Patent Application
20240074697
The invention falls within the scope of medical and gymnastic technologies, specifically devices and methods for kinetic energy measurement and training of muscles for sport or rehabilitation purposes.
Development of the invention relates to the method and device described in the document CZ307845, which enable measurement of lower extremity muscle strength, namely quadriceps femoris muscle, sartorius muscle, biceps femoris muscle, semitendinosus muscle, semimembranosus muscle and popliteus muscle, tibialis, toe extensor hallucis longus, thumb extensor hallucis longus, triceps surae, calf muscle long, and calf muscle short.
The device comprises of a mechanical unit measuring muscle strength and a control unit determining a pre-defined isokinetic movement. The mechanical unit comprises of a bearing surface for the knees of the measured person equipped with a sensor for sensing the angular position of the body of the measured person, an arm connected to the sensor of angular position, and at least one electric dynamometer to measure muscle pressure strength. The control unit comprises of a computer-controlled system with firmware to analyze data gathered from the electric dynamometer, sensor of angular position, and imaging equipment supplying optical instructions to the measured person in a manner so as this person keeps isokinetic movement or alternatively simultaneously also an audible device to supply acoustic instructions. The imaging equipment can be mounted perpendicularly to the axis of movement of the measured person or in the axis of movement for better sensorimotor guidance of the measured person. The control unit is also equipped with an interface to transfer data to the computer to allow their subsequent display and evaluation. Dynamometers, the sensor of angular position, and the control unit can be powered by an external power source or the device can be equipped with its own battery.
The method used by this device is employed in a manner that the measured person is in the kneeling position with the upright posture of both the trunk and thigh parts of lower extremities, and calf part of lower extremities perpendicular to them. The calf part of lower extremities is thus fixed by knees on the bearing surface and by ankles, leaning against dynamometers mounted above them. The measured person touches the arm of the sensor of angular position in the area of the upper part of the thigh. Measurement or exercise begins with the start of a forwarding angular movement of the measured person in such a manner that the angle of both the trunk and thigh part of lower extremities opens against the calf part of lower extremities. Gravitational force affects both the trunk and thigh part of lower extremities, thus orienting this part of the body towards the forwarding angular movement; strength of muscles of lower extremities counteracts this strength, measured during this movement by the dynamometers, against which the measured person leans by the ankles. The arm of the sensor of angular position copies the movement of the measured person in the forwarding angular movement; said movement, generated by the person, pushes the arm in the direction and speed of the movement of the measured person. The control unit evaluates the advancement of angular movement of the measured person on the basis of values supplied by the sensor of angular position monitoring the change in the speed of change in angular position, and based on these data the control unit displays the speed of change in angular movement on the imaging equipment and, at the same time, desired speed in such a manner to keep isokinetic mode. During the movement, the control unit continuously monitors the keeping of the isokinetic mode of the movement; if the defined deviation between actual and requested values is exceeded, the unit evaluates and records the course of values from the dynamometers and the sensor of angular position in their interaction. Thus, the described process allows measurement and evaluation of the course of movement both from the point of isokinetic demonstration of the movement and achieved individual limit values regarding the physical constitution of the measured person.
The shortcoming of such a device is its focus on the specific group of measured muscles, whereas data on the strength characteristics of the knee, muscle contraction of the quadriceps, eccentric muscle contraction of the knee extensors, concentric muscle contraction of the knee extensors, or isometric muscle contraction of the knee extensors cannot be obtained from results of such measurement.
Currently, the said shortcoming can be overcome only by the use of very complex devices, which are large and expensive. Such devices include, among others, the device described in the document WO9111221, where the measurement is made with the measured person in the sitting position; therefore, the device must be equipped with a large seat, considerably increasing the weight of the device and, consequently, restricting its mobility. The method of measurement using such device requires the measured person to do the concentric exercise with the contraction of the calf part of the lower extremity. Therefore, such or similar device must be equipped with electric motors or hydraulic or pneumatic system, working against the strength generated by muscles of the measured person.
The purpose of this invention is to propose a method which will reduce or eliminate the above-mentioned shortcoming while keeping the requested simplicity and self-service of the device, on which the said method will be employed.
Subject of the invention is the method of measurement of strength characteristics of the knee using a device which allows the collection of data on muscle contraction of the quadriceps, eccentric muscle contraction of the knee extensors, concentric muscle contraction of the knee extensors, or isometric muscle contraction of the knee extensors.
This method is applied in sub-steps, when the rear side of calves of the measured person in the upright posture leans against statically mounted dynamometers, with the rear part of thighs leaning against the movable arm; then, the measured person starts a transition to the sitting position, thus influencing the movable arm, which—by the connected sensor of angular position of the movable arm—monitors speed of change of angular position of the movable arm and, further, influences the dynamometers which measure the strength which the measured person generates individually for each lower extremity, whereas the sensor of angular position of the arm and dynamometers transmit collected information into the control unit, which evaluates the speed of change in angular position of the movable arm and informs the measured person about the actual and requested speed of change of angular position of the movable arm on the imaging equipment in a manner that the measured person will adjust the speed of transition from the upright posture to the sitting position to the requested speed.
Measurement or exercise done in this manner is advantageous to perform in the isokinetic mode as the isokinetic mode is the movement of muscles in the vicinity of their peak during the entire scope of movement in the joint and allows the full contraction in each point of the scope of movement. Especially for exercising, it is essential that the isokinetic movement means a maximum load of active muscles in the course of the entire scope of movement and allows to do a significantly more intensive work of muscles compared with the regular strength training as the muscle strength is not constant in the course of the movement.
Therefore, the said method allows measurement or exercise and evaluation of the course of movement of the measured person from the point of isokinetic demonstration of the movement and, at the same time, also from the point of achieved individual limit values regarding the physical constitution of the measured person.
In contrast to the state of the art, i.e. methods of measurement of strength characteristics of the knee, the invention especially differs in the different position of the body of the measured person, which is not in the sitting position with the fixed position of the trunk and thigh part of the lower extremity producing the movement only with the calf part of the lower extremity, but has the fixed calf part of the lower extremity, which leans against the dynamometers and makes the exercise by the movement of the thigh part of the lower extremity, where muscles of lower extremities generate pressure against the existing gravitational force.
The device used for the implementation of the described method comprises of the mechanical unit measuring muscle strength and the control unit determining the predefined isokinetic movement. The mechanical unit comprises of the frame, to which the movable arm is affixed, which is attached to the frame in its lower point in a manner that allows its rotation around the axis in this lower point. The sensor of angular position, reading data on the actual position of the movable arm, is attached to the movable arm in the axis of its rotation. Furthermore, dynamometers with the bearing surfaces located in the horizontal position for the calves of the measured person are attached to the frame. The control unit comprises of the computer-controlled system with firmware to analyze data gathered from the electric dynamometers, the sensor of angular position and further includes the imaging equipment supplying optical instructions to the measured person in a manner that this person keeps or adopts its movement to the pre-defined scenario of measurement or exercise, in particular isokinetic movement. The imaging equipment is fixed perpendicularly to the axis of movement of the measured person for better sensorimotor guidance of the measured person. The control unit is also equipped with the interface to transfer data to the computer to allow their subsequent display and evaluation.
The device can be preferably completed with the bearing surface connected to the frame, with another movable arm, to which another sensor of angular position is connected, whereas the said sensor of angular position is connected with the control unit. The dynamometers with bearing surfaces, in the point of their connection to the frame, will rotate from horizontal to vertical position, so that the measured person would lean against these bearing surfaces in the sitting position with thighs or ankles. The measured person starts measurement or exercise with the upright posture of both the trunk and thigh parts of lower extremities and the calf part of lower extremities perpendicular to them. The calf part of lower extremities is thus fixed by knees on the bearing surface and by ankles, leaning against the dynamometers mounted above them. The measured person touches the arm of the sensor of angular position in the area of the upper part of the thigh. Measurement or exercise begins with the start of the forwarding angular movement of the measured person in such manner that the angle of both the trunk and thigh part of lower extremities opens against the calf part of lower extremities. Gravitational force affects both the trunk and thigh part of lower extremities, thus orienting this part of the body towards the forwarding angular movement; strength of muscles of lower extremities counteracts this force and is measured in this movement by the dynamometers, against which the measured person leans by ankles.
In this configuration, the device allows measurement or exercise of other muscles of lower extremities, namely quadriceps femoris muscle, sartorius muscle, biceps femoris muscle, semitendinosus muscle, semimembranosus muscle and popliteus muscle, tibialis, toe extensor hallucis longus, thumb extensor hallucis longus, triceps surae, calf muscle long, and calf muscle short.
The method of measurement of strength characteristics of the knee using the device according to Example 2.
This method is performed in sub-steps where:
Description of the preferred embodiments of the device according to the invention in the baseline option for the implementation of the method described in Example 1.
Such a device comprises of the frame (1) with connected vertically mounted movable arm (2). This movable arm (2) is mounted to the frame (1) in its lower point for its rotation around the axis located in this lower point. The sensor (21) of angular position for recording data on the actual position of the movable arm is connected to the movable arm (2) in the axis of its rotation. The dynamometers with the bearing surfaces (3) mounted in the vertical position for calves of the measured person are attached to the frame (1).
The device is also equipped with control unit which is connected to the sensor of angular position (21) and to the dynamometers with the bearing surfaces (3). The control unit comprises of computer-controlled system with firmware to analyze data gathered from the dynamometers (3) and from the sensor (2) of angular position, and furthermore the visualization equipment (4) for displaying optical instructions to the measured person for it to keep or modify performed movement. The visualization equipment (4) is placed perpendicularly to the axis of the movement of the measured person in a manner that the visualization equipment (4) is in the visual field of the measured person. In addition, the control unit is equipped with the interface to transfer data to the computer for their subsequent display and evaluation.
Description of the preferred embodiments of the device in the combined variant including, in addition to the device described in Example 2, also components allowing measurement of strength of other muscles of lower extremities as well.
Such device comprises of the frame (1), to which the movable arm (2), connected to the frame (1) in its lower point for its rotation around the axis located in this lower point, is connected. The sensor (21) of angular position for recording data on the actual position of the movable arm is connected to the movable arm (2) in the axis of its rotation. The bearing surface (5) for knees is also connected to the frame (1); the movable arm (51) with the sensor of angular position (52) is connected to the bearing surface for the knees (5). Dynamometers with the bearing surfaces (3) are connected to the frame (1) in the pivot for the change in their position from the vertical, for pushing by calves of the standing measured person, to the horizontal, for pushing by ankles of the kneeling measured person.
The device is also equipped with the control unit, which is connected to the sensor (21) of angular position, to the sensor (52) of angular position, and to the dynamometers. The control unit comprises of the computer-controlled system with firmware to analyze data gathered from the dynamometers and the sensor (21) of angular position or the sensor (52) of angular position and, furthermore, the visualization equipment (4) for displaying optical instructions to the measured person for it to keep or modify performed movement. The visualization equipment (4) is placed perpendicularly to the axis of the movement of the measured person in a manner that the visualization equipment (4) is in the visual field of the measured person. In addition, the control unit is equipped with the interface to transfer data to the computer for their subsequent display and evaluation.
The method of measurement of strength characteristics of the knee and the device for implementation of this method is primarily applicable to diagnostic or training purposes, namely for sportsmen or convalescent patients.
| Number | Date | Country | Kind |
|---|---|---|---|
| PV 2019-632 | Oct 2019 | CZ | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CZ2020/050077 | 10/8/2020 | WO |
