examination subject (thus of the patient5to be examined) to be shown on a screen as a display device7. The screen of the display device7is linked with an evaluation unit8which is embodied in a data processing system used for operation of the imaging apparatus1. Both the image acquisition sensor6, and an x-ray source9as well as an x-ray detector10that form an image data acquisition unit11, are attached to the evaluation unit8.

The evaluation unit8is designed (in particular in terms of software) such that a surface data acquired by the image acquisition sensor6can be used as control information for control of the image data acquisition unit. As used herein, “control” means any influencing of the operation of the image data acquisition unit. In particular the positioning and movement of the x-ray source9relative to the patient bed3is included as such control. In computed tomography examination of the patient4the patient bed3and/or one or more components9,10of the image data acquisition unit can be moved. The computed tomography examination can be a spiral computed tomography examination.

In each case data that have been acquired with the aid of the optical image acquisition sensor6can be used for planning the computed tomography examination. According to the workflow of the preparation (shown simplified in FIG.2) of an examination to be implemented with the imaging apparatus1, a surface exposure of the appertaining region of the examination subject4is created with the image acquisition sensor6in a first step S1. In the next step S2, data acquired in the first step S1are linked with further data relevant for the examination (in particular with patient data PD) in order to create an examination protocol UP based on this, according to which examination protocol UP the computed tomography examination is implemented with the apparatus1. Data acquired in the step S1are thereby automatically adopted into the examination protocol UP by means of the evaluation unit8, which can also be realized in the form of a networked computer system.

The optical image acquisition sensor6enables a generation of three-dimensional surface data in cooperation with a light source12(such as a pulsed laser) which can also be integrated into the image acquisition sensor6.FIG. 3shows an example of a three-dimensional representation that can be generated by means of the image acquisition sensor6. For illustration of the wide-ranging possibilities of the spatial representation, inFIG. 3the patient4is shown sifting while in the imaging apparatus1he is typically located in a recumbent position.

The laser radiator12emits light pulses with a duration of less than 30 nanoseconds in the direction of the patient4. Reflections of these pulses are acquired by the image acquisition sensor6(which has a semiconductor array of, for example, 1000 pixels). The diaphragm of the image acquisition sensor6is realized electronically and exhibits a suitably high switching frequency. The light intensity of individual pixels thus is detected, with which light intensity the distance of the appertaining subject points (meaning points on the surface o the examination subject4) is detected. The image of the patient4shown inFIG. 3is generated in real time with this measurement data by software in the evaluation unit8. On the screen7, the operator of the imaging apparatus1thus can track any variation of the positioning of the patient4relative to the image acquisition sensor6.

The operator furthermore has the possibility to shift, zoom or manipulate in another manner the representation of a surface region of the patient4that is visible on the screen7.

A memory13, which can be part of the evaluation unit8, is provided for storage of data, such as data that can be processed by the evaluation unit8. This memory13enables the correlated storage of information determined with the image acquisition sensor6, which information pertains to the surface of the examination subject6, and information that has been acquired by the image data acquisition unit. This logically-linked storage of information acquired by means of optical light together with information acquired by computed tomography is also usable for further purposes, for example navigation purposes in medical interventions.

The acquisition of a surface of the examination subject4by the image acquisition sensor6integrated into the imaging apparatus1is in particular advantageous for routine applications in which conclusions about the position of internal structures of the examination subject4to be examined, which conclusions are sufficient for a computed tomography examination, can be made from the position of the acquired surface. The image acquisition sensor6(which can also be composed of a number of individual sensors) is suitable in an advantageous manner for implementation of video raster stereography (VRS) that, without any exposure with x-ray radiation, is based solely on surface information determined by optical light so as to substitute for a portion of the radiographic examination.

Application cases that pertain to orthopedic questions are illustrated inFIGS. 4 and 5, in these cases a surface grid shows a foot (FIG. 4) or a knee (FIG. 5) of the patient4. In both cases the surface images acquired with the image acquisition sensor6are sufficient for the planning of a computed tomography examination, in particular for definition of slices (as shown inFIGS. 4 and 5) and/or of the examination volume. This also applies for the planning of a spiral CT examination.