KR101008270B1 - A device for measuring thickness of subcutaneous fat capable of compensation with thickness of dermal depth - Google Patents

Abstract

The present invention is to measure the thickness of the subcutaneous fat by using the absorption (absorption), scattering, diffuse reflectance of the light, but to calculate the thickness of the subcutaneous fat and the thickness of the skin to calculate a more accurate subcutaneous fat thickness The apparatus for measuring subcutaneous fat thickness, which may be irradiated with near-infrared rays on the surface of an object, and may measure near-infrared rays to adjust the angle of incidence of the near-infrared ray on the surface, and for measuring the near-infrared rays incident on the object and coming back. Means and a controller for analyzing a near infrared signal received from the measuring means, wherein the controller calculates a skin thickness value and a subcutaneous fat thickness value of the object using the near infrared signal, and uses the skin thickness value to control the subcutaneous skin. It is characterized by calculating the correction value for the fat thickness value.

Subcutaneous fat thickness, skin thickness, correction, near infrared

Description

A device for measuring thickness of subcutaneous fat capable of compensation with thickness of dermal depth}

The present invention relates to an apparatus for measuring the thickness of subcutaneous fat using absorption, scattering, and diffuse reflectance of light, and more particularly, by measuring the thickness of subcutaneous fat and the thickness of skin. The present invention relates to a subcutaneous fat thickness measuring apparatus capable of calculating more accurate subcutaneous fat thickness.

When the fats in the body of mammals, including the human body, are classified according to where they are accumulated, they can be divided into visceral fats located between organs and subcutaneous fats that accumulate under the skin. Among these, visceral fat is fat distributed in various visceral parts of the body, and is fat causing health problems such as diabetes, hypertension, hyperlipidemia and various adult diseases. Subcutaneous fat, on the other hand, is the fat layer just below the skin, and is responsible for nourishing the epidermis and dermis, determining the body shape, maintaining body temperature, absorbing external shock, and protecting subcutaneous subcutaneous cells.

This subcutaneous fat does not cause a big problem metabolically, but it has become a subject of great interest in beauty with a social atmosphere that puts importance on the appearance of modern society. It is also a part that I want to pull out.

In general, the accumulation of subcutaneous fat is more evenly deposited in women than men, and both men and women become subcutaneous fat in middle age. In northern countries where the climate is cold, local sedimentation tends to be high, and excessive nutrition leads to an increase in fat accumulation. In the human body, the back of the hand, eyelids, penis, scrotum, the anus is distributed relatively little, and the belly, the palate, etc. are much distributed in the limbs.

Conventionally, a method of measuring fat including body fat of a human body is known in various ways as follows. First, there is a caliper (Calpers, Skinfold measurement) method to measure the thickness of the subcutaneous fat by using a caliper, and to measure the specific gravity after entering a water tank (Hydro-densitometry, Underwater) There is a weighing method, a bioelectrical resistance that measures the amount of fat in the body using the principle that a weak current flows through the body and the current flows well if there is water, and the electrical resistance value increases in the absence of water (for example, body fat). Bioelectrical Impedance (BIA)

In addition, the Near-infrared Interactance (NIR) method, which measures near-infrared rays on the skin, and trace X-rays, is used to measure the amount of bone in the human body.In this case, DEXA (Dual Energy X-ray Absorptiometry (DEXA) and Magnetic Resonance Imaging (MRI), which uses medical equipment to show the distribution of hydrogen nuclei in the body using high frequency harmless to the human body.

In addition to the methods listed above, there are various methods such as CT (computerized tomography) and ultrasonic measurement. Among these, conventionally, as a method for measuring the fat of the human body, in particular, the body fat distributed throughout the body, a fat measuring method using a bioelectrical resistance analysis (BIA) method is common enough to control 90% or more of the whole body. However, although the impedance by BIA method can measure the amount of fat distribution throughout the body, there are technical limitations to measure the thickness of subcutaneous fat of the desired area.

Among the above methods, the caliper method, the DEXA method, the magnetic resonance imaging method, the CT method, the ultrasonic measurement method, the near infrared method, and the like, which can be used as a method for directly measuring the thickness of the subcutaneous fat of the localized area so far. However, the DEXA method, magnetic resonance imaging method, CT method, and ultrasonic measurement method is cumbersome and expensive because it requires expensive equipment to be measured by an expert at a designated place. In addition, the method of using radiation is accurate, but it is expensive and carries the risk of irradiation. Ultrasonic measuring devices have little burden on patients and doctors when measuring, and recently, ultrasound with excellent resolution has been continuously developed, but this also has disadvantages in that the price of the equipment is expensive and the results may differ depending on the skill of the measurer. . And the caliper method is inaccurate, and there is a limit to its use because there is an inappropriate part to use it.

On the other hand, the fat analyzer using a conventional near-infrared measuring method is a device for measuring the percentage of body fat spread throughout the body by measuring the absorption and reflection of the light mainly by penetrating the near-infrared wavelength of 938 nm to 948 nm into the body. The measurement method measures the middle part of the biceps muscle, which was based on the results of a study (Conway and Norris, 1986, Elia et. Al., 1990; Gullstrand) which had the highest agreement with the standardized method.

However, since the accumulation of fat varies depending on the characteristics of each individual, such as a man who accumulates a lot of fat in the abdomen and a woman who accumulates in the thighs, it is very error to measure the body fat of the whole body by measuring one place. There is a limit that there is no choice but to. In addition, as a detector for detecting near-infrared rays in the wavelength band, silicon (Si, silicon) semiconductor devices are mainly used, which exhibits insensitive reaction to wavelengths used for measurement due to the characteristics of the semiconductor material. For this reason, the conventional body fat measuring device using the near-infrared rays is very poor in accuracy, and in the case of partial body correction for the present cosmetic reasons, it is not measuring the distribution of partial subcutaneous fat, but measuring the total fat content. It may not be more suitable.

An object of the present invention is to provide a device for non-invasive measurement of subcutaneous fat using a near infrared light source.

Another object of the present invention to provide a device that can measure the exact subcutaneous fat thickness of the human body using the near infrared.

The object of the present invention is to irradiate near-infrared to the surface of the object, but near-infrared irradiation means for adjusting the angle of incidence of the near-infrared surface, measuring means for detecting the near-infrared incident on the object and coming back to the measuring means and the measuring means A control unit for analyzing a near infrared signal received from the control unit, wherein the control unit calculates a skin thickness value and a subcutaneous fat thickness value of an object using the near infrared signal, and uses the skin thickness value for the subcutaneous fat thickness value. A subcutaneous fat thickness measuring apparatus characterized by calculating a correction value.

In this case, the control unit calculates the subcutaneous fat thickness value when the incident angle is 80 degrees to 90 degrees, and calculates the skin thickness value when the angle is 10 degrees to 80 degrees, and the wavelength range of the near infrared rays is preferably 750 nm to 1700 nm.

The apparatus for measuring subcutaneous fat thickness according to the present invention may be configured to send information about the incident angle to the controller, or may be configured to directly control the incident angle of the near infrared irradiation means in the control unit.

In the subcutaneous fat thickness measuring apparatus according to the present invention, the measuring means may be configured as a linear image sensor so that the measurement may be simply performed.

The subcutaneous fat thickness measuring apparatus according to the present invention uses a non-invasive method without burden on the human body, and by using a near-infrared light source, there is an advantage that accurate measurement data can be obtained regardless of the state or color of the skin.

In particular, the subcutaneous fat thickness measuring apparatus according to the present invention can measure the subcutaneous fat thickness of the human body can also measure the skin thickness, there is an advantage that can calculate the more accurate subcutaneous fat thickness through the skin thickness.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The foregoing terms or words used in this specification and claims are not to be construed as being limited to the common or dictionary meanings, and the inventors properly define the concept of terms in order to explain their invention in the best way. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that it can.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a conceptual diagram of a subcutaneous fat thickness measuring apparatus according to an embodiment of the present invention.

Subcutaneous fat thickness measuring apparatus according to the present invention is for measuring the subcutaneous fat of the human body, and includes a near infrared ray irradiation means 101 for injecting near infrared rays. The near-infrared irradiating means 101 is composed of light sources (FIGS. 2 and 202) and angle adjusting portions (FIGS. 2 and 201) for emitting near infrared rays. The angle of incidence to 103 can be adjusted. It is preferable to adjust so that the near-infrared ray incident on the skin surface 103 by the angle adjusting unit 201 can be incident vertically or at a non-vertical angle in an area having a diameter of several to several tens of micrometers on the skin surface 103. .

In addition, the near-infrared ray used in the present invention has a wavelength of 750 nm to 1700 nm, and thus is least affected by melanin present in the skin, thereby minimizing errors caused by skin conditions (skin color, etc.) and easily measuring. do. In particular, when using the extreme infrared rays of 750 to 1350 nm or 1500 to 1700 nm, accurate data measurement is possible by minimizing the absorption of wavelengths by moisture. In order to emit light in such a wavelength band, the light source 202 of the near-infrared irradiation means 101 may be configured using a filter on its front surface. On the other hand, the distance between the skin surface and the near infrared ray is preferably configured to be spaced apart from 0.7 to 3 cm to minimize the damage to the skin.

Near-infrared rays emitted from the light source 202 and incident on the skin can pass through each skin tissue (epidermis, dermis, subcutaneous fat), flow along layers with similar physical properties, or be emitted back out through each tissue. have. That is, the near infrared ray may continuously pass through each tissue of the skin, but the incident near infrared ray may pass through only a portion of the upper layer, flow along the middle layer, and then pass through the upper layer and be emitted to the outside. In this way, the intensity of near-infrared rays passing through the middle layer of the skin is increased in a certain distance from the point where near-infrared rays are incident, and the predetermined distance varies depending on the thickness of the middle layer. In addition, when near-infrared light is incident vertically (about 80 to 90 degrees) (see FIG. 2), it is possible to minimize single backscattering that can be observed in bio-optics, thereby increasing the accuracy of subcutaneous thickness measurement, and not in the vertical range. When the light is incident at 80 degrees or less (see FIG. 3), the intensity of light diffused from the epidermis and the dermis of the skin increases and the thickness of the epidermis and the dermis can be accurately calculated.

The measuring means 102 applied in the present invention is a sensor for measuring the diffusion of light from the light source 202 into the near-infrared rays incident to the skin and radiating back to the outside. Photograph the pattern by intensity. The measuring means 102 may be configured as a two-dimensional image sensor, but is preferably applied as a simple linear image sensor. When using the linear image sensor, the light source 202 is preferably located at one side of the linear image sensor. In addition, it is preferable that an image sensor uses an appropriate compound semiconductor device in order to increase sensitivity to the infrared band.

When using the two-dimensional image sensor, the control unit 104 receives a signal from the measuring means 102 should find the distance between the concentric pattern corresponding to the subcutaneous fat layer or skin thickness of the round concentric pattern photographed through the measuring means 102. When the linear image sensor is used, only the measurement signal 105 corresponding to the skin thickness and the subcutaneous fat layer thickness can be selected among the peak values of the signal corresponding to the distance, so that the operation of the controller 104 is simple and quick. Subsequently, the skin and subcutaneous fat layer thicknesses may be obtained by using a pre-stored signal intensity, measurement distance versus subcutaneous fat layer or skin thickness table.

After calculating the skin thickness value and the subcutaneous fat thickness value of the object, the controller calculates a correction value for the subcutaneous fat thickness value with reference to the skin thickness value. Therefore, according to the present invention, it is possible to accurately measure the subcutaneous fat thickness.

The control unit receives the information on the angle of incidence and calculates the subcutaneous fat thickness value at 80 degrees to 90 degrees, and calculates the skin thickness value at 5 degrees to 80 degrees. Information may be configured to be sent from the angle adjuster to the controller, or may be configured to directly control the angle adjuster.

The present invention has been shown and described with reference to the preferred embodiments as described above, but is not limited to the above embodiments, those skilled in the art without departing from the spirit of the present invention. Various changes and modifications will be possible.

1 is a conceptual diagram showing a measuring principle of the subcutaneous fat thickness measuring apparatus according to the present invention,

2 is a conceptual diagram showing a method for measuring subcutaneous fat thickness value of the subcutaneous fat thickness measuring apparatus according to the present invention,

3 is a conceptual diagram showing a skin thickness value measuring method of the subcutaneous fat thickness measuring apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

101: infrared irradiation means 102: measuring means

103: skin surface 104: control unit

105: measurement signal 201: angle adjuster

202: light source

Claims (6)

Near-infrared irradiation means for irradiating near-infrared to the surface of the object to adjust the angle of incidence of the near-infrared to the surface; Measuring means for detecting the near-infrared rays incident on the object and coming back; And A control unit for analyzing a near infrared signal received from the measuring means, The controller calculates the subcutaneous fat thickness value of the object when the incident angle is 80 degrees to 90 degrees, calculates the skin thickness value of the object when the incident angle is 10 degrees to 80 degrees, and uses the skin thickness value to Subcutaneous thickness measuring apparatus for calculating a correction value for the subcutaneous thickness value. delete The method of claim 1, Subcutaneous fat thickness measuring device configured to send information about the incident angle to the control unit. The method of claim 1, Subcutaneous fat thickness measuring apparatus which controls the said incident angle of the said near-infrared irradiation means by the said control part. The method of claim 1, The wavelength of the near infrared ray is a subcutaneous fat thickness measuring apparatus of 750nm to 1700nm. The method of claim 1, And said measuring means is a linear image sensor.

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