KR20230164595A - System for measuring quantitative sensation of vibration and method thereof - Google Patents

Abstract

The present invention relates to a quantitative vibration sensation measurement system and method.
According to the present invention, the quantitative vibration sensation measurement system includes a vibrator that applies vibration stimulation divided into a plurality of stages according to the intensity of vibration to the subject, and a subject response that generates a feedback signal as to whether the stimulus is recognized according to feedback information input by the subject. Receive stimulation information related to the vibrator operation from the device and the vibrator, calculate a quantitative vibration sensation value according to the feedback signal received from the subject response device, and then combine the calculated quantitative vibration sensation value with the subject's personal characteristic information. It includes a measuring device that provides information on the presence of abnormalities and expected diseases according to changes in the degree of perception of vibration sensation by inputting it into the prediction model.

Description

{System for measuring quantitative sensation of vibration and method thereof}

The present invention relates to a quantitative vibration sensation measurement system and method. More specifically, in order to quantitatively evaluate the subject's vibration sensation, several levels of vibration are automatically applied step by step to the subject by a vibrator, and the applied vibration stimulation is applied to the subject. A quantitative vibration sensation measurement system to calculate the quantitative value of the patient's vibration sensation according to the subject's feedback information, and then provide information on the presence of abnormalities and expected diseases according to changes in the degree of perception of vibration sensation based on the calculated quantitative vibration sensation value. and methods.

Vibration sensation is mainly sensed through the action of Pacinian corpuscles. Pacinian corpuscles are concentrated in tendons and soft tissues around bones, so when testing vibration sensation in clinical practice, they are mainly detected on bone protrusions or tendons. This is why it is performed on the affected area. In particular, subcutaneous fat is a factor that affects sensory perception, and the more the fat layer is distributed, the more insensitive it feels.

When damage to the nervous system occurs due to various pathological causes, loss of vibration sensation may occur. Even in healthy people, the threshold of vibration sensation varies by body part and age, and changes occur in the threshold of vibration sensation depending on the lesion area in peripheral neuropathy and central neuropathy. Therefore, in patients suspected of having a nervous system disease, the threshold of vibration sensation in each body part is measured. Localization of the lesion is possible.

In this way, the measurement of vibration sensation is one of the very important neurological examinations that serve as a clue to the diagnosis of various peripheral nerve diseases. At present, measurement using a tuning fork is clinically performed, but this method uses only the magnitude of vibration for evaluation. There was a problem that it was difficult to objectively quantify the severity because it could vary depending on the clinician or the time of measurement.

The technology behind the present invention is disclosed in Republic of Korea Patent No. 10-2282961 (announced on July 29, 2021).

The technical problem to be achieved by the present invention is to automatically apply several levels of vibration to the subject by a vibrator step by step in order to quantitatively evaluate the subject's vibration sensation, and to vibrate the patient according to the subject's feedback information about the applied vibration stimulation. After calculating the quantitative sensation value, a quantitative vibration sensation measurement system and method is provided to provide information on the presence or absence of abnormality and expected disease information according to changes in the degree of vibration sensation perception based on the calculated quantitative vibration sensation value.

According to an embodiment of the present invention for achieving this technical task, a quantitative vibration sensation measurement system includes a vibrator that applies vibration stimulation divided into a plurality of stages according to the intensity of vibration to the subject, and whether the stimulation is recognized according to feedback information input by the subject. a subject response device that generates a feedback signal for, and receives stimulation application information related to the vibrator operation from the vibrator, calculates a quantitative vibration sensation value according to the feedback signal received from the subject response device, and then calculates the calculated vibration sensation. It includes a measuring device that inputs quantitative values and the subject's personal characteristic information into a prediction model to provide information on the presence or absence of abnormalities and expected diseases according to changes in the degree of perception of vibration sensation.

The vibrator may apply, as the first vibration stimulation, a level of vibration stimulation lower than the lowest point of the normal vibration sensory threshold range for each age group by a preset value according to age information input by the user.

Here, the entire range of vibration intensity of the vibration stimulation and the vibration intensity of each stage of the vibration stimulation can be determined by considering personal characteristic information including the vibration sensation measurement site and the subject's age, body fat, and muscle mass.

The measuring device includes an information receiving unit that receives stimulation application information from the vibrator, extracts a threshold value by matching a feedback signal received from the subject response device with the stimulation application information, and personal characteristic information, and bases the extracted threshold value on the basis. An analysis unit that calculates a quantitative vibration sensation value, a control signal generator that generates a control signal that changes the stimulation level using the feedback signal and transmits it to the vibrator, and learns the quantitative vibration sensation value and the subject's personal characteristic information. It includes a result provision unit that inputs the completed prediction model to provide information on the presence or absence of abnormalities and expected diseases according to changes in the degree of sensory perception.

The analysis unit obtains information about the stimulation level applied at the current time, and if a feedback signal is received within a preset time from the point when the stimulation was applied, it determines that the subject has recognized the stimulation, and sends a feedback signal within the preset time. If it is not received, it can be determined that the subject did not perceive the stimulus.

If the analysis unit determines that the subject does not perceive stimulation at a specific stage, the control signal generator causes the vibrator to apply stimulation corresponding to a stage that is higher than the specific stage by a preset level, and the analysis unit If it is determined that the subject has recognized stimulation in the upward stage, the control signal generator may cause the vibrator to re-apply stimulation corresponding to the specific stage.

After re-applying the stimulus corresponding to the specific stage, if the analysis unit determines that the subject has recognized the stimulus at the specific stage, the specific stage is determined as a threshold value, and the analysis unit determines that the subject has recognized the stimulus at the specific stage. If it is determined that the subject does not perceive the stimulus, the control signal generator can obtain whether the subject perceives the stimulus by applying the stimulus in one step higher than the specific level.

The result provider inputs the quantitative vibration sensation generated for each body part to which stimulation is applied and the subject's personal characteristic information into the prediction model to extract results regarding the presence or absence of abnormalities for each body part, and predict diseases according to the presence or absence of abnormalities for each body part. Information can be provided.

In addition, according to an embodiment of the present invention, a quantitative vibration sensation measurement method using a quantitative vibration sensation measurement system includes receiving stimulation application information from a vibrator, a feedback signal received from a subject response device, the stimulation application information, and personal characteristic information. Extracting a threshold value by matching, calculating a quantitative vibration sensation value based on the extracted threshold value, generating a control signal to change the stimulation level using the feedback signal and transmitting it to the vibrator, and It includes the step of inputting the quantitative value of vibration sensation and the subject's personal characteristic information into a predicted model that has completed learning, and providing information on the presence or absence of abnormalities and expected disease information according to changes in the degree of sensory perception.

In this way, according to the present invention, the results of vibration sensation can be quantified, thereby minimizing the difference in test results depending on the operator, and the subjective results of neurological examination can be quantified, making it possible to better understand the patient's vibration sensation. It is efficient, can be evaluated quantitatively, makes it easier for medical personnel to diagnose, and can accurately determine the patient's degree of recovery or deterioration.

1 is a configuration diagram illustrating a quantitative vibration sensation measurement system according to an embodiment of the present invention.
FIG. 2 is a configuration diagram for explaining the vibrator shown in FIG. 1.
FIG. 3 is a configuration diagram of the measuring device shown in FIG. 1.
Figure 4 is a flowchart for explaining a quantitative vibration sensation measurement method using a quantitative vibration sensation measurement system according to an embodiment of the present invention.
Figure 5 is an example diagram for explaining the relationship between the time when a stimulus is applied and the time when a feedback signal is received in step S430 shown in Figure 4.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

Then, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention.

Hereinafter, the quantitative vibration sensation measurement system according to an embodiment of the present invention will be described in more detail using FIG. 1.

FIG. 1 is a configuration diagram for explaining a quantitative vibration sensation measurement system according to an embodiment of the present invention, and FIG. 2 is a configuration diagram for explaining the vibrator shown in FIG. 1.

As shown in FIG. 1, the quantitative vibration sensation measurement system according to an embodiment of the present invention includes a vibrator 100, a subject response device 200, and a measurement device 300.

First, the vibrator 100 represents a device that applies vibration stimulation to a part of the subject's body.

More specifically, as shown in FIG. 2, the vibrator 100 includes a manipulation unit 110, a vibration generator 120, a vibration application unit 130, a control unit 140, and a display unit 150. do.

The manipulation unit 110 is formed in the form of a button on the body of the vibrator 100, and receives manipulation signals related to vibration generation and vibration level adjustment according to the user's manipulation.

The vibration generator 120 generates vibration according to a control signal from the controller 140, which will be described later, and generates vibration in stages.

Meanwhile, the vibration generator 120 divides the degree of vibration stimulation into a plurality of stages according to the vibration intensity and generates stimulation according to the control signal, and the normal vibration sensation threshold value range for each age group according to the age information input by the user. A vibration stimulus at a level lower than the lowest point by a preset value is generated as the first vibration stimulus.

In addition, the entire range of vibration intensity of the vibration stimulation and the vibration intensity of each stage of the vibration stimulation can be determined by considering personal characteristic information including the vibration sensation measurement site and the subject's age, body fat, and muscle mass. In this case, the intensity of vibration at each stage may be determined to be linearly or non-linearly proportional to each stage.

The vibration applicator 130 is used to apply vibration generated by the vibration generator 120 to the subject, and may be configured to be detachably attached to one end of the vibrator 100. Additionally, the vibration applicator 130 may be ergonomically formed according to the area where vibration is applied to the subject (eg, elbow, etc.).

The control unit 140 generates stimulation application information according to the vibration stimulation, transmits the generated stimulation application information to the measurement device 300, and controls the vibration stimulation stage according to the control signal received from the measurement device 300.

Lastly, the display unit 150 displays information related to the vibrator operation, for example, information about the vibration generated.

The subject response device 200 generates a feedback signal as to whether the stimulus is recognized according to feedback information input by the subject, and transmits the generated feedback signal to the measurement device 300. To explain this again, the subject inputs whether or not he or she recognizes the applied vibration through a button. When the button is pressed, the subject response device 200 generates a feedback signal and transmits the generated feedback signal to the measurement device 300.

The measuring device 300 receives stimulation application information related to the vibrator operation from the vibrator 100, calculates a quantitative vibration sensation value according to the feedback signal received from the subject response device 200, and then calculates a quantitative vibration sensation value. By inputting the subject's personal characteristic information into the prediction model, the presence or absence of abnormalities and expected disease information are provided according to changes in the degree of perception of vibration sensation.

FIG. 3 is a configuration diagram of the measuring device shown in FIG. 1.

As shown in FIG. 3, the measurement device 300 includes an information receiving unit 310, an analysis unit 320, a control signal generating unit 330, and a result providing unit 340.

The information receiver 310 receives stimulation application information from the vibrator 100.

The analysis unit 320 extracts a threshold value by matching the feedback signal received from the subject response device 200 with the stimulus application information and personal characteristic information, and calculates a quantitative vibration sensation value based on the extracted threshold value.

The control signal generator 330 generates a control signal that changes the level of stimulation using the feedback signal and transmits it to the vibrator 100.

The result providing unit 340 inputs the quantitative vibration sensation value and the subject's personal characteristic information into the learned prediction model to provide abnormality information and expected disease information according to changes in the degree of sensory perception.

Hereinafter, the quantitative vibration sensation measurement method using the quantitative vibration sensation measurement system according to an embodiment of the present invention will be described in more detail using FIGS. 4 and 5.

Figure 4 is a flowchart for explaining a quantitative vibration sensation measurement method using a quantitative vibration sensation measurement system according to an embodiment of the present invention.

As shown in FIG. 4, the measuring device 300 according to an embodiment of the present invention receives stimulation application information from the vibrator 100 (S410).

The vibration stimulation stage of the vibrator 100 consists of a plurality of stages (eg, stages 1 to 20). To elaborate, vibration sensation can be measured in the frequency range of 60Hz to 256Hz. However, since the threshold of vibration sensation may vary depending on the frequency, the entire range of vibration intensity of vibration stimulation and the vibration intensity of each stage of vibration stimulation are can be decided. In this case, the intensity of vibration at each stage may be determined to be linearly or non-linearly proportional to each stage.

With the stage for vibration stimulation set as above. The examiner operates the vibrator 100 while positioning the vibrator 100 on the subject's body measurement area. At this time, the vibrator 100 generates, as the first vibration stimulus, a vibration stimulus at a level lower than a preset value than the lowest point of the input normal vibration sensory threshold range for each age group of the subject. For example, assuming that there are 6 levels of stimulation that can be classified as normal depending on the subject's age, the vibrator 100 generates 2 levels of stimulation.

Then, the vibrator 100 generates vibration and simultaneously generates stimulation information, and transmits the generated stimulation information to the measurement device 300.

Here, the stimulation application information refers to vibration stimulation-related information including the applied stimulation stage, stimulation frequency, and stimulation application time.

Next, the measuring device 300 receives a feedback signal from the subject response device 200 (S420).

When the subject recognizes stimulation generated from the vibrator 100, he or she presses a button included in the subject response device 200. Then, the subject response device 200 generates a feedback signal and transmits it to the measurement device 300.

When step S420 is completed, the measurement device 300 extracts a threshold value by matching the received feedback signal with the stimulus application information and personal characteristic information (S430).

Figure 5 is an example diagram for explaining the relationship between the time when a stimulus is applied and the time when a feedback signal is received in step S430 shown in Figure 4.

As shown in FIG. 5, the analysis unit 320 obtains information about the stage of the stimulus applied at the current time from the received stimulus application information and determines whether a feedback signal is received within a preset time from the time the stimulus is applied. Determine whether or not For example, assuming that the stimulus application time is 2 seconds and the subject's reaction time to the stimulus is 4 seconds, the analysis unit 320 determines whether a feedback signal is received within the reaction time of 4 seconds.

At this time, the time for which stimulation is applied and the reaction time may be set differently depending on the stimulation frequency and intensity.

If the feedback signal is received within a preset time from when the stimulus is applied, the analysis unit 320 determines that the subject has recognized the stimulus, and if the feedback signal is not received within the preset time, the subject does not perceive the stimulus. It is judged as not possible.

If the analysis unit 320 determines that the subject does not perceive stimulation at a specific stage, the control signal generator 330 applies stimulation corresponding to a stage in which the vibrator 100 is higher than the specific stage by a preset level. Let's do it.

Thereafter, when the analysis unit 320 determines that the subject has recognized the stimulation at the upgraded level, the control signal generator 330 causes the vibrator 100 to re-apply the stimulation corresponding to the specific level.

After re-applying the stimulus corresponding to the specific step, if the analysis unit 320 determines that the subject has recognized the stimulus at the specific step, the specific step is determined as the threshold value.

On the other hand, if the analysis unit 320 determines that the subject does not perceive the stimulus at a specific stage, the control signal generator 330 applies the stimulus in one step higher than the specific stage to obtain whether the subject perceives the stimulus. do.

For example, assume that the subject is in his 30s and that the level of stimulation that can be judged normal is level 6. Then, the vibrator 100 sets stage 2 as the initial stimulation stage and generates vibration.

If the feedback signal is not received within a preset time from when the second-level vibration is generated, the control signal generator 330 generates a control signal for generating the fourth-level vibration and transmits it to the vibrator 100.

If the feedback signal is not received within a preset time from when the 4-level vibration is generated, the control signal generator 330 generates a control signal for generating the 6-level vibration and transmits it to the vibrator 100.

If a feedback signal is received within a preset time from when the 6-level vibration is generated, the analysis unit 320 determines that the subject has recognized the stimulus, and the control signal generator 330 generates the 4-level vibration again. A control signal is generated and transmitted to the vibrator 100.

When the feedback signal is received again within a preset time from when the 4th level of vibration is generated, the analysis unit 320 determines the threshold value for the 4th level of stimulation.

At this time, if the feedback signal is not received within a preset time from when the 4th level of vibration is generated again, the control signal generator 330 applies stimulation at a level higher than the current stimulation level to determine whether or not the subject is aware of the stimulation. judge.

When step S430 is completed, the analysis unit 320 extracts a quantitative vibration sensation value using the threshold value obtained for each body measurement part (S440).

Since the degree of stimulus perception is different depending on the body measurement area, different threshold values are extracted for each. Accordingly, the analysis unit 320 can extract a quantitative vibration sensation value in the form of a pattern using the threshold value obtained for each body measurement part.

Next, the result provider 340 extracts result information by inputting the extracted quantitative vibration sensation value and personal characteristic information into the learned prediction model (S450).

Here, the prediction model uses the vibration sensation quantitative value and the subject's personal characteristic information as input values, and is trained in advance to output a result on the presence or absence of abnormality for each body part in response to the subject's stimulation. A prediction model is built based on one algorithm among several algorithms that can be applied by a person skilled in the art.

Accordingly, the prediction model outputs a result on the presence or absence of abnormality for each body part in response to stimulation using the received quantitative vibration sensation value and personal characteristic information, and based on this, the result providing unit 340 determines the presence or absence of abnormality for each body part. Provides information on anticipated diseases.

For example, if it is determined that sensory abnormality has occurred in the big toe and the top of the foot, the result providing unit 340 provides information about diabetes causing peripheral nerve abnormality.

In this way, the quantitative vibration sensation measurement system according to the present invention can quantify the result value of the vibration sensation, thereby minimizing the difference in test results depending on the measurer, and can quantify the results of neurological examination that had been subjectively performed, so that the patient Vibration sensation can be evaluated more efficiently and quantitatively, making it easier for medical personnel to diagnose and accurately identify the patient's degree of recovery or deterioration.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

100: vibrator
110: control panel
120: Vibration generator
130: Vibration approving unit
140: control unit
150: display unit
200: Subject response device
300: measuring device
310: Information receiving unit
320: analysis department
330: Control signal generator
340: Result provision section

Claims (9)

A vibrator that applies vibration stimulation divided into multiple stages according to the intensity of vibration to the subject,
A subject response device that generates a feedback signal as to whether the stimulus is recognized according to feedback information input by the subject, and
Stimulation application information related to the vibrator operation is received from the vibrator, a quantitative vibration sensation value is calculated according to the feedback signal received from the subject response device, and the calculated vibration sensation quantitative value and the subject's personal characteristic information are entered into the prediction model. A quantitative vibration sensation measurement system that includes a measuring device that provides information on the presence or absence of abnormalities and expected disease information according to changes in the degree of vibration sensation perception. According to paragraph 1,
The vibrator is a quantitative vibration sensation measurement system that applies vibration stimulation at a level lower than the lowest point of the normal vibration sensation threshold range for each age group as the first vibration stimulation according to the age information input by the user. According to paragraph 1,
A quantitative vibration sensation measurement system in which the entire range of vibration intensity of vibration stimulation and the vibration intensity of each stage of vibration stimulation are determined by considering personal characteristic information including the vibration sensation measurement area and the subject's age, body fat, and muscle mass. According to paragraph 1,
The measuring device is,
An information receiving unit that receives stimulation application information from the vibrator,
An analysis unit that extracts a threshold value by matching the feedback signal received from the subject response device with the stimulus application information and personal characteristic information, and calculates a quantitative vibration sensation value based on the extracted threshold value;
A control signal generator that generates a control signal that changes the stimulation level using the feedback signal and transmits it to the vibrator, and
A quantitative vibration sensation measurement system including a result providing unit that inputs the quantitative vibration sensation value and the subject's personal characteristic information into a learned prediction model to provide information on the presence or absence of abnormalities and expected disease information according to changes in the degree of sensory perception. According to paragraph 4,
The analysis unit,
If information about the stimulus level applied at the current time is obtained and a feedback signal is received within a preset time from the time the stimulus was applied, it is determined that the subject has recognized the stimulus,
A quantitative vibration sensation measurement system that determines that the subject did not perceive the stimulus if the feedback signal is not received within a preset time. According to clause 5,
If the analysis unit determines that the subject did not recognize the stimulus at a certain stage,
The control signal generator causes the vibrator to apply stimulation corresponding to a level higher than the specific level by a preset level,
If the analysis unit determines that the subject has recognized the stimulus in the upward stage,
The control signal generator is a quantitative vibration sensation measurement system that causes the vibrator to re-apply stimulation corresponding to the specific step. According to clause 6,
After re-applying the stimulus corresponding to the specific step,
If the analysis unit determines that the subject has recognized the stimulus at the specific stage, the specific stage is determined as a threshold value,
If the analysis unit determines that the subject did not perceive the stimulus in the specific step,
A quantitative vibration sensation measurement system in which the control signal generator applies stimulation at one level higher than the specific level to obtain whether the subject perceives the stimulation. According to paragraph 3,
The result provision department,
Quantitative values of vibration sensation generated for each stimulus-applied body part and personal characteristic information of the subject are input into the prediction model to extract results regarding the presence or absence of abnormalities for each body part, and provide quantitative information on expected diseases according to the presence or absence of abnormalities for each body part. Vibration sensation measurement system. In the quantitative vibration sensation measurement method using a quantitative vibration sensation measurement system,
Receiving stimulation application information from the vibrator,
extracting a threshold value by matching the feedback signal received from the subject's response device with the stimulus application information and personal characteristic information, and calculating a quantitative vibration sensation value based on the extracted threshold value;
Generating a control signal that changes the stimulation level using the feedback signal and transmitting it to the vibrator, and
A quantitative vibration sensation measurement method comprising the step of inputting the quantitative vibration sensation value and the subject's personal characteristic information into a learned prediction model to provide information on the presence or absence of abnormality and expected disease according to changes in the degree of sensory perception.