JP2021087774A - Exercise apparatus for rehabilitation - Google Patents

Abstract

To provide an exercise apparatus for rehabilitation which has a function for enabling a person having difficulty in getting up, to effectively perform an exercise for strengthening muscles in legs even in a supine position.SOLUTION: An exercise apparatus for rehabilitation 1 comprises: pedals 10 each having an area to place the toe to the heel of a user thereon; sensors 11 each originating a signal by detecting a placed leg; and output devices 12 each converting a signal originated from the sensor 11 to visual information, auditory information, or vibration information and outputting it. The sensor 11 is disposed at least at a part of the toe side 1/2A of the pedal 10.SELECTED DRAWING: Figure 1

Description

The present invention relates to an exercise device for rehabilitation having a function for effectively exercising a foot even in a supine position.

When walking is difficult or muscle strength is weakened, general rehabilitation methods include walking training in parallel rods and muscle training using exercise equipment.

However, since the above-mentioned commonly used training methods require maintaining a standing or sitting position, it is difficult for a person who has difficulty in getting up to adopt the training method.

For this reason, for example, relaxation support for inputting a passive operation to the lower body of the user described in Patent Document 1 so that a person who has difficulty getting up can exercise his / her legs even in a lying position. It is a health device including a drive body and an upper body bearing that mainly supports the user's upper body. The relaxation support drive body includes a lower body holding portion that holds the user's lower body. It is provided with an operating mechanism for repeatedly reciprocating and reciprocating the lower body holding portion, and the user repeatedly passively rotates the lower body holding portion from the lower body holding portion while being supported by the upper body bearing. Passive health devices have been developed that are input and thereby relax the user's body and restore flexibility and elasticity.

Japanese Unexamined Patent Publication No. 2010-158506

However, in the passive health device described in Patent Document 1, there is still room for improvement in terms of function for the user to strengthen appropriate muscles.

The present invention has been made in view of the above circumstances, and an object of the present invention is to enable a person who has difficulty in getting up to effectively perform exercises for strengthening leg muscles even in a supine position. The purpose is to provide exercise equipment for rehabilitation having the above functions.

The exercise equipment for rehabilitation of the present invention that has solved the above problems is a footrest plate having an area on which the user's toes to heels can be placed, and a sensor that detects the placement of the foot and emits a signal. It has a unit and an output device that converts the signal emitted from the sensor unit into visual information, auditory information, or vibration information and outputs it, and the sensor unit is arranged at least a part of the toe side 1/2 of the footrest plate. It is an exercise device for rehabilitation characterized by being Since the sensor unit is located on the toe side 1/2 of the footrest plate, the sensor unit emits a signal when the ball of the finger or the pad of the finger touches or approaches the sensor. Become. By converting the emitted signal into visual information, auditory information, or vibration information and outputting it, the user can confirm that the thumb ball part and the finger pad part are arranged in the sensor part. .. As a result, the user can exercise while confirming that the foot can be placed at an appropriate position. Therefore, the user can perform effective exercise.

The sensor unit is preferably a pressure-sensitive sensor.

The output device is preferably a display device arranged at least a part of the toe side 1/2 of the footrest plate.

The footrest plate is connected to the arm portion, and the arm portion is preferably connected to at least a part of the toe side 1/2 of the footrest plate.

The rehabilitation exercise device according to the embodiment of the present invention can be used for rehabilitation of a person with orthostatic dysregulation.

By arranging the sensor unit on the toe side 1/2 of the footrest plate, the sensor unit emits a signal when the ball of the finger or the pad of the finger touches or approaches the sensor unit. .. By converting the emitted signal into visual information, auditory information, or vibration information and outputting it, the user can confirm that the thumb ball part and the finger pad part are arranged in the sensor part. .. As a result, the user can exercise while confirming that the foot can be placed at an appropriate position. Therefore, the user can perform effective exercise.

It is a perspective view of the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow x indicates the horizontal direction, the arrow y indicates the vertical direction, and the arrow z indicates the height direction. It is a horizontal view which shows the mode which uses the exercise equipment for rehabilitation which concerns on embodiment of this invention shown in FIG. The arrow x indicates the horizontal direction, the arrow y indicates the vertical direction, and the arrow z indicates the height direction. It is a perspective view of the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow x indicates the horizontal direction, the arrow y indicates the vertical direction, and the arrow z indicates the height direction. It is a horizontal view which shows the mode which uses the exercise equipment for rehabilitation which concerns on embodiment of this invention shown in FIG. The arrow x indicates the horizontal direction, the arrow y indicates the vertical direction, and the arrow z indicates the height direction. It is a horizontal view which shows the mode which uses the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow x indicates the horizontal direction, the arrow y indicates the vertical direction, and the arrow z indicates the height direction. It is a top view which shows the state which the user put the foot on the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow p indicates the front-back direction. It is a top view which shows the state which the user put the foot on the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow p indicates the front-back direction. It is a top view which shows the state which the subject put the ball part (the front side of the foot) on the pedal which imitated the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow p indicates the front-back direction. It is a top view which shows the state which the subject put the arch part (the center of the foot) on the pedal which imitated the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow p indicates the front-back direction. It is a top view which shows the state which the subject put the heel part (posterior side) on the pedal which imitated the exercise equipment for rehabilitation which concerns on embodiment of this invention. The arrow p indicates the front-back direction.

Hereinafter, the exercise device for rehabilitation according to the embodiment of the present invention will be specifically described with reference to the drawings. It is also possible to carry out with appropriate modifications to the extent possible, and all of them are included in the technical scope of the present invention.

FIG. 1 is a perspective view of an exercise device for rehabilitation according to an embodiment of the present invention. In this figure, of the arrows y indicating the vertical direction, the front side is the toe side and the back side is the heel side when facing the drawing. FIG. 2 is a side view showing a mode in which the rehabilitation exercise device according to the embodiment of the present invention shown in FIG. 1 is used in the supine position. The rehabilitation exercise device according to the embodiment of the present invention shown in FIGS. 1 and 2 is an ergometer-like device, which moves a foot in the direction of arrow B to perform an exercise such as riding a bicycle. ..

FIG. 3 is a perspective view of an exercise device for rehabilitation according to an embodiment of the present invention. Of the arrows z indicating the height direction, the upper side is the toe side and the lower side is the heel side when facing the drawing. FIG. 4 is a side view showing a mode in which the rehabilitation exercise device according to the embodiment of the present invention shown in FIG. 3 is used in the supine position. The rehabilitation exercise device according to the embodiment of the present invention shown in FIGS. 3 and 4 is a leg press machine-like device, which performs a squat-like exercise by exerting a force in the direction of arrow C. ..

FIG. 5 is a side view showing a mode in which an exercise device for rehabilitation according to an embodiment of the present invention is used. The rehabilitation exercise device according to the embodiment of the present invention shown in FIG. 5 is an ergometer-like device, which moves a foot in the direction of arrow B to perform an exercise such as riding a bicycle.

6 and 7 are top views showing a state in which the user puts his / her foot on the rehabilitation exercise device according to the embodiment of the present invention. The upper side facing the drawing is the toe side, and the lower side facing the drawing is the heel side.

As shown in FIGS. 1 to 5, the rehabilitation exercise equipment according to the embodiment of the present invention includes a footrest plate 10 having an area on which the user's toes to heels can be placed, and a foot rest plate 10 and a foot. It has a sensor unit 11 that detects mounting and emits a signal, and an output device 12 that converts a signal emitted from the sensor unit 11 into visual information, auditory information, or vibration information and outputs the sensor unit 11. The sensor unit 11 is a footrest plate. It is an exercise device 1 for rehabilitation characterized in that it is arranged at least a part of 1 / 2A on the toe side of 10.

The footrest plate 10 is a plate having an area on which the user's toes to heels are placed. The shape of the footrest plate 10 is not particularly limited as long as the user's toes to heels can be placed on the footrest plate 10, and the footrest plate 10 can be made into an ellipse or a rectangle in a plan view, for example. Further, the shape of the footrest plate 10 on which the user's toes to heels are placed may be a shape that follows the sole of the user's feet. Since the footrest plate 10 has an area on which the user's toes to heels can be placed, the user can put his / her foot in an appropriate position and perform exercise.

Further, the footrest plate 10 may have a belt for fixing the position of the toes by covering the instep, or further has a belt for fixing the position of the heel of the foot by covering the Achilles tendon. It may be. With the above configuration, the position of the foot on the footrest plate 10 does not shift, and the user can exercise while keeping the foot in an appropriate position.

The sensor unit 11 is a device that captures a physical phenomenon or a change in the physical state of an object, converts it into a signal or data, and outputs it. As the sensor unit 11 for detecting the placement of the foot, a temperature-sensitive sensor that detects the position of the foot by using the temperature of the foot, detects that a force is applied, and measures the magnitude of the applied force. From pressure-sensitive sensors that detect the position of the foot from changes in the capacitance that occurs between the electrodes and human skin, infrared sensors that detect the position of the foot using infrared rays, etc. It may be selected as appropriate.

As shown in FIGS. 6 and 7, the toe side 1 / 2A of the footrest plate 10 is the length in the front-rear direction (arrow p direction) when the user puts his / her foot on the footrest plate 10. , Refers to a portion having a length of 1/2 on the toe side (hereinafter, referred to as "toe side 1 / 2A"). As shown in FIG. 1, the sensor unit 11 is arranged at least a part of the toe side 1 / 2A of the footrest plate 10, but the sensor unit 11 is located on the toe side 1 / 2A of the footrest plate 10. It may be arranged as a whole. It is more preferable that the sensor unit 11 is arranged on at least a part of the toe side 1/3 of the footrest plate 10, and it is preferable that the sensor unit 11 is arranged on the entire toe side 1/3 of the footrest plate 10. More preferred. Further, it is particularly preferable that the sensor portion 11 is arranged in the entire region where the ball of the big toe and / and the pad of the finger are arranged.

The sensor unit 11 may be arranged at least in a part of the toe side 1 / 2A of the footrest plate 10, but the user's toes are arranged at an appropriate position and used. Since it is sufficient that the sensor unit 11 can detect that the toe of the person is exerting force, the part other than the toe side 1 / 2A, that is, the part corresponding to the heel side 1/2 of the footrest plate 10. The sensor unit 11 may not be arranged on the.

The output device 12 is a device that presents a signal received from the sensor unit 11 to the outside in a form that can be recognized by humans, such as visual information, auditory information, or vibration information. A display device such as a display or a light bulb is used as an output device for converting visual information, and a sounding device such as a speaker or earphone is used as an output device for converting auditory information. Can use a vibration generator typified by a vibrator.

When the output device 12 is a display device, the display or the blinking of the light bulb informs the user that the user's foot is placed at an appropriate position and is able to perform an appropriate exercise, or touches the sensor unit 11. It is possible to convey the exercise effect to the user by displaying the time spent and the time when the force is applied to the sensor unit 11 on the display as a number. More specifically, for example, as shown in FIG. 6, the position where the user puts his / her foot is not appropriate, and the position of the foot is too rearward with respect to the front-back direction (arrow p direction) of the footrest plate 10. In such a case, "a little before" is displayed on the display device (output device 12), and when the foot is placed at an appropriate position, the display device (output device 12) is "appropriate" as shown in FIG. It is a good position. "

1 to 4, 6 and 7 show an embodiment in which the output device 12 is provided on the footrest plate 10, but the embodiment of the output device 12 is not limited to this, and for example, FIG. As shown in 5, only the output device 12 may be independently connected by the wiring 12a.

By arranging the sensor unit 11 on the toe side 1 / 2A of the footrest plate 10, the sensor unit 11 sends a signal when the ball portion of the thumb or the pad of the finger comes into contact with or approaches the sensor portion 11. It will be emitted. By converting the emitted signal into visual information, auditory information, or vibration information and outputting it to the output device 12, the user can tell that the thumb ball portion and the finger pad portion are arranged in the sensor unit 11. You can check. As a result, the user can exercise while confirming that the foot can be placed at an appropriate position. Therefore, the user can perform effective exercise.

As described above, as the sensor unit 11, a temperature-sensitive sensor, a pressure-sensitive sensor, a capacitance sensor, an infrared sensor, or the like can be used, but the sensor unit 11 is preferably a pressure-sensitive sensor. By arranging the pressure-sensitive sensor on the toe side 1 / 2A of the footrest plate 10, a signal is emitted when a force is applied to the portion where the pressure-sensitive sensor is arranged. The emitted signal is converted into visual information, auditory information, or vibration information and output to the output device 12. Therefore, as shown in FIG. 7, the user can easily confirm that the force is applied to the toe side of the foot by exercising by placing the toe of the foot on the pressure-sensitive sensor (sensor unit 11). be able to. In addition, since the triceps surae muscle can be trained by performing an exercise that puts force on the toes of the foot, it is possible to perform an exercise for strengthening the triceps surae muscle with the above configuration. The user can easily confirm that he / she is there. The lower leg triceps muscle, also known as the second heart, plays a role in sending venous blood back to the heart by repeating contraction and relaxation, and plays an important role in blood circulation as well as pumping blood from the heart. It is a muscle that is By using the exercise device 1 for rehabilitation having the above configuration, it can be easily confirmed that the exercise for strengthening the triceps surae muscle can be performed, so that the user can perform the exercise for strengthening the triceps surae muscle. The muscle strength can be effectively trained, and the strengthened triceps surae muscle exerts a stronger pumping function to send venous blood back to the heart, so that blood circulation can be performed smoothly.

As described above, as the output device 12, a display device, a sounding device, a vibration generator, or the like can be used, but the output device 12 is arranged at least a part of the toe side 1 / 2A of the footrest plate 10. It is preferable that the display device is used. When the signal emitted by the sensor unit 11 is displayed as visual information on a display device arranged at least a part of the toe side 1 / 2A of the footrest plate 10, the foot is exercised at an appropriate foot position. You can easily check if you can do it. Moreover, since the display device is arranged on the footrest plate 10, the user does not lose his / her posture when visually checking the output device, and his / her own foot is also in the field of view. For this reason, the user can exercise without losing his / her posture to see the display device, and at the same time, he / she can visually check how to move his / her foot during exercise (exercise form), which is more effective. Can exercise.

As shown in FIGS. 1 to 5, the footrest plate 10 is connected to the arm portion 13, and the arm portion 13 is connected to at least a part of the toe side 1 / 2A of the footrest plate 10. Is preferable.

The arm portion 13 is a member that holds the footrest plate 10 in a state where one end is joined to the footrest plate 10. The other end of the arm portion 13 may be connected to the support member 14. The support member 14 is connected to the arm portion 13 and holds the arm portion 13.

In the exercise device 1 for rehabilitation according to the embodiment of the present invention shown in FIG. 1, the footrest plate 10 is preferably attached to the arm portion 13 in a rotatable state, for example, a pedal used for a bicycle. As described above, the footrest plate 10 has a rotation shaft that penetrates the footrest plate 10 in the lateral direction (x direction), and one end of the arm portion 13 is joined to one end of the rotation shaft. it can. As shown in FIG. 1, the other end of the arm portion 13 may be rotatably connected to the support member 14 in the direction of arrow B.

In the case of the exercise device 1 for rehabilitation according to the embodiment shown in FIGS. 1 and 2, for example, the arm portion 13 has an arm shaft 13a and may rotate about the arm shaft 13a in the arrow B direction. It can be configured as possible. As shown in FIGS. 2 and 5, the user puts his / her foot on the footrest plate 10 and applies force to rotate the footrest plate 10 around the arm shaft 13a in the direction of arrow B to move. As a result, it is possible to obtain the effect of riding a bicycle even in the supine position, so that the muscle strength of the triceps surae muscle can be effectively strengthened.

In the case of the rehabilitation exercise device 1 according to the embodiment shown in FIG. 3, for example, the arm portion 13 may be connected to the support member 14 in a form of extending and contracting. In this case, the force applied by the user to the footrest plate 10 is transmitted to the arm portion 13, which causes the arm portion 13 to contract in the direction of arrow C, and when the user releases the force, the arm portion 13 has the original length. It is preferable to return to. With such a form, the user of the exercise device 1 for rehabilitation can perform a squat-like exercise even in the supine position.

As shown in FIGS. 1 and 3, the arm portion 13 is preferably arranged on at least a part of the toe side 1 / 2A of the footrest plate 10, and is preferably arranged on the toe side 1/2 of the footrest plate 10. It is more preferable that it is arranged in at least a part of 3.

In the ergometer-like rehabilitation exercise device 1 as shown in FIG. 1, when the user applies a force to the area of the footrest plate 10 where the arm portion 13 is arranged, the footrest plate 10 rotates. It becomes easier to exercise without any problems. Since the arm portion 13 is connected to at least a part of the toe side 1 / 2A of the footrest plate 10, the user inevitably puts force on the toe side, especially the ball of the finger and the pad of the finger. It is possible to effectively strengthen the muscle strength of the triceps surae muscle. Further, since the sensor portion 11 is also provided on the toe side 1 / 2A of the footrest plate 10, the arm portion 13 is connected to at least a part of the toe side 1 / 2A of the footrest plate 10. , The user inevitably puts a lot of effort into the sensor unit 11. When a force is applied to the sensor unit 11, information is output from the output device 12, so that the user can easily confirm that the exercise for strengthening the triceps surae muscle can be performed. can do. By using the exercise device 1 for rehabilitation having the above configuration, it can be easily confirmed that the exercise for strengthening the triceps surae muscle can be performed, so that the user can easily confirm that the triceps surae muscle can be strengthened. The muscle strength can be trained efficiently, and the strengthened triceps surae muscle exerts a stronger pumping function to send venous blood back to the heart, so that blood circulation can be performed smoothly.

Although FIGS. 3 and 4 show an embodiment of a leg press machine-like device in which the left and right feet are placed on one footrest plate 10 to perform squat-like exercises, the rehabilitation according to the embodiment of the present invention is shown. The exercise device 1 for use is a twist stepper-like device in which a footrest plate 10 on which the left foot is placed and a footrest plate 10 on which the right foot is placed are separately provided and one-leg squat-like exercise is performed on each of the left and right feet. There may be.

The rehabilitation exercise device 1 according to the embodiment of the present invention can be used for rehabilitation of a person with orthostatic dysregulation.

In the past, orthostatic dysregulation was an autonomic dysfunction associated with remarkable growth during puberty, and was thought to improve sooner or later. Even if non-pharmacotherapy such as improvement of movement, water intake, salt intake, and improvement of life rhythm is used in combination with drug therapy that takes vasopressors, the symptoms do not improve and there are few cases of prolongation. Absent.

Recent studies have shown that people with orthostatic dysregulation require moderate exercise to improve their symptoms, but people with orthostatic dysregulation have severe general malaise and dizziness. It was difficult to exercise properly in a standing or sitting position, and it was also difficult to go to a specialized facility that prescribes the correct exercise method.

Therefore, by having a person with orthostatic dysregulation use this exercise device 1 for rehabilitation, the user can exercise in a supine position without standing or sitting, which is impossible at home. You can continue exercising without any problems. Further, since the user himself / herself can confirm whether or not he / she is able to perform appropriate exercise through the output device 12, he / she can perform appropriate exercise even if there is no instructor at the time of exercise. As a result, the symptoms of orthostatic dysregulation can be improved.

The rehabilitation exercise device 1 used by the orthostatic dysregulated person is a footrest plate 10 having an area on which the toe to the heel of the orthostatic dysregulated person can be placed, and the foot placement is detected. It has a sensor unit 11 that emits a signal and an output device 12 that converts the signal emitted from the sensor unit 11 into visual information, auditory information, or vibration information and outputs the sensor unit 11, and the sensor unit 11 is the toe side 1 of the footrest plate 10. It may be any device that is arranged in at least a part of / 2A, but a pressure-sensitive sensor is adopted as the sensor unit 11, and an exercise device for rehabilitation that is arranged on the toe side 1 / 2A of the footrest plate 10. It is preferable to use 1. By using the rehabilitation exercise device 1 having the above configuration, a signal is emitted when a force is applied to the portion where the pressure-sensitive sensor is arranged. The emitted signal is converted into visual information, auditory information, or vibration information and output to the output device 12. For this reason, as shown in FIG. 7, it is easy for a person with orthostatic dysregulation to place a force on the toe side of the foot by placing the toe on the pressure-sensitive sensor (sensor unit 11) and exercising. Can be confirmed in. In addition, since it is possible to train the triceps surae muscle by performing an exercise that puts force on the toes of the foot, it is possible to perform an exercise for strengthening the triceps surae muscle with the above configuration. The person with orthostatic dysregulation can easily confirm that he / she is present. For this reason, people with orthostatic dysregulation can efficiently train the muscle strength of the triceps surae muscle, and the strengthened triceps surae muscle exerts a stronger pumping function to send venous blood back to the heart, thereby promoting blood circulation. Will be able to be done smoothly. Since such an effect can be obtained, a person with orthostatic dysregulation can improve the symptoms of orthostatic dysregulation by using the exercise device 1 for rehabilitation as described above.

As described above, the exercise device for rehabilitation of the present invention can effectively exercise the legs, especially the triceps surae muscles, in the supine position even for a person who has difficulty getting up. ..

Hereinafter, the present invention will be described in more detail based on the following Examples and Comparative Examples, but the present invention is not limited by the following Examples as well as the present invention, and is appropriately modified to the extent that it can be adapted to the purpose of the above and the following. Of course, it is also possible to carry out the above, and all of them are included in the technical scope of the present invention.

It is intended for children aged 13 to 15 years with severe orthostatic dysregulation (hereinafter referred to as "OD children") who are admitted to the pediatrics department. The definition of a child with severe OD is (1) judged to be severe by the judgment of physical severity in the pediatric orthostatic dysregulation diagnosis and treatment guideline of the Japanese Society of Pediatric Psychosomatic Medicine, and (2) the period of school refusal continues for one month or more continuously It is assumed that the person is.

1. 1. Training method Training: Perform ergometer exercise in the lying position on the bed for 4 weeks, which is possible even for severely OD children who cannot exercise in the standing position. Before starting the training, a cardiopulmonary exercise test was conducted, the maximum oxygen uptake was measured, and exercise with a load of about 70% of the maximum oxygen uptake using the heart rate as an index was started from the relative awareness intensity 11. The target is 13 after 2 weeks, and the patient remains in the lying position for 2 weeks after the start, and gradually raises the bed after 15 days. To prove that pedaling exercises on the forefoot of the sole are effective, the study set up pedaling groups on the front, middle, and hindfoot, standing tests before and after training, and cardiovascular function. , Exercise tolerance, and muscle strength are compared.
Evaluation method: Various evaluations are performed before the start of training and 4 weeks after the start of training. Evaluation items include maximum heart rate and heart rate variability in the Schellong orthostatic test, cardiovascular function by Esclonmini, electrocardiogram reflecting the cardiovascular system, blood pressure, cardiac function (CP, SV, TPR) / cardiac ultrasound examination, and evaluation of muscle strength. A manual muscle strength test, a grip strength test, and a measurement of muscle mass (Inbody muscle mass, body fat) are performed.

2. Evaluation items (1) Cardiac output (CO)
It is the amount of blood pumped from the heart to the whole body in one minute, and indicates the pumping function of the heart. Cardiac output (mL / min) is calculated by stroke volume (mL) x heart rate (times / min).
(2) Stroke volume (SV)
It is determined by the amount of circulating blood returning to the heart (preload), the resistance to pumping blood from the heart (afterload), and the contractile force of the heart. In OD patients, venous return is reduced due to blood retention in the lower limbs, and the amount of circulating blood returning to the heart is reduced.

Cardiac output (CO) is defined by heart rate (HR), preload, afterload, and contractile force. In OD patients, the heart rate (HR) increases significantly in order to maintain the pumping function of the heart because the amount of blood that collects in the lower limbs (pooling) and returns to the heart (preload) when standing up is reduced.

That is, the circulatory reaction of the OD patient when standing is as follows: i) pooling to the lower limbs due to standing, ii) decrease in the amount of blood (venous return) returning to the heart, iii) decrease in SV, and iv) maintain CO. Therefore, the increase in HR is compensatory. And even if the HR increases, CO cannot be maintained, resulting in circulatory insufficiency.

As described above, since HR is compensatory due to the decrease in SV, exercise tolerance and cardiovascular function SV and CO are used for training evaluation.

3. 3. Test results Based on the results of the subject's cardiopulmonary exercise test conducted before the start, warm-up (5 minutes with a load of 20 watts) and aerobic exercise (maximum oxygen using each person's heart rate as an index) 5 days a week in the evening A training consisting of a load of about 70% intake, 15 minutes) and a cool-down (5 minutes with a load of 20 watts) was carried out.

In training, to prove that pedaling on the ball of the foot (front of the foot) is effective, as shown in FIG. 8, the ball of the foot (front of the foot), as shown in FIG. We tried to compare each evaluation item in the case where the arch (center of the foot) and the heel (rear side of the foot) were pedaled (width: 9.5 cm, length: 8 cm) as shown in FIG. The subject complained that it was difficult to perform the heel (posterior side of the foot), and the observer also evaluated that it was difficult to continue. Therefore, two cases were compared: the ball of the big toe (front of the foot) and the arch (center of the foot). Table 1 below shows the cardiovascular function (SV) of the subjects who stepped on the pedal 30 at the ball of the foot (front side of the foot) and the subjects who stepped on the pedal 30 at the arch (center of the foot). Table 2 below shows the heart rate output (CO) of the subject who stepped on the pedal 30 at the ball of the foot (front side of the foot) and the subject who stepped on the pedal 30 at the arch (center of the foot).

Comparing the case of pedaling at the ball of the foot (front side of the foot) and the case of pedaling at the arch (center of the foot), the ball of the ball in cardiac output (CO) and cardiovascular function (SV). The result of the part (front side) was excellent. Cardiac output (CO), which is considered to indicate the pumping function of the heart, is defined by heart rate (HR) (not shown), preload, afterload, and contractile force. In OD patients, the heart rate (HR) (not shown) increases to maintain the pumping function of the heart because the amount of blood that collects in the lower limbs (pooling) and returns to the heart (preload) decreases when standing up. ..

The circulatory response when standing up in an OD patient is a machine in which pooling to the lower limbs occurs due to standing up, the amount of blood (venous return) returning to the heart decreases, SV decreases, and HR increases compensatory to maintain CO. Proceed in the beginning. And even if HR increases, CO cannot be maintained, resulting in circulatory insufficiency. In other words, since HR increases compensatoryly due to the decrease in SV, the effect of training is more directly reflected in exercise tolerance, SV, and CO.

It is presumed that the large increase in CO and SV in the forefoot part means that the function of the active muscles improved during training and the venous return during exercise increased. From this result, ergometer training in the recumbent position where the ball is pedaled on the ball of the big toe (front side of the foot) is more OD than pedaling on the arch (center of the foot) and heel (rear side of the foot). It was shown that it is highly effective in improving the condition and is useful for improving the symptoms of severely OD children.

1: Exercise equipment for rehabilitation 10: Footrest plate 11: Sensor part 12: Output device 12a: Wiring 13: Arm part 13a: Arm shaft 14: Support member 20: Bed A: Toe side 1/2
30: Pedal

Claims (5)

A footrest board that has an area from the user's toes to the heel,
A sensor unit that detects the placement of the foot and emits a signal,
It has an output device that converts the signal emitted from the sensor unit into visual information, auditory information, or vibration information and outputs it.
An exercise device for rehabilitation, wherein the sensor unit is arranged at least a part of the toe side 1/2 of the footrest plate. The rehabilitation exercise device according to claim 1, wherein the sensor unit is a pressure-sensitive sensor. The exercise device for rehabilitation according to claim 1 or 2, wherein the output device is a display device arranged at least a part of the toe side 1/2 of the footrest plate. The footrest plate is connected to the arm portion and
The rehabilitation exercise device according to any one of claims 1 to 3, wherein the arm portion is connected to at least a part of the toe side 1/2 of the footrest plate. The exercise device according to any one of claims 1 to 4, which is used for rehabilitation of a person with orthostatic dysregulation.

Images