DE102008033761A1 - Medical imaging diagnostic system, particularly angiographic X-ray device, has examination table for supporting and examining patient and impedance sensors are integrated in medical imaging diagnostic system - Google Patents

Abstract

The medical imaging diagnostic system has an examination table (14) for supporting and examining a patient. Impedance sensors are integrated in the medical imaging diagnostic system for contact free measurement of load changes in the body of the patient. Capacitive sensors (15) are provided as impedance sensors. The impedance sensors are structurally integrated into the bearing surface (21) of the examination table in such a manner that the impedance sensors form a common surface with the bearing surface.

Description

The The invention relates to a medical imaging diagnostic system according to claim 1.

at the use of medical imaging diagnostic systems such as for example X-ray machines, computer tomographs or ultrasound devices, it is often necessary and reasonable, electrical potentials, currents or voltages of the body of a patient to be examined, for example, to carry out an electrocardiogram (EKG). For the measurement of electrical potentials is It has been imperative to have a senior connection between the body of the patient and a galvanic sensor, usually with a metal electrode. For the quality Above all, the resistance of the contact point plays a role in the measurement the body and the electrode an essential role.

Around To keep the resistance as low as possible, the skin the patient often treated with electrolytes and then the galvanic sensor applied. It can also be used for Avoiding the use of electrolytes special suction electrons be used. For both methods, however, is a direct galvanic contact to the skin of the patient unavoidable. For this must be at least the corresponding body region of the patient be undressed. On the one hand, this means a relevant intervention into the privacy of the patient and on the other hand arise thereby also hygienic problems. In addition, the require Preparation of the patient, undressing, a possible shave the corresponding body site and the application of the electrolytes and the electrodes a considerable amount of time.

In addition to conventional galvanic sensors exist today impedance sensors and in particular so-called capacitive sensors with which electrical potentials can also be recorded without contact. Such capacitive sensors do not measure by means of a galvanic contact but by means of charge changes on the surface of the skin. These charge changes are caused by displacement currents, which in turn are caused by the potential changes in the heartbeat. By doing Article "Comparison of Capacitive ECG with conventional ECG" by Martin Oehler, Andre Riggert, Frank Ludwig, Meinhard Schilling, Benjamin Blankertz, Klaus-Robert Müller, Volker Kunzmann, Gabriel Curio from the journal Biomedical Engineering, Volume 51, 2006 , corresponding capacitive sensors are described.

It The object of the present invention is a medical imaging Provide diagnostic system, which provides a fast and hygienic detection the heart signal of a patient allows.

The The object is achieved by a medical imaging diagnostic system according to the Claim 1; advantageous embodiments of the invention are each subject of the dependent claims.

at the inventive medical imaging Diagnostic system with an examination table for storage and examination of a patient, is through the integrated into the diagnostic system, at least one impedance sensor and in particular a capacitive sensor a non-contact and therefore hygienic measurement of charge changes on the body surface the patient possible, which in turn makes a special achieved fast and easy determination of the human heart signal can be.

The Measurement does not mean interference with the privacy of the person Patients, resulting in certain religious Culture is a big advantage. The patient can keep parts of his clothes on request, which in turn is a Time saving means no elaborate individual Preparation of the contact points and the measurement is necessary. The application of electrolytes or suction electrodes leading to skin irritation can lead the patient is avoided. Also a shave of the skin is not necessary. Overall, the hygiene of the improved overall examination and the number of hygiene-relevant Parts are reduced as there are no contacts or cables directly to the patient must be attached.

Especially the structural integration of the impedance sensor or the impedance sensors in the examination table leads to a significant improvement the examination procedure, as the patient is only on the examination table must be positioned accordingly and so directly a measurement and thus a determination of the heart signal can be made. The necessary Proximity of the impedance sensors to the body of the patient and minimizing movement between the sensor and the body are automatically created by positioning the patient. In addition, the impedance sensors can save costs be, because impedance sensors by the non-contact measurement do not represent consumables, but often reused can be.

According to one embodiment of the invention, the impedance sensor is integrated into the support surface of the examination table such that the impedance sensor forms a common abutment with the support surface closed surface forms. This increases patient comfort by not feeling the sensors and thus not feeling uncomfortable.

In advantageous for a particularly simple positioning of the patient and thus a particularly smooth examination procedure is the impedance sensor in the area of the upper body provided by the patient support surface in the examination table integrated.

To A further embodiment of the invention is at least one impedance sensor structurally in a resting mat on the examination table integrated.

In an advantageous development, the diagnostic system of a Angiography X-ray machine or a computed tomography device or a magnetic resonance device or an ultrasound device or a nuclear medicine device. In such Diagnostic systems are often a determination of the heart signal important for improved imaging, for example at the presentation of longer lasting image sequences or for triggering recordings at specific times during the heart cycle.

advantageously, for a particularly reliable and accurate measurement a plurality of impedance sensors are provided.

To Another embodiment of the invention is the impedance sensor with an evaluation unit for determining a cardiac signal, in particular a Electrocardiogram, the patient from the measured electric Charge change, connected. Such an evaluation unit, in particular an ECG device, determined quickly and reliably from the data of the impedance sensor or the corresponding heart signal and thus contributes to an improved diagnosis of the patient at.

In Advantageously, the detected heart signal is used to control used by the diagnostic system. For example, triggering the image recording after the heart signal a useful application for Improve the diagnosis of a patient.

The Invention and further advantageous embodiments according to features The dependent claims are described below with reference to schematically illustrated embodiments explained in more detail in the drawing, without thereby limiting the invention to these Embodiments takes place; show it:

1 a view of a medical diagnostic imaging system according to the invention with integrated capacitive sensors;

2 a side view of a study table with structurally integrated capacitive sensors;

3 a schematic structure of a capacitive sensor according to the prior art.

In the 1 is an inventive diagnostic system in the form of an angiographic X-ray machine 10 with an examination table 14 shown for storage of a patient. The X-ray machine 10 includes a C-arm 11 at which an X-ray source 12 for emitting an X-ray and an X-ray detector 13 are arranged for receiving an X-ray image. In the support surface 21 of the examination table 14 are several impedance sensors in the form of capacitive sensors 15 structurally integrated. The capacitive sensors 15 are in the area of the bearing surface 21 arranged on which the upper body of the patient is usually stored.

In particular, the capacitive sensors 15 so in the bearing surface 21 of the examination table 14 let in that the capacitive sensors 15 with the surface of the support surface 21 forming a common closed surface - as in 2 shown. In this way, the capacitive sensors 15 from one on the support surface 21 positioned patients did not feel distracting. Will the patient on the examination table 14 it is important to note that the upper body and in particular the area of the heart above the capacitive sensors 15 is stored. Undressing the patient and other preparations are not necessary in the diagnostic system according to the invention.

through The capacitive sensors will charge changes on the Surface of the patient's skin contactless measured. The charge changes are due to shift currents which causes their cause in the electrical potential changes to have at heart.

The capacitive sensors 15 are conductive to the signal inputs of an ECG device 19 connected. The cables can be inside the examination table 14 and / or outside in the form of cables. The measurement data on the charge changes on the surface of the patient's skin, are then taken from the ECG device 19 evaluated and converted into cardiac signals and in particular electrocardiograms. The heart signals can subsequently be used to trigger the x-ray device 10 continue to be used. This is a communication connection between the ECG device 19 and one the X-ray machine 10 controlling system control 16 intended. In this context, for example, a triggering of the recording of X-ray images to certain phases of the heart signal may be provided.

The X-ray machine 10 also has an image system 17 for processing and evaluation of X-ray images. Furthermore, the recorded X-ray images on a display units 18 are displayed.

In the 3 is an example of a capacitive sensor 15 shown. The capacitive sensor 15 has a metal electrode 22 on, which towards the patient by means of a plastic layer 23 is isolated. The plastic layer 23 is the side of the sensor, which is oriented in the direction of the patient. In the in the 2 example shown thus includes the plastic layer 23 flush with the surface of the support surface 21 from.

The on the metal electrode 22 Influenzierten electrical charges are by means of a signal processing unit 24 , which also in the capacitive sensor 15 integrated, detected and filtered. To minimize the influence of disturbances, the metal electrode is 22 through different protection circuits 25 and protective layers 26 shielded.

Next An X-ray machine, the invention also in a CT, an MR, an ultrasound machine, a PET or be integrated into a SPECT.

As described above, the impedance sensors can be used as capacitive sensors ( 15 ), but it can also be used inductive sensors.

The The invention can be briefly summarized in the following way: For an improved examination procedure is a medical Imaging diagnostic system with an examination table for storage and examination of a patient, wherein at least one capacitive Sensor for non-contact measurement of charge changes of the patient's body structurally into the imaging diagnostic system and in particular integrated into the examination table.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - Article "Comparison of CAPACITIVE ECG with conventional ECG" by Martin Oehler, Andre Riggert, Frank Ludwig, Meinhard Schilling, Benjamin Blankertz, Klaus-Robert Müller, Volker Kunzmann, Gabriel Curio from the journal Biomedical Engineering, Volume 51, 2006 [0004]

Claims (10)

Medical imaging diagnostic system with an examination table ( 14 ) for storage and examination of a patient, wherein at least one impedance sensor for non-contact measurement of changes in charge of the body of the patient is structurally integrated into the imaging diagnostic system. A medical imaging diagnostic system according to claim 1, wherein as impedance sensor a capacitive sensor ( 15 ) is provided. A medical imaging diagnostic system according to claim 1 or 2, wherein at least one impedance sensor is structurally incorporated into the examination table (10). 14 ) is integrated. A medical imaging diagnostic system according to claim 3, wherein the impedance sensor is so mounted in the bearing surface (Fig. 21 ) of the examination table ( 14 ) is integrated, that the impedance sensor with the support surface forms a common closed surface. A medical imaging diagnostic system according to claim 3, wherein the impedance sensor in the area provided for the upper body of the patient support surface ( 21 ) in the examination table ( 14 ) is integrated. Medical diagnostic imaging system according to one of the preceding claims, wherein at least one impedance sensor is structurally placed in one of the examination table ( 14 ) auflegbare pad is integrated. A medical imaging diagnostic system according to any one of the preceding claims, wherein the diagnostic system is from an angiographic x-ray machine ( 10 ) or a computed tomography device or a magnetic resonance device or an ultrasound device or a nuclear medicine device. Medical imaging diagnostic system after one of the preceding claims, wherein a plurality of impedance sensors are provided. Medical imaging diagnostic system after one of the preceding claims, wherein the impedance sensor with an evaluation unit for determining a cardiac signal, in particular an electrocardiogram, the patient from the measured electrical Charge change is connected. Medical Imaging Diagnostic System claim 9, wherein the heart signal used to control the diagnostic system becomes.