KR101432871B1 - Measuring method and device of bone density by using dispersion rate of ultrasonic phase velocity - Google Patents

Abstract

The present invention relates to a method and an apparatus for measuring bone density using an ultrasonic phase velocity dispersion ratio, and a method of measuring bone density using an ultrasonic phase velocity dispersion ratio comprises: an ultrasonic wave irradiation step of irradiating ultrasonic waves to a cavernous bone; A converting step of receiving ultrasonic waves passing through the cavernous bone and converting the ultrasonic waves into electric signals; And a bone mineral density measurement step of measuring the bone mineral density of the spongy bone from the ultrasonic wave phase velocity dispersion ratio by calculating the electrical signal converted in the conversion step as an ultrasonic wave phase velocity dispersion ratio; Thereby providing a technique capable of improving the measurement accuracy of the cavernous bone bone density.
In the present invention, measurement of bone density is performed through ultrasound irradiation, so that the patient is not exposed to radiation. That is, the present invention has an effect of providing a safe measurement method to a patient.
In addition, the present invention provides an ultrasonic phase velocity dispersion ratio, which is a new parameter in addition to parameters used in existing quantitative ultrasonic techniques, thereby improving the accuracy of bone density measurement compared to the conventional method of measuring bone density using only sonic velocity and wide- It is effective.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for measuring bone density using an ultrasonic wave phase velocity dispersion ratio,

The present invention relates to a method and an apparatus for measuring bone density using an ultrasonic phase velocity dispersion ratio.

In general, osteoporosis is a disease in which bone fracture due to reduction in bone mass due to bone loss and destruction of bone structure can easily result in fracture even in small impact.

Conventional techniques for diagnosing osteoporosis include simple X-ray imaging, dual energy X-ray absorptiometry, and quantitative ultrasound.

The conventional X-ray or dual energy X-ray absorptiometry is a technique for measuring bone density per unit area of the vertebrae by irradiating low energy and high energy radiation to a patient's body for diagnosis of osteoporosis. However, there is a problem that such a radiation irradiation method may have harmful effects on the human body.

On the other hand, the quantitative ultrasonic technique is a method of diagnosing osteoporosis using ultrasonic waves, and has advantages over conventional methods of diagnosing osteoporosis using X-rays, little influence on the human body, easy use and low price. Quantitative ultrasound technology is a technique that quantifies the bone mineral density (BMD) by measuring the speed of sound (SOS) and broadband ultrasound attenuation (BUA) by irradiating ultrasound to the calcaneus of a human body composed of spongy bone, ) Is indirectly measured to diagnose osteoporosis.

However, the conventional quantitative ultrasonic technique requires additional parameters to improve the measurement accuracy of bone density and bone porosity as the bone density is measured only by the parameters obtained by the measurement by the sonic velocity of the calcaneus and the measurement of the broadband ultrasound attenuation rate .

SUMMARY OF THE INVENTION It is an object of the present invention to provide a technique for improving the accuracy of measurement of marginal bone marrow bone density.

According to an aspect of the present invention, there is provided a method of measuring bone mineral density using an ultrasonic wave phase velocity dispersion ratio, the method comprising: an ultrasonic wave irradiation step of irradiating ultrasonic waves onto a cavernous bone; A converting step of receiving ultrasonic waves passing through the cavernous bone and converting the ultrasonic waves into electric signals; And a bone mineral density measurement step of deriving an ultrasound phase velocity dispersion ratio through the electrical signal converted in the conversion step and measuring the bone mineral density of the spongy bone from the derived ultrasound phase velocity dispersion ratio; And a control unit.

Wherein the bone mineral density of the cavernous bone is measured using the correlation between the ultrasound phase velocity dispersion ratio and the bone mineral density of the cavernous bone.

The correlation between the ultrasonic wave phase velocity dispersion ratio and the bone mineral density of the spongy bone is such that the bone mineral density of the spongy bone is reduced as the ultrasonic phase velocity dispersion ratio increases.

The bone mineral density measuring step may include calculating an ultrasonic wave phase velocity to calculate an ultrasonic wave phase velocity with respect to a frequency function by analyzing the electrical signal to derive the ultrasonic wave phase velocity dispersion ratio through the electrical signal; And deriving the ultrasound phase velocity dispersion ratio by applying the ultrasound phase velocity calculated in the ultrasound phase velocity calculation step to a linear regression analysis method to derive the ultrasound phase velocity dispersion ratio; And a control unit.

의 식을 이용하여 계산되는 것을 특징으로 한다.(여기서, Cp(f)는 주파수 함수에 대한 초음파 위상속도, f는 초음파의 주파수, ΔΦ(f)는 해면질골의 유무에 따라 수신된 초음파 신호의 위상차, d는 해면질골의 두께, Cw는 온도에 의존하는 수중에서의 음속)The ultrasonic phase velocity for the frequency function is

(F) is the frequency of the ultrasonic wave with respect to the frequency function, f is the frequency of the ultrasonic wave, and ?? (f) is the frequency of the received ultrasonic signal according to the presence or absence of the cavernous bone. D is the thickness of cavernous bone, and Cw is the sound velocity in water depending on temperature)

The sound velocity in the temperature-dependent water

의 식을 이용하여 계산되는 것을 특징으로 한다.(여기서, Cw는 온도에 의존하는 수중에서의 음속, T는 섭씨온도)

(Where Cw is the sound velocity in water depending on the temperature, T is the temperature in degrees Celsius)

The method comprising: an output step of outputting a result calculated in the bone mineral density measurement step; And further comprising:

According to another aspect of the present invention, there is provided an apparatus for measuring bone mineral density using an ultrasonic wave phase velocity dispersion ratio, the apparatus comprising: an ultrasonic transmitter for irradiating ultrasonic waves to the spongy bone to measure bone density of the spongy bone; An ultrasonic wave receiving unit for receiving the ultrasonic wave irradiated from the ultrasonic wave transmitting unit; An ultrasonic transducer for transmitting an electric signal to the ultrasonic wave transmitter for ultrasonic wave irradiation or converting the ultrasonic wave received by the ultrasonic wave receiver into an electric signal; A signal processing unit for detecting the electrical signal converted by the ultrasonic conversion unit; An operation unit for calculating an ultrasonic wave phase velocity with respect to a frequency function by analyzing the electric signal detected by the signal processing unit and deriving an ultrasonic wave phase velocity dispersion ratio by applying the ultrasonic wave phase velocity to a linear regression analysis; And a control unit.

Wherein the calculation unit measures the bone mineral density of the cavernous bone using the correlation between the ultrasonic wave phase velocity dispersion and the bone mineral density of the cavernous bone.

The correlation between the ultrasonic wave phase velocity dispersion ratio and the bone mineral density of the spongy bone is such that the bone mineral density of the spongy bone is reduced as the ultrasonic phase velocity dispersion ratio increases.

Wherein the calculation unit calculates an ultrasonic phase velocity for the frequency function by the following equation

에 의해 계산하는 것을 특징으로 한다.(여기서, Cp(f)는 주파수 함수에 대한 초음파 위상속도, f는 초음파의 주파수, ΔΦ(f)는 해면질골의 유무에 따라 수신된 초음파 신호의 위상차, d는 해면질골의 두께, Cw는 온도에 의존하는 수중에서의 음속)

(F) is the phase difference of the received ultrasonic signal according to the presence or absence of the cavernous bone, d (f) is the phase difference of the received ultrasonic signal, d Is the thickness of the caudal bone, and Cw is the sound velocity in water depending on the temperature)

The sound velocity in the temperature-dependent water

의 식을 이용하여 계산되는 것을 특징으로 한다.(여기서, Cw는 온도에 의존하는 수중에서의 음속, T는 섭씨온도)

(Where Cw is the sound velocity in water depending on the temperature, T is the temperature in degrees Celsius)

An apparatus for measuring bone mineral density using an ultrasonic wave phase velocity dispersion ratio comprises: an output unit for outputting a result calculated by the calculation unit; And a control unit.

As described above, according to the present invention, the ultrasonic wave transmitted through the spongy bone by the ultrasonic wave transmitter and the ultrasonic wave receiver is converted into an electric signal, the ultrasonic wave phase velocity with respect to the frequency function is calculated through the converted electric signal, The bone mineral density of the cavernous bone is measured by the ultrasonic phase velocity dispersion obtained by applying the velocity value to the linear regression analysis.

Therefore, since the measurement of bone density is performed through the ultrasonic irradiation, the patient is not exposed to radiation. That is, the present invention has an effect of providing a safe measurement method to a patient.

In addition, the present invention provides an ultrasonic phase velocity dispersion ratio, which is a new parameter in addition to parameters used in existing quantitative ultrasonic techniques, thereby improving the accuracy of bone density measurement compared to the conventional method of measuring bone density using only sonic velocity and wide- It is effective.

1 shows a bone density measuring apparatus according to a preferred embodiment of the present invention.
2 and 3 show graphs of experimental results according to the present invention.
4 shows a flow diagram according to a preferred embodiment of the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for simplicity of explanation.

<Description of Configuration>

The apparatus 10 for measuring bone mineral density using the ultrasonic wave phase velocity dispersion ratio of the present invention includes an ultrasonic transmission unit 100, an ultrasonic wave reception unit 200, an ultrasonic wave conversion unit 300, a signal processing unit 400, an operation unit 500 and an output unit 600 ), Which will be described with reference to Fig.

The ultrasonic transmission unit 100 is located at one side of the cavernous bone B and irradiates the cavernous bone B with ultrasonic waves to introduce ultrasonic waves into the cavernous bone B.

The ultrasound receiving unit 200 is located on the other side of the cavernous bone B and receives ultrasound transmitted by the ultrasound transmitting unit 100.

The ultrasonic transducer 300 transmits an electric signal to the ultrasonic transmitter 100 so that the ultrasonic transmitter 100 irradiates ultrasonic waves with the cavernous bone B. When the ultrasonic wave receiving unit 200 receives the ultrasonic wave transmitted by the ultrasonic wave transmitting unit 100, the ultrasonic wave converting unit 300 converts the ultrasonic wave into an electric signal and transmits the electric signal to the signal processing unit 400.

The signal processing unit 400 detects an electrical signal transmitted from the ultrasonic transducer 300 and performs amplification and filtering of the detected electrical signal.

The operation unit 500 analyzes the electrical signal detected by the signal processing unit 400 and calculates the ultrasonic wave phase velocity with respect to the frequency function. The ultrasonic wave velocity is applied to the linear regression analysis to determine the rate of change of the ultrasonic wave phase velocity The bone mineral density of cavernous bone is measured by deriving the ultrasound phase velocity dispersion ratio. At this time, the operation unit 500 calculates the ultrasonic phase velocity for the frequency function using the following equation (1).

&Quot; (1) &quot;

(F) is the phase difference of the received ultrasound signal, d is the thickness of the cavernous bone, Cw is the temperature of the ultrasound wave, It is the speed of sound in the dependent water.

In addition, the calculating unit 500 calculates the sound velocity in water depending on the temperature using the following equation (2).

&Quot; (2) &quot;

Where Cw is the sound velocity in water dependent on the temperature and T is the temperature in degrees Celsius. At this time, the Celsius temperature is measured through a digital thermometer (not shown) installed in the water tank in which the cavernous bone B is located.

The output unit 600 outputs the result calculated by the operation unit 500 and may output the calculation result and the bone density through the output unit 600 according to an embodiment of the present invention.

The ultrasonic wave transmitting unit 100 and the ultrasonic wave receiving unit 200 used in the embodiment of the present invention have a diameter of 12.7 mm and a center frequency of 1 MHz and the distance between the ultrasonic wave transmitting unit 100 and the ultrasonic wave receiving unit 200 Was maintained at 53 mm.

1, the ultrasound transmitting unit 100 and the ultrasound receiving unit 200 are arranged to face each other. Between the ultrasound transmitting unit 100 and the ultrasound receiving unit 200, Lt; / RTI &gt;

At this time, the 25 cavernous bone samples used in this experiment were obtained from the bovine femur, and 25 cavernous bone (B) were used for the acoustic characteristics test of the cavernous bone because they have acoustical characteristics similar to those of the bone cauline of the human cavernous bone have.

<Description of Method>

The method of measuring bone mineral density using the dispersion rate of the ultrasonic wave phase velocity of the present invention will be described with reference to Figs. 1 to 4 and will be described for convenience.

1. Ultrasonic wave irradiation step < S401 >

In this step, when the ultrasonic transducer 300 transmits an electric signal for transmitting ultrasonic waves to the ultrasonic transmitter 100, the ultrasonic transmitter 100 irradiates ultrasonic waves to the cavernous bone B.

2. Conversion step < S402 >

The ultrasound receiving unit 200 receives ultrasound waves irradiated by the ultrasound transmitting unit 100 in step S401. The ultrasonic wave received by the ultrasonic wave receiving unit 200 is converted into an electric signal by the ultrasonic wave converting unit 300. Then, the ultrasound transducer 300 transmits the converted electrical signal to the signal processor 400. At this time, the signal processor 400 amplifies the received electrical signal and removes the noise through a filtering process. Next, the signal processing unit 400 transmits the filtered electrical signal to the operation unit 500.

3. Bone mineral density measurement step <S403>

In this step, the operation unit 500 receives the electrical signal transmitted by the signal processing unit 400 in step S402, and the operation unit 500 derives the ultrasound phase velocity dispersion ratio through analysis of the received electrical signal. In addition, the operation unit 500 measures the bone mineral density of the cavernosal bone B through the derived ultrasound phase velocity dispersion ratio.

3-1. Ultrasonic phase velocity calculation step for frequency function

First, the operation unit 500 analyzes an electric signal received from the signal processing unit 400 and calculates an ultrasonic phase velocity with respect to a frequency function using Equation (1). In addition, the operation unit 500 calculates the sound velocity in water depending on the temperature using the above-described expression (2).

3-2. Step of deriving ultrasound phase velocity dispersion ratio

The operation unit 500 applies the calculated ultrasonic phase velocity data to the linear regression analysis to derive an ultrasonic phase velocity dispersion ratio which is a rate of change of the ultrasonic wave phase velocity according to the ultrasonic frequency. At this time, the operation unit 500 determines the bone density of the actual cavernous bone by substituting the ultrasound phase velocity dispersion ratio of the plurality of cavernous bone samples and the derived ultrasound phase velocity dispersion ratio in the negative correlation equation formed between the bone mineral density.

4. Output step < S404 >

The output unit 600 outputs the result calculated by the operation unit 500 on the screen in step S403. At this time, the types of data output on the screen may include an ultrasonic phase velocity, an ultrasonic phase velocity dispersion ratio, a bone density and an osteoporosis determination result with respect to a frequency function.

Fig. 2 shows ultrasonic phase velocities with respect to a frequency function in a frequency range from 0.8 MHz to 1.2 MHz by irradiating ultrasound waves to a representative spongy bone sample out of 25.

FIG. 3 is a graph showing the relationship between the ultrasonic wave phase velocity and the bone density obtained by applying the ultrasonic wave phase velocity to the linear regression method with respect to the frequency function shown in FIG. 2 for each of 25 spongy bone B Respectively. 3, the bone density of each caudal bone (B) was obtained by a general density measurement method.

As shown in Fig. 3, as the bone mineral density of the caustic bone B increases, the ultrasonic phase velocity dispersion decreases linearly. That is, it can be seen from FIG. 3 that there is a linear negative correlation between the bone mineral density and the ultrasonic phase velocity dispersion ratio.

The correlation between the ultrasonic phase velocity dispersion ratio and the bone mineral density of the cavernous bone (B) was confirmed through the present invention. This correlation implies that bone mineral density of the sponge bone can be predicted by the ultrasonic phase velocity dispersion ratio obtained when the spongy bone of an actual person is measured by a BMD measuring device.

Therefore, the present invention can measure the bone mineral density of the spongy bone in the measurement of the bone mineral density of the cavernous bone using the new parameters such as the sonic velocity and the broadband ultrasound attenuation factor, which are parameters used in the existing quantitative ultrasonic technique, and the ultrasonic phase velocity dispersion ratio. That is, the present invention has an effect that the measurement accuracy and reliability are improved more than the conventional method of measuring bone density by increasing the parameters that can be used for bone density measurement.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. And the scope of the present invention should be understood as the following claims and their equivalents.

10: BMD measurement device using ultrasound phase velocity dispersion
100: Ultrasonic transmitter
200: Ultrasonic receiver
300: Ultrasonic wave conversion unit
400: Signal processor
500:
600: Output section
B: spongiform bone

Claims (13)

An ultrasound irradiation step of irradiating the caudal bone with ultrasound of 0.8 to 1.2 MHz;
A converting step of receiving ultrasonic waves passing through the cavernous bone and converting the ultrasonic waves into electric signals; And
A bone mineral density measurement step of deriving an ultrasound phase velocity dispersion ratio through the electrical signal converted in the conversion step and predicting a bone mineral density of the spongy bone from the derived ultrasound phase velocity dispersion ratio; , &Lt; / RTI &
The bone mineral density measuring step
In order to derive the ultrasonic phase velocity dispersion ratio through the electrical signal,
An ultrasonic wave phase velocity calculation step of analyzing the electric signal to calculate an ultrasonic wave phase velocity with respect to a frequency function; And
A step of deriving an ultrasonic wave phase velocity dispersion ratio which is a rate of change of the ultrasonic wave phase velocity according to an ultrasonic frequency by applying the ultrasonic wave phase velocity calculated in the ultrasonic wave phase velocity calculation step to linear regression analysis; Lt; / RTI &gt;
The bone mineral density measuring step predicts the bone mineral density of the spongy bone using the correlation that the bone mineral density of the spongy bone becomes smaller as the ultrasonic phase velocity dispersion ratio increases,
In the step of calculating the ultrasonic wave phase velocity, the ultrasonic wave phase velocity for the frequency function is

Lt; / RTI &gt;
The correlation between the bone mineral density of the cavernous bone and the bone mineral density of the cavernous bone sample and the correlation of the ultrasonic phase velocity dispersion calculated by irradiating the cavernous bone sample with a linear negative correlation , And in the step of deriving the ultrasound phase velocity dispersion, the bone mineral density of the spongy bone is predicted by substituting the ultrasound phase velocity dispersion ratio of the caustic bone with the negative correlation equation
A Method of Measuring Bone Mineral Density Using Ultrasonic Phase Velocity Dispersion.
(F) is the phase difference of the received ultrasound signal depending on the presence or absence of the cavernous bone, d is the thickness of the cavernosal bone, Cw is the temperature Lt; / RTI &gt; speed) delete delete delete delete The method according to claim 1,
The sound velocity in the temperature-dependent water

Is calculated using the following equation:
A Method of Measuring Bone Mineral Density Using Ultrasonic Phase Velocity Dispersion.
(Where Cw is the sonic velocity in water depending on the temperature, T is the temperature in degrees Celsius) The method according to claim 1,
An output step of outputting a result calculated in the bone density measurement step; &Lt; RTI ID = 0.0 &gt;
A Method of Measuring Bone Mineral Density Using Ultrasonic Phase Velocity Dispersion. An ultrasonic transmitter for irradiating ultrasonic waves of 0.8 to 1.2 MHz with the spongy bone to predict bone density of spongy bone;
An ultrasonic wave receiving unit for receiving the ultrasonic wave irradiated from the ultrasonic wave transmitting unit;
An ultrasonic transducer for transmitting an electric signal to the ultrasonic wave transmitter for ultrasonic wave irradiation or converting the ultrasonic wave received by the ultrasonic wave receiver into an electric signal;
A signal processing unit for detecting the electrical signal converted by the ultrasonic conversion unit; And
Wherein the ultrasonic wave phase velocity is calculated by analyzing the electrical signal detected by the signal processing unit to calculate an ultrasonic wave phase velocity with respect to a frequency function and applying the ultrasonic wave phase velocity to a linear regression analysis, An arithmetic and logic unit , &Lt; / RTI &
Wherein the calculation unit estimates the bone mineral density of the cavernous bone using the correlation that the bone mineral density of the cavernous bone is decreased as the ultrasound phase velocity dispersion ratio increases,
Wherein the calculation unit calculates an ultrasonic phase velocity for the frequency function by the following equation

Lt; / RTI &gt;
The correlation between the bone mineral density of the cavernous bone and the bone mineral density of the cavernous bone sample and the correlation of the ultrasonic phase velocity dispersion calculated by irradiating the cavernous bone sample with a linear negative correlation And the calculation unit predicts the bone mineral density of the spongy bone by substituting the ultrasonic phase velocity dispersion ratio of the caustic bone with the negative correlation equation.
An apparatus for measuring bone mineral density using ultrasound phase velocity dispersion.
(F) is the phase difference of the received ultrasound signal depending on the presence or absence of the cavernous bone, d is the thickness of the cavernosal bone, Cw is the temperature Lt; / RTI &gt; speed) delete delete delete 9. The method of claim 8,
The sound velocity in the temperature-dependent water

Is calculated using the following equation:
An apparatus for measuring bone mineral density using ultrasound phase velocity dispersion.
(Where Cw is the sonic velocity in water depending on the temperature, T is the temperature in degrees Celsius) 9. The method of claim 8,
An output unit for outputting a result calculated by the operation unit; &Lt; RTI ID = 0.0 &gt;
An apparatus for measuring bone mineral density using ultrasound phase velocity dispersion.

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