DE8909245U1 - Cable routing for an adjustable patient table - Google Patents

Description

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Siemens AG GR 89 G 3377 DE

Medical device with a cable guide to an adjustable patient table

A cable guide for an adjustable patient support table of an MRI scanner is known, for example, from DE-GM 84 13 651. The cables lead from a stationary part to plug-in devices provided on one side of the patient support table. Some plug-in devices are used to connect transmitting and receiving coils that are used to measure the magnetic resonance signals, for example in the head area of a patient. Other plug-in devices are provided for connecting a headset, EXG electrodes, breathing measuring devices, pulsinometer devices, etc. So that the patient support table can be adjusted to the magnet of the MRI scanner, the cables are led in a loop from the stationary part of the device to the patient support table.

The invention is to improve the protection of cables in cable routing.

The object is achieved according to the invention in a medical device with a cable guide to an adjustable patient support table in that the cable guide takes up the cables as an articulated hollow body and the cable guide forms a loop between the patient support table and a fixed part of the device, the length of which is dimensioned such that one end of the cable guide can be adjusted with the patient support table along the adjustment path of the patient support table.

The invention ensures that the cables are defined by the hollow body and can be routed from the stationary device part to the adjustable patient table without additional guidance.

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Any unacceptable bending stress and the resulting destruction of the cable is counteracted by the sheathing with the articulated hollow body.

Further advantages and details of the invention will become apparent from the following description based on the figures.

Fig. 1 shows a schematic representation of a patient support device in connection with a magnetic resonance imaging scanner.

Fig. 2 shows a view of a patient support table of the

Patient support device according to Fig. 1 »on top. Fig. 3 shows a cable guide according to the invention in the ^; ) Device according to figures 1 and 2.

Fig. 4 shows schematically the structure of the cable routing according to Figure 3.

Figure 1 shows the magnet 1 of a magnetic resonance imaging device, which is attached to the floor of the treatment room. The examination of a patient 2 is carried out by inserting this patient 2 into the cylindrical space 5 formed by the magnet 1 using the patient support table 3 of a patient support device 4. Figure 1 shows a coil 6 which is used to excite the hydrogen nuclei in a predetermined area of the patient 2, namely in the area of the head. For this purpose, the coil 6 is pushed onto the head of the patient 2 and the patient is then pushed into the space 5 on the patient support table 3. The hydrogen nuclei in the patient 2 are aligned by the magnet 1 and deflected by a high-frequency pulse in the coil 6. The coil 6 is also used to detect the back swing of the hydrogen nuclei, so that an image of the examined layer of the patient 2 can be calculated from the measured signals.

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From Figure 1 it can be seen that the patient support table 3 carries plug-in devices A, B, C and D, to which, for example, the coil 6 and other signal transmission devices can be connected via cables.
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The plug device A, which is shown hidden, is used to connect the head coil 6 or a special coil 7, the plug device B is used to connect headphones, the plug device C is used to connect ECG electrodes, breathing measuring devices, pulse measuring devices, etc. and the plug device D is used to connect a hand switch.

Figure 2 shows the patient support table 3 in plan view. It shows that the plug device A is arranged on one side X and the plug devices B, C and D on one side Y of the patient support table 3. The plug devices A, B, C and D are arranged on the patient support table 3 in such a way that the cable connections to the patient can be kept as straight as possible, i.e. they lead as directly as possible to the coil 6 or 7 or to measuring points 8, 9 for recording the physiological signals. This keeps the transmission of interference signals, which can arise, for example, when controlling the gradient coils, to these cable connections as low as possible. In addition, the cable connections then only have a slight influence on the magnetic fields inside the cylindrical space 5.

Figure 2 shows that the plug device A has several plug devices Al, A2, A3, A4, A5, which are intended for connecting the coils 6 and 7. All plug devices Al to A5 are connected to one another by a cable 11, which is hidden on the patient support table 3.

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Figure 2 further shows that at the measuring points 8 of the

Three electrodes are placed on the patient for taking an ECG, whereby ¹ ^Ie cables of the electrodes are led to the plug-in device C2, and a pulse sensor can be connected to the plug-in device C3. The cable of a respiratory probe 9 leads to the plug-in device C1. A pneumatic hand switch 10 is connected to the plug-in device D via a cable and is used to manually trigger the control processes. Cables 12 lead to the plug-in devices B, C, D, which are also hidden on the patient support table 3. The separate routing of the cables and 12 on the patient support table 3 prevents the signals in the cables 11, 12 from influencing each other.

Advantageously, the plug-in devices A, B, C and D are mounted on the side and on the top of the patient support table 4 and are adjustable along its longitudinal axis. For this purpose, the plug-in devices A, B, C and D can be arranged, for example, on plug-in trolleys 25 that are guided on rails and can thus be moved into the area of the signal pickup on the patient with optimal adjustment, i.e. with the shortest possible cable connection.

Figure 3 shows a schematic side view of the patient support device 4 with a cable guide according to the invention. The cables 11 are surrounded by a cable guide formed by an articulated casing 13 with a square cross-section. One end of the cable guide is attached to a carriage 15 at a point 14. The carriage 15 carries the patient support table 3, which is not shown in Figure 3 for the sake of clarity. The carriage 15 can be moved from the fully extended position to the position shown in dot-dash lines. The cable 11 forms a loop with the casing 13, which loops under the patient support table 3 when the carriage 15 is moved in the direction of the arrow 16.

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freely and, due to the cross-section of the casing 13, without guidance. The loop is dimensioned so that the patient support table 3 can be adjusted in height relative to the

5 stationary device part 18. The cables 11 are guided through an opening 17 into the stationary device part 18. The cables 12 are also sheathed and are guided on the side X of the patient table 3 in the same way as the cables 11.

Figure 4 shows an example of a sheath 13 for the cables 11, 12. The sheath 13 is formed as a hollow body of chain-shaped segments 19, which are made of plastic and have a square cross-section. The individual segments 19 are connected to one another by joints formed by pins 20 and holes 21. By appropriately designing the segments 19, the pivoting range can be adjusted around the joint axis 22. Advantageously, the pivoting range is dimensioned such that the cables 11, 12 are guided in a sufficient curve in the area 23 of the loop (see Fig. 3). The cables 11, 12 are thus protected from impermissible bending stress, which can lead to damage to the cables 11, 12. The cables 11, 12 can be inserted into the hollow body via a foldable bracket 24 on the segments 19. To close the hollow body, the brackets 24 are folded over so that they snap into place on the segments and close them.

The cable guide according to the invention can of course not only be used in an MRI scanner, it can be used anywhere where a patient support table is to be set up against a stationary device table in a medical device, for example in computer tomographs or radiotherapy devices.

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Claims (7)

GR 89 Protection claims 1. Medical device with a cable guide to an adjustable patient support table (3), the cable guide as an articulated hollow body receiving the cables (11, 12), the cable guide forming a loop between the patient support table (3) and a fixed device part (18), the length of which is dimensioned such that one end (14) of the cable guide can be adjusted with the patient support table (3) along the adjustment path of the patient support table (3). 2. Medical device according to claim 1, wherein the hollow body has a square cross-section, wherein the hollow body is constructed from individual chain segments (19) and wherein the chain segments (19) are pivotable about an axis (22) transverse to the longitudinal axis of the cable guide. 3. Medical device according to claim 1 or 2, wherein the cable guide to a patient support table (3) of a magnetic resonance imaging. 4. Medical device according to claim 1 or 2, wherein the cable guide leads to a patient support table (3) of an X-ray diagnostic device, in particular a computer tomograph. 5. Medical device according to claim 1 or 2, wherein the cable guide leads to a patient support table (3) of a radiotherapy device. 6. Medical device according to claim 1, 2 or 3, wherein cables (11) on one side (X) of the patient support table (3) are concealed to a connection (A) and wherein other cables (12) on a side (Y) of the patient support table (3) opposite the side (X) are also concealed to further connections (B, C, D). &#10* JUS* ■: :^:.i":Ci.: ^:: :C: .: * *..· ..* *..· ..' GR 89 G 3377 EN 1 7. Medical device according to one of claims 1 to 6, wherein a plug-in device (A, B, C, D) is attached to a plug-in carriage (25) y that can be adjusted in the longitudinal direction of the patient support table (4). jf 5 &eegr;