WO2000006021A1

WO2000006021A1 - Three-dimensional vertebral column measuring device

Info

Publication number: WO2000006021A1
Application number: PCT/DE1999/002270
Authority: WO
Inventors: Mubr. Miroslar Kucera
Original assignee: Allstuff Computervertriebs Gmbh
Priority date: 1998-07-27
Filing date: 1999-07-27
Publication date: 2000-02-10
Also published as: DE19833568A1; DE19981414D2

Abstract

Using a device for quantitative measurement of the position of the vertebral column in the human body, the explicit position is determined by scanning the individual vertebral bodies and detecting the spatial coordinates x, y and z. Two vertical guide rails (1, 1') are provided, the ends of which are fixed to a bottom plate (10). Both guide rails (1, 1') are spaced in relation to each other, the distance being slightly bigger than the width of the human body. A horizontal support element (3) is disposed between the guide rails (1, 1') which may be displaced continuously in vertical direction and locked. Moreover, a palpation element (4) is indirectly disposed on the support element (3). Coordinates (x, y, z) of the palpation element (4) are read either analogically by means of a measuring scale or digitally by transmitting the measured data to a computer that graphically displays the individual data.

Description

Description of the 3D spine measuring device

The invention relates to a device for generating measured values based on the spatial coordinates (x, y, z) of a spine in the human body, consisting essentially of

- a frame with two vertical guide rails,

a base plate from which the vertical guide rails extend,

- and a system for recording and evaluating the determined measured values.

The above devices are used in particular for the treatment of scoliosis. Scoliosis is defined as a fixed partial curvature of a spine that is only capable of regression in the initial stage, but is later fixed. In addition to this side curvature, especially in another type of scoliosis, there is a flat back or even a hollow back in the area of the main curvature as well as a rotational component of the individual parts of the spine against each other, which is responsible for the rib hump and the lumbar bulge of the human body are.

There are various treatment methods for scoliosis treatment, which also include physiotherapy. Targeted therapeutic treatments can help to alleviate and improve therapeutic measures, particularly in the growth phases of young patients. In order to see the corresponding success of the therapeutic treatments, a great deal of experience is required to determine the actual position of the spine in the human body and then to apply the corresponding therapeutic measures.

A device for monitoring such therapeutic measures is known from the publication DE-OS 43 20 270. This device described here is used to measure and analyze malpositions of the human body in order to develop appropriate treatment methods and to be able to monitor their success accordingly. This device comprises a frame which has two vertical guide rails parallel to one another. To detect the position of selected reference points on the patient's bone structure, in particular the individual vertebral bodies of the spine, at least one probe arm is mounted on each side of the guide rails. The patient enters the device to determine and analyze the incorrect posture, the individual load on the individual legs being recorded by means of two weighing plates and, together with the measurement of the height differences of the individual legs, thereby making it possible to draw quantitative conclusions about the patient's incorrect posture. The probe arms are used to create a correct posture of the body so that it can be reproduced accordingly.

Furthermore, EP-A 0144 528 provides a device for measuring incorrect posture of the pelvis, shoulder and spine of the human body. This invention is a device for measuring a functional and / or anatomical incorrect posture, for example of the spine of the human body, the device being two vertical guide rails at a distance of more than a body width. At least one height-displaceable, lockable holder runs on the guide rails, the height position of which can be determined quantitatively. The brackets themselves serve to accommodate horizontally displaceable and lockable probe elements that protrude horizontally into the space between the guides. These feeler elements can be spring-loaded in the longitudinal direction and pivotable in the horizontal - these movements also being quantitatively detectable - and serve to scan selected reference points of the skeleton. In addition, the device for immobilizing the body and for achieving defined basic positions can be provided with support and holding means.

Essentially, the entire incorrect posture of the body is measured in this device, from which ultimately conclusions can then be drawn about the position of the spine.

The object of the invention is to provide a very simple device for the quantitative measurement of the position of the spine in the human body, the measurement being very easy to carry out and the measurement values being evaluated in the simplest way.

The solution principle of the task consists in modifying or improving the device according to the state of the art in that the entire incorrect posture of the body is not measured quantitatively, but the explicit position of the spine by scanning the individual vertebral bodies and acquiring the spatial coordinates x, y and z. According to the invention, the object is achieved in that

a probe element is provided for scanning the spine, in particular the individual vertebral bodies of the spine and for generating at least one measured value,

- A horizontal support element with its two ends is mounted on the guide rails so as to be steplessly vertically displaceable and lockable, and

- On the horizontal support element, the touch element is mounted in the horizontal plane (x, y) in a continuously sliding and lockable manner.

The main advantage of the inventive device is the fact that it is a very simple and therefore very inexpensive construction. Basically, only commercially available components are used, so that the device can ultimately also be manufactured as a modular system.

Two versions are advantageously provided. On the one hand, the quantitatively determined measured values (x, y, z coordinate of a vertebral body) can be read off on a measuring scale or on an electronic display on the device itself. Another embodiment provides that the measured values generated are transmitted to a computer via a data interface, which then acquires the corresponding measured values, evaluates them and, for example, displays them graphically on the screen. In addition, it can be provided that an ideal spine is then displayed for the spine shown on the screen, so that deviations from the ideal dimension are visible in a simple manner.

For simple measurement of the position of the individual vertebral bodies in the human body, a probe element is arranged on the horizontal support element of the device in a continuously sliding and lockable manner. The probe element itself is used to record the individual measured values. This is preferably done in that the probe element consists of a push button, an adapter element and a base body, the push button of the push button element emitting a signal when tapping a vertebral body, which is provided for the coordinates x, y, z to be determined accordingly are. The next vertebral body can then be scanned immediately.

The sensing element itself is in turn mounted on a holder which is slidably arranged on the guide rails.

The button itself can be designed as an electromechanical sensor or as an optical sensor, an ultrasonic sensor also being conceivable.

The bearings of the individual guide rails or the bearings are designed in such a way that they have a corresponding coefficient of friction, so that a comfortable guidance of the feeler element by the hand of a doctor, for example, is possible accordingly. However, it is also conceivable that the guidance can be carried out by means of servomotors, the control being controllable, for example, by means of a joystick. Alternatively, it can also be provided that the probe element is positioned on the carrier element by means of a rack and pinion gear. The carrier element itself should preferably be adjustable via friction guides.

For the creation and triggering of a measured value, it is proposed that the pushbutton of the pushbutton element be of electro-mechanical design. This means that when approaching the vertebral body and exerting a slight pressure on the vertebral body using the feeler element, comparable to a known electronic measuring device, a measurement result is generated in which the positions of the displacement sensors attached to the respective guides are recorded and output.

The measurement results are preferably output digitally. In the case of analog position sensors, it is intended to use a corresponding analog-digital converter.

With the device according to the invention, a corresponding “image” of the spine can thus be created in a simple manner by any person, including assistants, it being possible to use the evaluation technique provided here to graphically depict differences from the ideal position of a spine the problem can also be described to the patient in a simple and obvious manner.

The invention is explained in more detail below in exemplary embodiments with reference to the drawings. Show it :

1 is a perspective view of the device according to the invention, showing the x, y, z axes;

Figure 2 is a side view of an embodiment of a probe element together with a holder, partially in section.

Fig. 3 is a front view of the embodiment of the probe element acc. Fig. 2;

4 shows a block diagram of a possible system configuration for recording and evaluating measured values.

In the embodiment shown in FIG. 1, two vertical guide rails 1, 1 'are provided, which are fastened with their one end to a base plate 10 and extend away from this base plate. These guide rails 1, 1 'also form the z-axis shown in FIG. 1. The two guide rails 1, 1 'are at a distance from one another which is a little larger than the width of a human body.

A horizontal support element 3 is arranged between the guide rails 1, 1 'and can be moved and locked in a stepless vertical manner. The bearings between the horizontal support element 3 and the guide rails 1, 1 'are not shown in FIG. 1. These bearings are designed in such a way that they have a corresponding coefficient of friction, so that the user who wants to move the carrier element 3 on the vertical guide rails 1, 1 ′ against a defined angle the state has to work.

In the exemplary embodiment shown in FIG. 1, the guides are clad in a housing, the housing itself, at least in the region of the spine of the patient, not shown here, having a recess in which a sensing element 4, which is displaceably mounted on the carrier element 3, is free can be moved back and forth.

In the exemplary embodiment shown in FIG. 1, the pushbutton element 4 is arranged on a holder 5, which in turn is coupled to the carrier element 3. A measuring scale 19 is shown on the carrier element itself, which indicates the deviations from the center point, for example in centimeters (x-axis). The horizontal displacement in the y-axis of the probe element 4 can be read on a measuring scale arranged on the probe element 4 itself.

In order to stabilize the position of the human body, in which the position of the spine is to be measured, and also to produce reproducible results, three contact surfaces 13, 14, 15 are preferably provided, which can be freely moved in the z direction. This ensures that the body is erected accordingly by stretching the breastbone upwards and comes to rest on these contact surfaces.

In order to further increase the reproducibility, positioning elements 11, 12 are additionally provided on the base plate 10, which accordingly align and partially fix the position of the feet. A measuring scale 18 is provided in the recess of the housing to determine the high value, also based on a defined zero point.

2 and 3 show a side or front view of a possible embodiment of the probe element 4 for scanning individual vertebral bodies of the spine to be measured and for generating at least one measured value. The feeler element 4 is slidably received in a holder 5, which enables a linear movement of the feeler element 4 in the y-axis (movement perpendicular to the patient's back). The feeler element 4 is provided with a toothed rack in which a manually operated gearwheel engages, for example via a handwheel 7c. The holder 5 is slidably mounted on the horizontal support element 3, so that a linear movement of the feeler element 4 m in the x direction (lateral movement) is possible. In this possible embodiment of the feeler element, the horizontal movement takes place manually, for example by holding and moving the support element 3.

The pushbutton element 4, as shown in FIG. 3, has at one end a pushbutton 4a and an adapter element 4b, which creates a connection between the pushbutton 4a and a basic body 4c. The basic body 4c is mounted in the holder 5, as described above. The button 4a is used to precisely determine and locate the position of the vertebral bodies and to trigger the determination of the respective measured values. It is conceivable that the button 4a is designed such that when a certain contact pressure is reached, an electrical signal is triggered which serves to control a possible electric drive for moving the button element 4. The signal could also be used to trigger an automatic measuring process, with all three position sensors, such as they are shown in Fig. 4 (23, 24, 25), are queried and recorded by a connected computer 27 at this time.

In another embodiment of the device according to the invention, it is provided that the probe element 4 is equipped with a light source for aiming at a measuring point in order to facilitate adjustment of the probe 4a. For this purpose, it is then provided that an additional push button switch triggers the corresponding output of the measured values.

In all embodiments of the invention, the position of the button 4a or the vertebral body to be measured can be detected electronically in three axes by means of a path length measurement. The functional sequence of a measurement for actually determining the position of a spine in the human body can look as follows in the exemplary embodiment described.

A patient whose spine is to be analyzed stands upright on the base plate 10 and presses his back against the frame and against the contact surfaces 13, 14, 15 by pushing up his breastbone. At the same time, he presses his feet closely against the positioning element 11, 12. As soon as the patient's posture is correctly aligned, the operator of the measuring device can manually attach the tip of the sensing element 4 (button 4a) to the first vertebral body to be measured and either read the measured values from the three measuring scales 18, 19, 20 or, if electronic displacement sensors are provided, view the measured values on the display or on a PC, as shown in the block diagram in FIG. 4. The measuring process is triggered by gently pressing the button 4a against the vertebral body. Once the measurement is done this can be indicated by an acoustic signal, the user holding the button in his hand can drive to the next vertebral body and then carry out the measurement there in the same way. This process is repeated until the desired number of vertebral bodies has been measured. The actual position of the spine can then be viewed on a monitor, for example to compare an ideal spine.

B e z u g s z e i c h e n

1. Vertical guide rails

2. - 3. horizontal support element 4. feeler element 4a. Button 4b. Adapter element 4c. Basic body 5. Bracket

6.-

7. Manually operated rack drive 7a. Rack

7b. Gear 7c. handwheel

8th. -

9.-

10. Base plate

11. Positioning element (on the heels) 12. Positioning element (between the feet)

13. Contact surface (hip)

14. Contact surface (shoulder blades)

15. Contact surface (head)

16. Vertical guidance (height measurement system) 17. Measurement arm (height measurement system)

18. Visual measuring system (z-coordinate of the vertebrae) 18a. Measuring scale

18b. pointer

19. Visual measuring system (x coordinate of the vertebrae) 19a. Measuring scale

19b. pointer 20. Visual measuring system (y-coordinate of the vertebrae) 20a. Measuring scale

20b. pointer

21. Measuring scale (height measurement system) 22. Pointer (height measurement system)

23. Electronic displacement sensor (x coordinate of the vertebral bodies)

24. Electronic position sensor (y coordinate of the vertebral bodies)

25. Electronic displacement sensor (z-coordinate of the vertebrae)

26. Screen 27. Computer

28. Keyboard

29. Printer

30. Evaluation system

Claims

EXPECTATIONS

1. Device for generating measured values, based on the spatial coordination (x, y, z) of a spine in the body of a patient, consisting essentially of

- a frame with two vertical guide rails d, l ')

- a base plate (10) from which the vertical guide rails (1, 1 ') extend,

- a system for recording and evaluating the measured values,

characterized in that

one for scanning the spine, in particular the individual vertebral bodies of the spine, and for generating at least one measured value

Probe element (4) is provided,

- A horizontal support element (3) with its two ends on the guide rails (1, 1 ') is vertically displaceable and lockable and is mounted

- On the horizontal support element (3), the feeler element (4) is mounted in the horizontal plane (x, y) in a continuously sliding and lockable manner.

Apparatus according to claim 1, characterized in that the sensing element (4) consists of a button (4a), an adapter element (4b) and a base body (4c), wherein the adapter element (4b) is arranged between the button (4a) and the vertebral body.

3. Apparatus according to claim 2, characterized in that a. Holder (5) for continuously sliding and lockable receiving the base body (4c) is provided.

4. The device according to claim 3, characterized in that the holder (5) is designed as a continuously sliding and lockable connection between the carrier element (3) and the base body (4c).

5. The device according to claim 2, characterized in that the button (4a) is designed as an electromechanical sensor.

6. The device according to claim 2, characterized in that the button (4a) is designed as an optical sensor.

7. The device according to claim 2, characterized in that the button (4a) is designed as an ultrasonic sensor.

8. The device according to claim 1, characterized in that on the carrier element (3) is a manually operated rack and pinion drive (7) consisting of a rack (7a), a gear (7b) and a handwheel (7c) is provided, wherein the handwheel (7c) is coupled to the gearwheel (7b) and the feeler element (4) is arranged on part of the rack and pinion drive (7) in such a way that the feeler element (7) can be moved in the Y-axis direction.

9. The device according to claim 8, characterized in that a motor drive for the continuous movement of the Tastele- elements (4) is provided in the y-axis direction.

10. The device according to claim 3, characterized in that a motor drive is provided for the stepless movement of the feeler element (4) in the x-axis direction.

11. The device according to claim 1, characterized in that a motor drive for the continuous movement of the horizontal support element (3) is provided in the z-axis direction.

12. The device according to claim 1, characterized in that a visual measuring system (18,19,20), consisting of a measuring scale (18a, 19a, 20a) and a pointer (18b, 19b, 20b) for reading the The x, y and z coordinates of the measured vertebral body are provided.

13. The apparatus according to claim 1, characterized in that one or more electronic displacement sensors (23, 24, 25) is provided for detecting the actual position of the push button (4a) in the x, y, z space based on a specific zero point .

14. The device according to claim 1, characterized in that at least one contact surface (13, 14, 15) is provided for aligning and keeping the patient calm.

15. The apparatus according to claim 14, characterized in that the contact surfaces (13, 14, 15) on the vertical guide rails (1, 1 ') are designed so as to be continuously slidable and lockable.

16. The device according to one or more of the preceding claims, characterized in that at least one adjustable positioning element (11, 12) is provided on the base plate (10) for aligning the patient's feet.

17. The device according to one or more of the preceding claims, characterized in that an evaluation system (30) for recording and evaluating the measured values consisting of a computer (27), a keyboard (28), a screen (26) and a printer (29 ) is provided.

18. The apparatus according to claim 1, characterized in that in addition a measuring system for measuring the body size of the patient, consisting of a vertically displaceable measuring arm (17), a vertical guide (16), a measuring scale (21) and a pointer (22) is provided for reading the body size.

19. The apparatus according to claim 18, characterized in that the measuring arm (17) is pivotally formed on the vertical guide (16).