TRAINING DEVICE FOR STIMULATING NERVE CELL ENDS IN A TRAINING MANNER, AND A CORRESPONDING PROSTHESIS

Abstract

A training device for stimulating nerve cell ends in a training manner, includes a housing having at least one first housing portion and a plurality of stimulators for stimulating physionomie-typical nerve area portions. A plurality of stimulators are arranged systematically at least on the first housing portion of the housing so that the plurality of stimulators in the training state each act on nerve cell ends with which they are associated. Also disclose are a method for operating the training device, the use of the training device as a modular stimulation device for stimulating nerve cell ends, a prosthesis, a method for producing a prosthesis and the use of a training device for stimulating nerve cell ends in a prosthesis.

Claims

1. A training device (10) for stimulating nerve cell ends in a training manner, comprising: a housing (11) having at least one first housing portion (12); and a plurality of stimulators (20) for stimulating physionomy-typical nerve area portions (71), wherein, at least on the first housing portion (12) of the housing (11), a plurality of stimulators (20) are systematically arranged in such a way that the plurality of stimulators (20) in the training state act on respectively associated nerve cell ends.

2. The training device (10) according to claim 1, further comprising: a control device (30) for controlling the plurality of stimulators (20), which comprises at least one training program.

3. The training device (10) according to claim 2, further comprising a data transmission device (40) for transmitting data, wherein the data transmission device (40) is arranged in the control device (30) in such a way that external training data and/or stimulation data is transferred to the control device (30).

4. The training device (10) according to claim 3, wherein the data transmission device (40) is provided with external sensor data (65) of a prosthesis (50).

5. The training device (10) according to claim 2, wherein the control device (30) comprises a computing unit (35), the computing unit (35) comprises at least one stimulation program for creating stimulation commands for a stimulation state and/or at least one training program for creating training commands for a training process.

6. The training device (10) according to claim 1, wherein the housing (11) comprises at least one second housing portion (13), on the second housing portion (13), a mounting unit (15) for mounting the housing (11) on a first prosthesis part of a prosthesis (50).

7. The training device (10) according to claim 2, wherein the control device (30) is equipped in such a way that a training program for training purposes or a stimulation program for stimulation by means of external sensors (65) is configured, wherein the control device (30) automatically detects a rehabilitation mode and a prosthesis mode by means of a detection device (45).

8. A method for operating a training device (10) for stimulating nerve cell ends in a training manner, and including: (i) a housing (11) having at least one first housing portion (12); and (ii) a plurality of stimulators (20) for stimulating physionomy-typical nerve area portions (71), wherein, at least on the first housing portion (12) of the housing (11), a plurality of stimulators (20) are systematically arranged in such a way that the plurality of stimulators (20) in the training state act on respectively associated nerve cell ends, the method comprising: arranging the training device (10) on a physionomy-typical nerve area portion (71) with nerve cell ends; and displaying the nerve cell ends at a visualization device (32) of the training device (10) or on a mobile terminal device (68).

9. (canceled)

10. A prosthesis (50), comprising: a first prosthesis part; a prosthesis shaft (51) and/or a prosthesis stocking, wherein the first prosthesis part comprises at least one receptacle (52) for accommodating a training device (10) as a modular stimulation device, wherein the training device is arranged in a separable manner on the at least one receptacle (52) of the first prosthesis part, and wherein the training device (10) for stimulating nerve cell ends in a training manner includes: (i) a housing (11) having at least one first housing portion (12); and (ii) a plurality of stimulators (20) for stimulating physionomy-typical nerve area portions (71), wherein, at least on the first housing portion (12) of the housing (11), a plurality of stimulators (20) are systematically arranged in such a way that the plurality of stimulators (20) in the training state act on respectively associated nerve cell ends.

11. The prosthesis (50) according to claim 10, wherein the first prosthesis part comprises at least one input unit (54) for detecting the training device.

12. The prosthesis (50) according to claim 10, wherein the first prosthesis part comprises at least one prosthesis mounting unit (55), the at least one prosthesis mounting unit (55) is complementary to a mounting unit (15) of the training device (10).

13. The prosthesis (50) according to claim 10, further comprising external sensors (65) for the detection of forces acting on the prosthesis (50) and/or pressures, which are connected to the training device for receiving sensor data, wherein the external sensors (65) are arranged in a further prosthesis part of the prosthesis (50).

14. A method for producing a prosthesis (50), the prosthesis (50), comprising: a first prosthesis part; a prosthesis shaft (51) and/or a prosthesis stocking, wherein the first prosthesis part comprises at least one receptacle (52) for accommodating a training device (10) as a modular stimulation device, wherein the training device is arranged in a separable manner on the at least one receptacle (52) of the first prosthesis part, and the training device (10) for stimulating nerve cell ends in a training manner, including: (i) a housing (11) having at least one first housing portion (12); and (ii) a plurality of stimulators (20) for stimulating physionomy-typical nerve area portions (71), wherein, at least on the first housing portion (12) of the housing (11), a plurality of stimulators (20) are systematically arranged in such a way that the plurality of stimulators (20) in the training state act on respectively associated nerve cell ends, the method comprising: producing a receptacle (52) for attaching the training device (10) on a first prosthesis part of the prosthesis (50).

15. (canceled)

16. The training device (10) according to claim 2, further comprising a visualization device (32) coupled to the control device (30) for visually display to the patient of a stimulation in a training manner from at least one training program.

17. The training device (10) according to claim 2, wherein the control device (30) is arranged in the housing (11) and is controlled using at least one of an external remote device (68).

18. The training device (10) according to claim 3, wherein the data transmission device (40) comprises an interface (43), on which a user defines training programs and/or stimulation programs, wherein the interface (43) comprises, an input device (44) for entering control data.

19. The training device (10) according to claim 5, wherein the computing unit (35) is connected to the data transmission device (40) for exchanging data, including external sensor data, and the computing unit (35) comprises a computational algorithm, which, in an operating state, processes external sensor data from external sensors (65) of an artificial foot sole (61).

20. The training device (10) according to claim 6, further comprising a positioning unit (16) for positioning the training device (10) on the first prosthesis part of a prosthesis (50).

21. The prosthesis (50) according to claim 12, wherein the at least one prosthesis mounting unit (55) is arranged on an outer surface of the first prosthesis part.

22. The prosthesis (50) according to claim 13, wherein the external sensors (65) are arranged in a further prosthesis part of the prosthesis (50), on an artificial foot sole (61) thereof.

Description

[0104] The figures show:

[0105] FIG. 1 a training device according to the invention in a sectional view,

[0106] FIG. 2 the training device in accordance with FIG. 1 in a top view,

[0107] FIG. 3 one stimulator from the plurality of stimulators of the training device according to the invention in a detailed illustration,

[0108] FIG. 4 a prosthesis according to the invention without the training device in a sectional view,

[0109] FIG. 5 the artificial foot sole of the prosthesis in accordance with FIG. 4 in a top view, and

[0110] FIG. 6 the prosthesis in accordance with FIG. 4 with the training device in accordance with FIG. 1 in a perspective view.

[0111] FIG. 1 and FIG. 2 show the training device 10 according to the invention for the training stimulating of nerve cell ends. The training device 10 comprises a housing 11 with a first housing portion 12, on which plurality of stimulators 20 for stimulating physionomy-typical nerve area portions are arranged. For this purpose, the first housing portion 12 comprises a plurality of housing openings 25, in which the stimulators 20 are arranged in portions. On a second housing portion 13 of the housing 11, the training device 10 comprises a mounting unit 15 for mounting the housing 11 on a first prosthesis part of a prosthesis, as well as a positioning unit 16 for positioning the training device 10 on a first prosthesis part of a prosthesis. A control device 30 is arranged in the housing 11 for controlling the plurality of stimulators 20. The control device 30 comprises a computing unit 35, a processor, as well as a memory unit 36, which are electrically connected to each other and to the plurality of stimulators 20. In the computing unit 35, different stimulation programs are executed for creating stimulation commands for a stimulation state of the plurality of stimulators 20. Furthermore, 35 different training programs for creating training commands for a training process for the plurality of stimulators 20 are executed in the computing unit. The computing unit 20 comprises a plurality of calculation algorithms, using which the stimulation commands and/or the training commands are generated. In the memory unit 36, the plurality of calculation algorithms are stored, which are retrieved by the computing unit 35 or by the processor as required. The control device 30 is designed in such a way that at least one training program for either training purposes or a stimulation program for stimulation by means of the plurality of stimulators 20 can be configured.

[0112] In accordance with this special embodiment, the training device 10 comprises a data transmission device 40 with a transmitting unit 41 and a receiving unit 42 for wireless data exchange. The data transmission device 40 is electrically connected to the control device 30 and the computing unit 35. The data transmission device 40 further has an interface 43, with which a remote device 68, such as a computer for example, can be electrically connected and at which a training program or a stimulation program can be defined. The transmitting unit 41 or the receiving unit 42 can be connected with a cloud 66 or with a mobile terminal device 68 (smartphone, tablet, etc.) for exchanging data, for example historical data. The transmitting unit 41 is also connected to an external sensor, for example, a sensor on a prosthesis part or an external sensor, such as a temperature sensor, a humidity sensor or a GPS sensor, etc., for exchanging data. The data is transferable to the computing unit 35 and is processed there in the calculation algorithm so that the control device can transmit 30 stimulation commands and/or training commands to the plurality of stimulators 20.

[0113] The housing 11 comprises a further housing portion 14 with the visualization device 32, on which individual training data or training commands as well as stimulation data or stimulation commands and information, such as messages are displayed, being partially animated if applicable.

[0114] The visualization device 32 is electrically connected to the control device 30 and receives from the control device 30 the training data or training commands, as well as stimulation data or stimulation commands and information. The visualization device 32 comprises an input device 44, which is preferably designed as a touchscreen. In addition to a main switch (on and off switch), the input device 44 also includes a selection switch for selecting specified training programs and/or stimulation programs.

[0115] On the further housing portion, an energy storage unit 38, a battery or an accumulator is arranged, which is electrically connected to the control device 30, with the plurality of stimulators 20 and with the detection device 45. The energy storage unit 38 also supplies the visualization device 32 with energy.

[0116] On the first housing portion 12, a detection device 45, as RFID unit 46, is provided so that the control device 30 automatically recognizes the need for a rehabilitation mode (reha mode) and a prosthesis mode (active mode)—depending on what is immediately connected.

[0117] The plurality of stimulators 20 are systematically arranged on the first housing portion 12 so that the plurality of stimulators 20 in the training state can act on their respectively associated nerve cell ends. For this purpose, the systematic arrangement of the planarity of stimulators 20 displays a depiction of the gait line 63 of a human foot sole. The plurality of stimulators 20 are arranged in a lightning shape on the first housing portion 12. In the example shown in FIG. 2, five stimulators 20 are needed to display the depiction of the gait line 63 of the human foot. The systematic arrangement of the plurality of stimulators 20 is carried out in such a way that each stimulator 20 each at least coincides identically with at least one associated nerve cell end in the physionomy-typical nerve area portion.

[0118] FIG. 3 shows one of the plurality of stimulators 20 for stimulating nerve cell ends, which are arranged on the first housing portion 12. The stimulator 20 comprises a vibration generator 21 with a vibration-generator housing 26, which is connected to a spring member 23 as decoupling elements 24. The spring member 23 is a rod-shaped spring wire, which is arranged on one housing side of the vibration-generator housing 26. For this purpose, the spring member 23 is attached with one end to the vibration-generator housing 26. The spring member 23 decouples the vibrations or oscillations of the vibration generator 21 from the surrounding area. The other end of the spring member 23 is fixed with a fastening means 29 to a fastening portion 22 of the first housing portion 12 and is supplied with energy by means of the power lines 27. In this case, the stimulator 20 is arranged along the housing portion 12 in a longitudinal direction in a spatially adjustable manner. Furthermore, the stimulator 20 is arranged around the fastening means 29 in a rotatable manner, wherein the fastening means 29 can thereby be detached. For this purpose, the housing openings 25 comprise a corresponding embodiment. Alternatively, another rod-shaped spring member is arranged between the fastening portion 22 and the vibration-generator housing 26 (not shown). The vibration-generator housing 26 is introduced at least partially into the housing opening 25, so that the vibration-generator housing 26 at least partially penetrates the housing opening 25. An eccentric element 28 is arranged in the vibration-generator housing 26. The eccentric element 28 is rotatable or rotatably mounted in the vibration-generator housing 26. The vibrating of the vibration generator 21 is caused with the eccentric element 28 via the alternating direction of the centripetal force of the eccentric element 28. The vibration generator 21 has in its vibration-generator housing 26 a drive motor for rotational propulsion of the eccentric element 28 (not shown). The drive motor is connected to the energy storage unit 38. Alternatively, the vibration generator 21 has an oscillation element instead of the eccentric element, which moves along a straight guide and causes a vibration due to the mass inertia of the oscillation element (not shown).

[0119] The invention also relates to a method for operating the herein described training device 10, in particular as a modular stimulation device comprising the following steps: [0120] arranging the training device 10 on a physionomy-typical nerve area portion 71 with nerve cell ends, in particular, with reinnervated nerve cell ends 72; [0121] representing the nerve cell ends or the original activity site associated with them on the amputated extremity of the patient at a visualization device 32 of the training device 10 or on a mobile terminal device 67.

[0122] In addition, the plurality of stimulators 20 are displayed on the visualization device 32 or on the mobile terminal device 67 so that the user of the training device 10 can mentally link the triggering of a certain stimulation with a certain stimulator 20, thereby improving the training effect.

[0123] Subsequently, an adaptation of at least one stimulation command and/or of at least one training command on the input device 44 of the visualization device 32 or on the mobile terminal device 67 is carried out. One stimulation program from the plurality of stimulation programs or one of the plurality training programs is selected and then executed by the control device 30. The plurality of stimulators 20 are stimulated sequentially or simultaneously according to the program, so that they stimulate the nerve cell ends on the physionomy-typical nerve area portion 71.

[0124] Another aspect of the invention concerns the use of the training device described here in the present case 10 as a modular stimulation device for stimulating nerve cell ends, in particular, of reinnervated nerve cell ends.

[0125] FIG. 4 shows a prosthesis 50 with a prosthesis shaft 51 as the first prosthesis part, which is arranged at an extremity 69. The prosthesis shaft 51 comprises a receptacle 52 for accommodating a training device as a modular stimulation device. The training device can be separated from the receptacle 52 of the prosthesis shaft 51. The receptacle 52 is shaped in a window-like manner and comprises a frame, wherein the training device is inserted in it. The receptacle 52 is arranged in the region of a skin area 70 of the remaining extremity 69 and allows an access from the outside to the skin area 70. At this skin area 70, there is a physionomy-typical nerve area portion 71 with the reinnervated nerve cell ends 72 arranged there. The reinnervated nerve cell ends 72 are arranged in the physionomy-typical nerve area portion 71 in this example according to a special matrix or in a lightning-shaped manner. The reinnervated cell ends 72 lie along the depiction of a gait line 63. The prosthesis shaft 51 has an input unit 54, as an RFID unit, which acts together with the RFID unit of the training device and automatically recognizes this in the state arranged on the prosthesis 50. The prosthesis shaft 51 comprises a prosthesis mounting unit 55, whereby the training device can be arranged on the prosthesis 51. The prosthesis 50 has a prosthesis cosmetic element 59 and an artificial foot 60 with an artificial foot sole 61, which also bears a gait line 62 of the artificial foot sole 61 or rolls along it when the artificial foot performs a walking motion. The receptacle 52 comprises receptacle openings 53, which are suitable for the respective accommodation of at least one stimulator 20 of a training device. A sealing insert 57, for example, made of a silicone material, can be arranged between the receptacle 52 and the training device.

[0126] FIG. 5 shows the artificial foot sole 61 of the prosthesis 50. Five external sensors 65, which are designed as pressure sensors, are arranged on the artificial foot sole 61. The external sensors 65 are arranged in a lightning-shaped manner on the artificial sole 61 and lie along the gait line 62 of the artificial foot sole. In the embodiment shown, the shape of the depiction of the gait line 63 on the physionomy-typical nerve area portion 71 of the extremity 69 (FIG. 4) is identical to the shape of the gait line 62 of the artificial foot sole 61. However, it is possible to design the depiction of the gait line 63 independently to the gait line 62 of the artificial foot sole 61. The only decisive factor here is that the respective nerve cell ends in the physionomy-typical nerve area portion 71 are associated with the respective stimulators 20 of the training device 10.

[0127] FIG. 6 shows the prosthesis 50 described here with the training device 10 accommodated on the receptacle 52. In this process, the mounting unit 15 of the training device 10 complementary to the prosthesis mounting unit 55 on the prosthesis shaft 51. In this case, the training device 10 can be positioned with the positioning unit 16 and fastened or fixed to the prosthesis shaft 51 using the fixing unit 58 attached or fixed. The training device 10 is arranged with their systematically arranged stimulators 20 on their respectively associated nerve cell ends on the physionomy-typical nerve area portion 71 of the extremity 69 in such a way that the depiction of the gait line 63 coincides with the systematic arrangement of the plurality of stimulators 20.

[0128] On the artificial foot sole 61 of the artificial foot 60, a plurality of external sensors 65 are arranged for the detection of pressures acting on the prosthesis 50. The plurality of external sensors 65 are arranged along the gait line 62 and electrically connected to the transmitting unit 64 of the artificial foot 60. Thereby, the transmitting unit 64 is arranged in a detachable manner on the artificial foot 60, or on the cosmetic element 59. In this case, the transmitting unit 64 is magnetically arranged on the artificial foot 60 or on the cosmetic element 59 by means of a retaining device and arranged along this in an adjustable manner. The prosthesis 50 can also comprise further external sensors for detecting a force acting on the prosthesis 50. These external sensors are arranged, for example, on a prosthesis portion arranged on the side of the artificial foot 60 and transmit sensor data to the training device 10, which act by a shock on these external sensors in the prosthesis-strip portion (not shown). The transmitting unit 64 sends the sensor data from the external sensors 65 and the sensors on the prosthesis-strip portion to the receiving unit 42 of the data transmission device 40 of the training device 10. The sensor data is then forwarded to the control device 30. The transmitting unit 64 can comprise a charging coupling unit, with which an energy storage unit in the transmitting unit is inductively rechargeable by means of a separate charging unit (not shown).

[0129] As shown in FIG. 6, the prosthesis shaft 51 comprises a receptacle 52 for accommodating the training device 10. In the production of the prosthesis 50, a window-like receptacle 52 for fastening the training device 10 is produced on the prosthesis shaft 51. Alternatively, a box-shaped receptacle is produced in which the training device 10 is attached. Subsequently, the training device 10 is inserted into the window-like receptacle 52 whereby training device 10 is detected by means of its detection device 45 of the input unit 54 of the prosthesis 50 in such a way that the control device 30 automatically switches into the prosthesis mode. The transmitting unit 64 on the artificial foot 60 sends the sensor data from the external sensors 65 and the sensors on the prosthesis-strip portion to the receiving unit 42 of the data transmission device 40 of the training device 10. The sensor data is then forwarded to the control device 30 and processed there. In the computing unit 35 of the control device 30, the sensor data of the external sensors are transmitted in stimulation commands of the respectively associated stimulators 20. The respective stimulator 20 then stimulates the nerve cell end associated with it on the physionomy-typical nerve cell portion 71.

[0130] Thus, the training device 10 is usually used in a state separated from the prosthesis 50 as a training device 10 in rehabilitation mode and in the state arranged on the prosthesis 50 in prosthetic mode. Deviations from this rule can be provided, for example, if the user wishes to obtain training in the case of a prosthesis mounted on.

REFERENCE LIST

[0131] 10 training device

[0132] 11 housing

[0133] 12 first housing portion

[0134] 13 second housing portion

[0135] 14 further housing portion

[0136] 15 mounting unit

[0137] 16 positioning unit

[0138] 20 stimulators

[0139] 21 vibration generator

[0140] 22 fastening portion

[0141] 23 spring member

[0142] 24 decoupling element

[0143] 25 housing opening

[0144] 26 vibration-generator housing

[0145] 27 power line

[0146] 28 eccentric element

[0147] 29 fastening means

[0148] 30 control device

[0149] 32 visualization device

[0150] 35 computing unit

[0151] 36 memory unit

[0152] 38 energy storage unit

[0153] 40 data transmission device

[0154] 41 transmitting unit

[0155] 42 receiving unit

[0156] 43 interface

[0157] 44 input device

[0158] 45 detection device

[0159] 46 RFID unit

[0160] 50 prosthesis

[0161] 51 prosthesis shaft

[0162] 52 receptacle

[0163] 53 receptacle openings

[0164] 54 input unit

[0165] 55 prosthesis mounting unit

[0166] 57 sealing insert

[0167] 58 fixing unit

[0168] 59 prosthesis cosmetic element

[0169] 60 artificial foot

[0170] 61 artificial foot sole

[0171] 62 gait line

[0172] 63 depiction of the gait line

[0173] 64 transmitting unit

[0174] 65 external sensors

[0175] 66 cloud

[0176] 66 mobile terminal device

[0177] 67 remote device

[0178] 68 extremity

[0179] 70 skin area

[0180] 71 physionomy-typical nerve area portion

[0181] 72 reinnervated nerve cell end