JP6658077B2 - How to assess stumbling risk - Google Patents

Description

  The present invention relates to a method for evaluating a risk of stumbling from a minimum toe clearance during walking and an apparatus therefor.

  In walking, the period from the heel landing of one foot to the next heel landing of the foot is referred to as one walking cycle, and the period from toe landing to the next heel landing of the foot is referred to as a free leg period. The distance between the toe and the ground in the swing phase is the toe clearance, and the minimum value of the toe clearance in the middle swing phase is the minimum toe clearance. Measuring the minimum toe clearance can assess the risk of stumbling during walking.

  Conventionally, the measurement of toe clearance has been performed using a motion capture system, but the motion capture system is expensive and the measurement method is complicated. On the other hand, the regression equation was obtained by performing multiple regression analysis using the floor reaction force data measured by the floor reaction force meter in the horizontal direction, the front-rear direction, and the vertical direction as explanatory variables, and the minimum toe clearance normalized by height as the objective variable. , And using the regression equation to estimate the minimum toe clearance from the floor reaction force data for any subject and compare the estimated value to a predetermined threshold, or the magnitude of the variance in the estimated value, to reduce the risk of stumbling. An evaluation method has been proposed (Patent Document 1).

  On the other hand, when the dorsiflexion force decreases, the toes hang down during the swing phase and stumbling is induced, so an accelerometer is attached to the waist and from the kicking out of one leg to the middle stage of standing with only the other leg Find the average acceleration in the back and forth direction of the waist, obtain the relationship between the average acceleration and the dorsiflexion force, estimate the dorsiflexion force from the waist acceleration for any subject using that relationship, It is proposed to take measures (Patent Document 2)

JP 2013-138873 A JP 2007-125368 A

  In the method described in Patent Literature 1, in order to obtain floor reaction force data of the subject's walking, it is necessary to have the subject walk the floor reaction force meter at an examination hall for a walking characteristic or the like. However, the floor reaction force data obtained in this manner does not always represent the subject's daily walking characteristics. Therefore, it is difficult for this method to evaluate a subject's daily trip risk.

  In the method described in Patent Literature 2, when estimating the dorsiflexion force, the acceleration of the waist is measured by an accelerometer attached to the waist, so that the acceleration of the subject in daily walking can be measured. However, since this method does not directly estimate the minimum toe clearance, but estimates the dorsiflexion force at which a stumbling is induced by a decrease, the accuracy of evaluating the stumbling risk is inferior.

  On the other hand, an object of the present invention is to accurately estimate a minimum toe clearance using an accelerometer attached to the waist and to evaluate a risk of tripping.

  When estimating the minimum toe clearance by multiple regression analysis using the acceleration parameter derived from the acceleration measured by the accelerometer mounted on the waist as an explanatory variable, the acceleration in a specific period within one walking cycle is minimized. Based on the idea that there is a strong relationship with toe clearance, one walking cycle of the measured acceleration is time-divided, and a time-divided acceleration that has a high correlation with the minimum toe clearance is used as an acceleration parameter. The present inventors have found that the accuracy of estimating the minimum toe clearance is remarkably improved, and arrived at the present invention.

That is, the present invention, the minimum toe clearance purposes variable, the longitudinal direction of the waist in walking, using a regression equation including the explanatory variable acceleration parameters derived from the left and right direction and the vertical direction of the acceleration, the subjects' right leg Or, calculating the minimum toe clearance for the left foot, a stumbling risk evaluation method to evaluate the stumbling risk,
As the acceleration parameter, for the foot for which the minimum toe clearance is to be estimated, an acceleration selected from the acceleration in the middle of the stance phase in one walking cycle, the acceleration in the mid-leg support phase, the acceleration in the first half of the swing phase, and the acceleration in the second half of the swing phase is used. Provides a method of assessing stumbling risk.

  In particular, the present invention provides the method for evaluating a stumbling risk as described above, wherein the acceleration parameter includes, as an acceleration parameter, a lateral acceleration in a middle stance phase in one walking cycle, a longitudinal acceleration in a mid-legs support phase, and a longitudinal acceleration in a first half of a swing phase. And the method of using the acceleration in the left-right direction, and the acceleration in the front-rear direction and the left-right direction in the latter half of the swing period, and as an acceleration parameter, further, from the heel landing to the next heel landing for the foot for which the minimum toe clearance is estimated. Use the principal component score calculated by the principal component analysis of the acceleration in the front-rear direction, the left-right direction, and the vertical direction at a predetermined time interval in one walking cycle of the walking cycle, and having a high correlation with the actually measured minimum toe clearance. Provide a way.

Further, the present invention is a minimum toe clearance estimating apparatus for estimating the minimum toe clearance from the acceleration of the waist of the subject during walking,
An acceleration sensor carried by the subject, and an arithmetic unit that calculates and outputs the minimum toe clearance using the acceleration measured by the acceleration sensor,
The acceleration sensor can measure the acceleration in the front-rear direction, the left-right direction, and the vertical direction of the subject while walking,
The arithmetic unit has a function of storing the above-described regression equation,
For foot to estimate the minimum toe clearance, it functions the acceleration of 1 walking period from the heel landing until the next heel wear land by dividing time to get the acceleration of a predetermined time interval,
From the acceleration at the predetermined time interval, an acceleration selected from the acceleration parameters of the regression equation, ie, the acceleration in the middle stance phase, the acceleration in the mid-leg and foot support phase, the acceleration in the first half of the swing phase, and the acceleration in the second half of the swing phase is extracted. function,
A function of calculating the minimum toe clearance using the extracted acceleration in the regression equation,
And an apparatus for estimating a minimum toe clearance.

  According to the stumbling risk evaluation method of the present invention, the minimum toe clearance can be easily and accurately estimated using the waist acceleration during walking, and the stumbling risk is accurately evaluated based on the estimated minimum toe clearance. can do.

  According to the toe clearance estimating apparatus of the present invention, the minimum toe clearance is calculated by the method of calculating the minimum toe clearance used by the stumbling risk evaluation method of the present invention using an acceleration sensor attached to the waist, and output. can do.

  Therefore, the present invention is useful for knowing a stumbling risk in daily life and taking a stumbling prevention measure.

FIG. 1 is an explanatory diagram of one walking cycle. FIG. 2 is a relationship diagram between the 21st principal component score and the minimum toe clearance. FIG. 3 is a diagram showing the relationship between the 24th principal component score and the minimum toe clearance. FIG. 4 is a relationship diagram between the measured value and the estimated value of the minimum toe clearance. FIG. 5 is a relationship diagram between the measured value and the estimated value of the minimum toe clearance according to the comparative example. FIG. 6 is a diagram illustrating the relationship between the measured value and the estimated value of the minimum toe clearance in the model building group of the example. FIG. 7 is a relationship diagram between the measured value and the estimated value of the minimum toe clearance in the model evaluation group of the example.

  Hereinafter, the present invention will be described in detail with reference to the drawings.

<Overview>
In the method for evaluating a stumbling risk of the present invention, a regression equation including, as an explanatory variable, an acceleration parameter derived from the acceleration of the waist in the front-rear direction, the left-right direction, and the vertical direction during walking with the minimum toe clearance as an objective variable is used. Then, the minimum toe clearance of any subject is calculated, and the risk of stumbling is evaluated.

  Here, the minimum toe clearance refers to the distance when the distance between the toe and the ground is shortest in the middle stage of the swing. This minimum toe clearance includes not only its physical quantity, but also standardized by height or weight, or both. Since the minimum toe clearance is the height of the toes in the middle stage of swing, it is considered that the minimum toe clearance is affected by the body mass. Therefore, if the minimum toe clearance is standardized by body weight, the accuracy of estimating the minimum toe clearance by the regression equation can be improved.

<Regression equation>
As the regression equation used in the present invention, it is preferable to use a regression equation obtained by performing a multiple regression analysis using the minimum toe clearance as an objective variable and the acceleration parameter as an explanatory variable.

  The acceleration parameters used in this regression equation are derived from the acceleration of the waist in walking in the front-rear direction, the left-right direction, and the vertical direction measured for a plurality of subjects. The acceleration can be measured by a three-axis acceleration sensor attached to the waist of each subject. On the other hand, the minimum toe clearance can be measured by motion capture, and is measured every left and right one-direction cycle.

  The acceleration parameters include at least (a) the acceleration in the middle stance phase in one walking cycle, the acceleration in the mid-legs support phase, the acceleration in the front-rear direction in the first half of the swing phase, and the swing phase in the walking phase for the foot for which the minimum toe clearance is estimated. Include the acceleration selected from the second half acceleration.

  In addition, as the acceleration parameter, (b) a principal component score obtained by performing principal component analysis on acceleration at predetermined time intervals obtained by time-dividing the measured acceleration, and a correlation with the minimum toe clearance is obtained. It is preferable to use a higher one in combination. By using the two types of acceleration parameters (a) and (b), the accuracy of estimating the minimum trip risk can be significantly increased.

Among them, as the acceleration parameter (a), it is preferable to use acceleration selected from the following (a1) to (a6), and it is particularly preferable to use all of (a1) to (a6).
(a1) The acceleration in the left-right direction in the middle of the stance phase in one walking cycle from the heel landing to the next heel landing, preferably, the time rate when one walking cycle is 100% as shown in FIG. (Referred to as time rate) is a lateral acceleration of 20 to 30%.
(A2) Acceleration in the front-rear direction during the mid-foot support period in one walking cycle, preferably in the front-rear direction at a time rate of 50-60%.
(A3) Front-back acceleration in the first half of the swing phase in one walking cycle, preferably front-back acceleration at a time rate of 70 to 75%.
(A4) Horizontal acceleration in the first half of the swing phase in one walking cycle, preferably horizontal acceleration at a time rate of 75 to 80%.
(A5) The longitudinal acceleration in the latter half of the swing phase in one walking cycle, preferably the longitudinal acceleration at a time rate of 90 to 95%.
(A6) Front-back acceleration in the latter half of the swing period in one walking cycle, preferably a left-right acceleration at a time rate of 92 to 100%.

  These accelerations (a1) to (a6) are, for example, when associating the minimum toe clearance of the right foot with the acceleration, the landing of the right foot in the front-back, left-right, or vertical acceleration of the waist measured by the acceleration sensor. One walking cycle is cut out based on the extreme value of the accompanying vertical acceleration, the acceleration of one walking cycle of the right foot is time-divided into acceleration at a predetermined time interval, and the acceleration at a predetermined time interval and the minimum toe in the one walking cycle are calculated. When the correlation coefficient with the clearance is obtained from a large number of subjects, the acceleration is a time rate at which the correlation coefficient becomes preferably 0.25 or more, more preferably 0.4 or more.

  In determining the accelerations (a1) to (a6), when examining the correlation between the acceleration at a predetermined time interval obtained by time-dividing one walking cycle and the minimum toe clearance in the one walking cycle, it is necessary to determine the acceleration of each walking cycle. A predetermined number of one walking cycle may be cut out and a correlation coefficient between the acceleration at a predetermined time interval of each walking cycle and the minimum toe clearance may be calculated. The acceleration and the averaged minimum toe clearance may be calculated, and the correlation coefficient between the averaged acceleration of one walking cycle and the acceleration at a predetermined time interval obtained by time division and the averaged minimum toe clearance may be calculated. The former is preferred from the viewpoint of emphasizing the dispersion of the minimum toe clearance.

  In the time division of the acceleration data in one walking cycle, if the interval is too long, the accuracy of estimating the minimum toe clearance decreases. If the interval is too short, the amount of calculation increases. Is preferred.

  As the accelerations (a1) to (a6), any of the accelerations in the respective time rate ranges may be used as representative values, or the average of the accelerations in the time rate ranges may be used. .

  As the acceleration parameter (a), a combination of the acceleration in the left-right direction, the acceleration in the front-rear direction, and the acceleration in the vertical direction in the range of the time rates (a1) to (a6) may be used.

  As the acceleration parameter of (a), the acceleration in the left-right direction, the acceleration in the front-rear direction, the acceleration in the vertical direction, or the acceleration obtained by combining these in the range of the time rate of (a1) to (a6) is defined as height, weight, or height. Acceleration normalized by both body weights may be used.

  On the other hand, as the acceleration parameter consisting of the principal component score of (b), the acceleration in the front-rear direction, the left-right direction, and the vertical direction measured for the plurality of subjects are time-divided, and the front-rear direction, the left-right direction, and the vertical direction obtained thereby are obtained. Principal component analysis is performed on the acceleration at a predetermined time interval to calculate the principal component score, and the correlation between each principal component score and the measured value of the minimum toe clearance of the foot on which the minimum toe clearance is to be estimated is examined, and the phase relationship is determined. Use the high number of principal component scores. Preferably, one or more principal component scores having a correlation coefficient of 0.25 or more with respect to the measured value of the minimum toe clearance are used.

  In obtaining the acceleration parameter consisting of the principal component score of (b), the acceleration at a predetermined time interval is obtained by cutting out the acceleration data of one walking cycle and dividing it by time similarly to the case of obtaining the acceleration parameter of (a). Obtainable.

  In the present invention, as the explanatory variables of the regression equation for estimating the minimum toe clearance, in addition to the acceleration parameter of (a) described above, preferably the acceleration parameters of (a) and (b), the age, sex, and height of the subject It is more preferable to use an attribute parameter selected from the group consisting of, weight, BMI, and the like. In other words, the regression equation used in the present invention is obtained by performing multiple regression analysis using the above acceleration parameters (a) and (b) and, if necessary, attribute parameters as explanatory variables and minimum toe clearance as an objective variable. Those obtained are preferred. In the multiple regression analysis, it is preferable to select the acceleration parameters (a) and (b) as the explanatory variables and the attribute parameters by a stepwise method.

<Calculation of minimum toe clearance using regression equation>
The minimum toe clearance of any subject is determined by measuring the acceleration of the subject's waist in the front-rear direction, left-right direction, and vertical direction during walking, and obtaining an acceleration parameter that is an explanatory variable of the regression equation. It is calculated by using. The calculated minimum toe clearance is used as an estimated value of the minimum toe clearance of the subject.

  More specifically, for example, when calculating the minimum toe clearance of the right foot, one walking cycle is cut out from the measured waist acceleration by the extreme value of the vertical acceleration accompanying the landing of the right foot, and every one walking cycle It is time-divided to determine acceleration at predetermined time intervals, and at least acceleration parameters (a), preferably (a) and (b), are determined from accelerations at predetermined time intervals. Preferably, the clearance is calculated. As a result, variations in the minimum toe clearance can be seen.

  On the other hand, in obtaining the acceleration parameters of (a) and (b), an acceleration of one walking cycle averaged from a plurality of cut-out accelerations of one walking cycle is obtained, and the averaged acceleration of one walking cycle is time-divided. Thus, the acceleration at predetermined time intervals may be obtained from the acceleration, and the acceleration parameters (a) and (b) may be obtained from the acceleration at predetermined time intervals. The minimum toe clearance calculated from the regression equation using the acceleration parameters thus obtained can be said to be an average of the minimum toe clearances in a plurality of walking cycles. From the viewpoint that emphasis is placed on the variation of the minimum toe clearance, it is preferable to obtain the minimum toe clearance for each cutout walking cycle.

The estimated value of the minimum toe clearance obtained in this way has high estimation accuracy of the minimum toe clearance because at least the acceleration parameter (a) is used as an explanatory variable of the regression equation for calculating the minimum toe clearance, and in particular, (a) and (b) When the two types of acceleration parameters are used, the accuracy of estimating the minimum toe clearance is remarkably improved as compared with the case where one of the acceleration parameters is an explanatory variable. The determination coefficient indicating the degree of correlation between the estimated value of the toe clearance and the actually measured value can be 0.4 or more.
Therefore, according to the present invention, the stumbling risk can be evaluated based on the estimated value of the minimum toe clearance.

<Evaluation of stumbling risk>
As a specific embodiment of the method of evaluating the stumbling risk based on the minimum toe clearance, for example, a relationship between the minimum toe clearance and the ease of stumbling is checked in advance, and the minimum toe clearance in the case of evaluating the ease of stumbling stepwise is evaluated. By setting a threshold value and comparing the estimated value of the minimum toe clearance of any subject to the threshold value, the subject's ease of tripping can be evaluated stepwise.

  The average of the minimum toe clearance may be calculated for each predetermined time period, and the risk of stumbling may be compared for each time period. As the average of the minimum toe clearance, a value obtained by dividing the integrated value of the minimum toe clearance for each walking cycle of the walking in the time period by the number of stride of walking in the time period (that is, the number of steps) can be used.

  Further, since it is known that if the variation in the minimum toe clearance is large, it is easy to trip, the variation in the minimum toe clearance may be calculated for each predetermined time period, and the risk of tripping may be evaluated based on the variation. As the variation, a standard deviation, a variance, or the like can be used.

  By knowing the minimum toe clearance or its variation for each predetermined time period, for example, a person who advises the subject on how to walk can provide the subject with advice according to the time period of the day. Become.

<Minimum toe clearance estimation device>
For any subject, the minimum toe clearance estimating device for estimating the minimum toe clearance from the measurement of the acceleration of the waist may be a device that is portable in daily life so that the minimum toe clearance in daily walking can be estimated. preferable.

  Therefore, the minimum toe clearance estimating device of the present invention includes an acceleration sensor carried by the subject, and a calculation device that calculates and outputs the minimum toe clearance using acceleration measured by the acceleration sensor, and further includes an as needed. A display for displaying the calculated toe clearance is provided. Note that the minimum toe clearance calculated by the arithmetic device may be output to a mobile phone, a printer, or the like.

  In this device, an acceleration sensor that can measure the acceleration of the walking subject in the front-back direction, the left-right direction, and the vertical direction is used. As such an acceleration sensor, a portable terminal capable of extracting acceleration waveforms of three axes of XYZ can be cited.

The arithmetic unit has a function of storing the above-described regression equation for calculating the minimum toe clearance,
The legs of estimating the minimum toe clearance of the left and right feet, the ability acceleration of 1 walking period from the heel landing to the next heel deposition locations by dividing the time to obtain the acceleration of the predetermined time interval,
A function of extracting, from the acceleration at the predetermined time interval, an acceleration in a predetermined time rate range, which is an acceleration parameter of the regression equation;
It has a function of calculating a minimum toe clearance by using the extracted acceleration and the calculated principal component score in the regression equation, and outputting it as an estimated value of the minimum toe clearance.

  In addition to these functions, the arithmetic device has a function of extracting acceleration in a desired direction at a predetermined time rate and a function of calculating a principal component score, which is a regression-type acceleration parameter, using acceleration at predetermined time intervals. It is also preferred to have

  Among these, as a specific mode of the function of acquiring the acceleration at a predetermined time interval, a plurality of accelerations in one walking cycle are cut out and cut out from the respective accelerations in the front-rear direction, the left-right direction, or the vertical direction measured by the acceleration sensor. It is preferable that the acceleration is time-divided for each walking cycle to obtain acceleration at predetermined time intervals. Further, the acceleration of one walking cycle averaged from the accelerations of a plurality of walking cycles may be calculated, and the acceleration at a predetermined time interval may be obtained from the averaged acceleration of one walking cycle.

  Instead of the acceleration for each component of the front-rear direction, the left-right direction, and the vertical direction, three directions may be collectively set as a vector, and the magnitude of the vector may be used as an acceleration parameter.

  The arithmetic unit may be provided with a function of calculating the average and the variation of the minimum toe clearance of walking in a predetermined time zone, and these may be output.

  Further, the arithmetic unit has a function of evaluating a stumbling risk based on the minimum toe clearance calculated using the regression equation, the average of the minimum toe clearance, or the variation of the minimum toe clearance, so that the evaluation result is output. Is also good. That is, the above-described method of evaluating the stumbling risk may be performed by this function.

Hereinafter, the present invention will be specifically described based on examples.
Example 1
(1) Acquisition of regression equation 133 subjects (74 men and 59 women) between 20 and 73 years old who can walk on their own without pain when walking were used. Subjects were instructed to refrain from excessive exercise and drinking the previous day.

  A reflection marker is attached to the subject's waist to measure the acceleration of the subject's waist in the front-rear direction, the left-right direction, and the vertical direction, and the position of the marker during walking in each time zone is measured by a motion capture system (Vicon MX manufactured by Vicon Corporation). Acceleration was calculated based on waist position information by measuring with the system, Vicon Nexus).

Pre-processing for constructing a model for obtaining a regression equation was performed in the following procedure.
1) A 4th-order Butterworth low-pass filter was applied to the measured raw data of the marker coordinates of all subjects to remove noise. The cutoff frequency was 10 Hz.
2) Three-axis acceleration of the hip (sacrum) was extracted. The acceleration was obtained by differentiating the marker coordinates twice.

  One walking cycle is cut out from the measured three-axis direction acceleration by the extreme value of the vertical acceleration associated with the landing of the right foot, and the acceleration of one walking cycle is divided into 101 equal parts (at intervals of about 10 msec) to obtain a total. An acceleration component of 303 (time rate 0 to 100%) was obtained. By performing principal component analysis using a variance-covariance matrix, which is one of the multivariate analysis methods, for the acceleration components in the three axial directions, a total of 26 principal acceleration components are extracted. The principal component score was calculated by multiplying the principal component score coefficients and taking the sum of them.

  In addition, by attaching a reflective marker to the first metatarsal of the right leg of the same subject and measuring the position of the marker during walking in each time zone with a motion capture system (Vicon MX system, Vicon Nexus manufactured by Vicon), 1 The minimum toe clearance of the walking cycle was measured.

  The correlation between the principal component score of each acceleration principal component and the minimum toe clearance was examined, and the 21st and 24th principal components having high correlation were extracted. FIG. 2 shows the relationship between the 21st principal component score and the minimum toe clearance, and FIG. 3 shows the relationship between the 24th principal component score and the minimum toe clearance.

  On the other hand, for each of the acceleration components 303, the correlation with the measured value of the minimum toe clearance was examined, and the acceleration component of the time rate at which the correlation coefficient was 0.25 or more was selected.

  In addition, standardized numerical values of 0 mean and 1 variance were given for each subject's gender.

  Multiple regression analysis (stepwise method) using the minimum toe clearance as the objective variable, the gender of each subject, the acceleration component having the above-mentioned correlation coefficient of 0.25 or more, the 21st principal component score, and the 24th principal component score as explanatory variables And the following regression equation was obtained. In the equation, Xt% represents acceleration at a time rate t% in the left-right direction, and Yt% represents acceleration at a time rate t% in the front-rear direction.

Minimum toe clearance (cm)
= 4.464 + (sex) x 0.367 + (X24%) x (-0.018) + (Y53%) x (-0.018) + (Y71%) x (-0.017) + (X77%) x (-0.042) + ( Y94%) x (0.007) + (X95%) x (-0.019) + (21st principal component score) x (0.056) + (24th principal component score) x (-0.054)

FIG. 4 shows the relationship between the estimated value of the minimum toe clearance calculated from the regression equation and the measured value of the minimum toe clearance. Determination coefficient R ² indicating the degree of correlation is 0.421, it is understood that the estimation accuracy of the minimum toe clearance by the regression equation is high.

(2) Estimation of minimum toe clearance for each time zone A 28-year-old man who can walk on his / her own irrespective of acquisition of the regression equation was set as a subject, and the subject's daily life was from 0:00 to 3:00, 3:00 to 3:00 Acceleration can be measured every time period from 6:00, 6:00 to 9:00, 9:00 to 12:00, 12:00 to 15:00, 15:00 to 18:00, 18:00 to 21:00, and 21:00 to 24:00. With respect to walking with the number of strides, accelerations in X (left and right directions), Y (front and rear directions), and Z (vertical direction) were measured. Note that 0:00 to 3:00 means from 0:00 to 3:00. The same applies to other time zones.

  For each time zone, one walking cycle is cut out from the measured acceleration, each walking cycle is divided into 101 equal parts, an acceleration component of a time rate of 0 to 100% is obtained, and the minimum toe is obtained from the regression equation using the acceleration component. The clearance (MTC) was calculated, the integrated value of the number of strides for each time zone was obtained, and the average value of the minimum toe clearance (MTC) was obtained by dividing the integrated value by the number of strides for each time zone. In addition, the standard deviation of the minimum toe clearance (MTC) was obtained in order to see the variation of the minimum toe clearance for each time zone. Table 1 shows the results.

  From the results in Table 1, the estimated value of the minimum toe clearance differs for each time zone, and the stumbling risk differs, so that the usefulness of changing advice for stumbling prevention for each time zone can be understood. For example, for the subject who performed the acceleration measurement this time, the estimated value of the minimum toe clearance became higher than that during the day between 6:00 and 9:00 and between 18:00 and 21:00. This is considered to be because the user walks faster than usual when going to work or returning home. On the other hand, the standard deviation of the smallest toe clearance is high between 18:00 and 21:00 when returning home. This means that the risk of stumbling increases most when returning home, and it is important to present measures to prevent the risk of stumbling during this time.

(3) Estimation accuracy of minimum toe clearance in individual subject The minimum toe clearance of the subject in (2) was measured from 12:00 to 15:00 in the same manner as in (1). As a result, the estimated value of (2) was 3.70 cm, whereas the measured value of the minimum toe clearance in daily life was 3.73 cm, confirming that the estimation accuracy was high.

Comparative Example 1
In the multiple regression analysis of (1), the same as in Example 1 except that the principal component score is not used as an explanatory variable and only the acceleration component having a gender and a correlation coefficient of 0.25 or more for each subject is used. The following regression equation was determined. In the formula, Xt% represents the acceleration at the time rate t% in the left-right direction, Yt% represents the acceleration at the time rate t% in the front-rear direction, and Zt% represents the acceleration at the time rate t% in the vertical direction.

Minimum toe clearance (cm)
= 4.617 + (sex) x 0.331 + (Z58%) x (0.009) + (Y64%) x (-0.067) + (Y65%) x (0.173) + (Y66%) x (-0.104) + (X84% ) X (-0.021) + (X85%) x (0.04) + (Y92%) x (-0.092) + (Y93%) x (0.205) + (Y94%) x (-0.1) + (X95%) x (-0.29) + (X96%) x (0.521) + (X97%) x (-0.272)

FIG. 5 shows the relationship between the estimated value of the minimum toe clearance and the measured value of the minimum toe clearance calculated from the regression equation. Determination coefficient R ² indicating the degree of correlation is 0.336, it can be seen that low estimation accuracy of the minimum toe clearance by regression of Comparative Example 1 than in Example 1.

Example 2
(1) Acquisition of regression equation The subjects were 120 healthy adults (63 males and 57 females) from 20 to 77 years old who can walk on their own without pain when walking. Subjects are healthy adults who do not have a history of injury or illness that may affect their walking behavior, and who can walk on two feet without complaining of pain at the time of measurement and without using walking aids or equipment. Met.

  The walking was measured as follows in a laboratory where a tile carpet was laid, which was capable of walking straight about 10 m.

  Using a motion capture system (Vicon MX system, Vicon Nexus manufactured by Vicon), a total of 57 marker coordinates attached to the subject's body surface were measured at 200 Hz. The marker attachment position was based on the Helen Hayes marker set. Subjects walked straight across the walking path barefoot. The walking speed, stride length, line of sight, etc. were not specified, and instructions were given to walk as usual. The start of each trial was verbally signaled by the experimenter. The measurement was performed for at least 5 trials while considering the fatigue of the subject.

  As preprocessing for constructing a model for obtaining a regression equation, noise removal and extraction of three-axis acceleration of the hip (sacral portion) were performed in the same manner as in the first embodiment. Further, the magnitude of the acceleration vector was calculated by adding a gravity component to the acceleration of the three axes of the waist acquired from the marker coordinates.

  Data for one walking cycle was cut out from the waveform of the magnitude of the calculated acceleration vector, and the time was normalized by dividing one walking cycle into 100 equal parts (time rate 0 to 100%). In addition, regarding the acceleration, a total of 303 components were calculated in advance: 101 non-normalized acceleration components, 101 acceleration components normalized by weight, and 101 acceleration components normalized by height. From the above, one measured value of the minimum toe clearance and 303 magnitudes of the waist acceleration vector were obtained as data for one trial.

  A model for estimating the minimum toe clearance from the magnitude of the waist acceleration vector was constructed using data for a total of 600 trials for 120 healthy adults × 5 trials. At that time, 120 subjects were divided into two groups (60 in group A and 60 in B group) so that their ages and genders were homogeneous, and were classified as a “model construction group” and a “model evaluation group”. Since the minimum toe clearance is the height of the toes in the middle stage of swing, it is considered that the minimum toe clearance is affected by the body mass. On the other hand, the pelvis may be close to the center of gravity of the body, and it is considered that the acceleration of the waist is hardly affected by the mass of the body. Therefore, the minimum toe clearance was normalized by body weight to remove the effect of body weight.

  The following regression equation was obtained by using multiple regression analysis (stepwise method) using the above-described vector 303 component as the explanatory variable and the minimum toe clearance in the “model building group” as the objective variable. In the equation, t% represents the magnitude of the acceleration vector at the time rate t%.

Minimum toe clearance (cm)
= 0.055 + (24%: normalized by height) x (-0.009) + (51%: not normalized) x (-0.007) + (99%: not normalized) x (0.002) + (77% : Normalized by weight) x (0.421) + (94%: not normalized) x (0.005)

FIG. 6 shows the relationship between the estimated value of the minimum toe clearance and the measured value of the minimum toe clearance in the model building group calculated from the regression equation. Determination coefficient R ² indicating the degree of correlation is 0.561, it is understood that the estimation accuracy of the minimum toe clearance by the regression equation is high.

  On the other hand, FIG. 7 shows the relationship between the estimated value of the minimum toe clearance and the measured value of the minimum toe clearance in the model evaluation group calculated by the regression equation. The correlation coefficient r is 0.512, which indicates that the estimation accuracy of the regression equation is high.

Claims (17)

Minimum and toe clearance purposes variable, the longitudinal direction of the waist in walking, using a regression equation which includes the left-right direction and the vertical direction of the explanatory variable acceleration parameters derived from the acceleration, the minimum toe clearance for the right foot or left foot of the subjects' Is calculated, and the stumbling risk is evaluated.
As the acceleration parameter, for the foot for which the minimum toe clearance is to be estimated, an acceleration selected from the acceleration in the middle of the stance phase in one walking cycle, the acceleration in the mid-leg support phase, the acceleration in the first half of the swing phase, and the acceleration in the second half of the swing phase is used. How to evaluate stumbling risk.   As acceleration parameters, the acceleration in the left-right direction in the middle of the stance phase in one walking cycle, the acceleration in the front-rear direction during the mid-leg support period, the acceleration in the front-rear direction and the left-right acceleration in the first half of the swing phase, and the front-rear direction in the second half of the swing phase 2. The method for evaluating a stumbling risk according to claim 1, wherein the acceleration in the right and left directions is used.   The acceleration parameter is further calculated by principal component analysis of longitudinal, lateral, and vertical accelerations at predetermined time intervals in one walking cycle from the heel landing to the next heel landing for the foot for which the minimum toe clearance is estimated. The method for evaluating a stumbling risk according to claim 1 or 2, wherein a principal component score, which is a principal component score and has a high correlation with the measured minimum toe clearance, is used.   4. The method for evaluating a stumbling risk according to claim 3, wherein the principal component score has a correlation coefficient with a minimum toe clearance of 0.25 or more.   The method for evaluating a stumbling risk according to claim 1, wherein an acceleration standardized by height or weight is used as the acceleration parameter.   The method for evaluating a stumbling risk according to any one of claims 1 to 5, wherein the minimum toe clearance is standardized by body weight.   The method for evaluating a stumbling risk according to claim 1, wherein the minimum toe clearance is calculated for each walking cycle.   The method for evaluating a stumbling risk according to any one of claims 1 to 7, wherein an average of a minimum toe clearance of walking in a predetermined time zone is calculated.   The method for evaluating a stumbling risk according to any one of claims 1 to 8, wherein a variation in minimum toe clearance of walking during a predetermined time period is calculated.   The regression equation measures the acceleration of the waist in the front-rear direction, the left-right direction, and the vertical direction, and the minimum toe clearance for multiple subjects, and explains the acceleration parameter derived from the measured acceleration using the minimum toe clearance as a target variable. The method for evaluating a stumbling risk according to claim 1, wherein the method is derived by a multiple regression analysis including variables. A minimum toe clearance estimating device for estimating the minimum toe clearance from the acceleration of the waist of the subject during walking,
An acceleration sensor carried by the subject, and an arithmetic unit that calculates and outputs the minimum toe clearance using the acceleration measured by the acceleration sensor,
The acceleration sensor can measure the acceleration in the front-rear direction, the left-right direction, and the vertical direction of the subject while walking,
An arithmetic unit configured to store the regression equation according to claim 1;
For foot to estimate the minimum toe clearance, it functions the acceleration of 1 walking period from the heel landing until the next heel wear land by dividing time to get the acceleration of a predetermined time interval,
From the acceleration at the predetermined time interval, an acceleration selected from the acceleration parameters of the regression equation, ie, the acceleration in the middle stance phase, the acceleration in the mid-leg and foot support phase, the acceleration in the first half of the swing phase, and the acceleration in the second half of the swing phase is extracted. function,
A function of calculating the minimum toe clearance using the extracted acceleration in the regression equation,
Device for estimating the minimum toe clearance. The regression equation stored in the arithmetic unit is defined as acceleration parameters as acceleration parameters in the left-right direction in the middle of the stance phase in one walking cycle, the acceleration in the front-rear direction during the mid-leg support period, the acceleration in the front-rear direction in the first half of the swing phase, and the left-right direction. Including the acceleration in the longitudinal direction and the lateral acceleration in the latter half of the swing phase,
The arithmetic unit calculates the acceleration parameters from the acceleration at a predetermined time interval in one walking cycle to the acceleration in the left-right direction during the middle of the stance phase, the acceleration in the front-rear direction during the mid-leg support period, the acceleration in the front-rear direction in the first half of the swing phase, and the left-right direction. The function of extracting the acceleration in the longitudinal direction and the lateral acceleration in the latter half of the swing period, and the function of calculating the minimum toe clearance using the extracted acceleration in the regression equation,
The minimum toe clearance estimating device according to claim 11, comprising: The regression equation stored in the arithmetic unit is a principal component score calculated by principal component analysis of the acceleration in the front-rear direction, the left-right direction, and the vertical direction at predetermined time intervals in one walking cycle as the acceleration parameter, and the minimum toe Includes principal component scores that are highly correlated with clearance,
The arithmetic unit calculates a principal component score, which is an acceleration parameter, from the acceleration of the subject at a predetermined time interval in one walking cycle, and calculates a minimum toe clearance by using the extracted acceleration and the calculated principal component score in a regression equation. Function to calculate,
The apparatus for estimating a minimum toe clearance according to claim 11 or 12, comprising:   The minimum toe clearance estimating device according to any one of claims 11 to 13, wherein the arithmetic device calculates the minimum toe clearance for each walking cycle.   The minimum toe clearance estimating device according to any one of claims 11 to 14, wherein the arithmetic device has a function of calculating an average of the minimum toe clearance of walking in a predetermined time zone.   The minimum toe clearance estimating device according to any one of claims 11 to 15, wherein the arithmetic device has a function of calculating a variation of the minimum toe clearance of walking in a predetermined time zone.   Arithmetic device, a function to evaluate the stumbling risk based on the minimum toe clearance calculated using the regression equation, or calculate the average of the minimum toe clearance in a predetermined time zone, a function to evaluate the stumbling risk based on the average, The minimum toe clearance estimating apparatus according to any one of claims 11 to 13, further comprising a function of calculating a variation of the minimum toe clearance in a predetermined time zone and evaluating a stumbling risk based on the variation.

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