KR101444730B1 - Transmitted light detection type measurement apparatus for skin autofluorescence - Google Patents

Abstract

The present invention relates to a method and apparatus for measuring autofluorescence of skin such as diabetes mellitus by measuring the autofluorescence of skin from the Advanced Glycation End products (AGE) To a fluorescence measuring apparatus.
For this purpose, in the present invention, in measurement of skin fluorescence, a transmitted light detection type skin fluorescence measurement capable of simply correcting a measurement error of skin fluorescence due to scattering and absorption of light transmitted through the skin surface of the irradiation light, Device.
In the present invention, the reference sample or the object to be measured can be irradiated with light and can detect light, and includes a first light source for emitting excitation light, a second light source for emitting light of a wavelength different from that of the first light source, A first photodetector and a second photodetector arranged to detect transmitted light from the first light source and the second light source and detecting two different wavelengths of the fluorescence signal and the transmitted light signal; And a calculation section for calculating a skin fluorescence signal corrected from the fluorescence signal and the transmitted light signal detected from the first photodetector and the second photodetector, wherein the second light source And irradiates light of a wavelength band of skin fluorescence excited and excited by the excitation light from the first light source.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a skin fluorescence measuring apparatus,

The present invention relates to a method and apparatus for measuring autofluorescence of skin such as diabetes mellitus by measuring the autofluorescence of skin from the Advanced Glycation End products (AGE) To a fluorescence measuring apparatus.

Advanced Glycation End products (AGEs) are formed in the oxidation of body organ proteins as a result of the Maillard reaction. These reactions impair many protein functions. Oxidative stress is rapidly increased by acute illnesses such as smoking, high fat acid, or cardiac risk factors such as hypercholesterolemia, as well as sepsis. As a result, an end glycation product (AGE) occurs. This final glycation end product (AGE) is slowly degraded and accumulated over the entire time. The increase in the final glycation end product (AGE) is associated with the progression of chronic diseases such as atherosclerosis and tends to accumulate in the body as the age increases over a person's lifetime.

In the case of persistent hyperglycemia, non-enzymatic protein glycation and glycoxidation reactions occur continuously, leading to the formation of Advanced Glycation End products (AGE), a complex of irreversible sugars and proteins. Accumulation of the final glycation end product (AGE) progresses significantly in people suffering from vascular disease such as diabetes, renal failure, cardiovascular disease. The final glycation products (AGE) products accumulate in various tissues, including the skin. The final glycation product (AGE) has the property of emitting autofluorescence (AF) in the blue spectral region (maximum near 440 nm) by excitation light irradiation in the ultraviolet region (maximum near 370 nm).

It is known that the final glycation end product (AGE) can act as a biomarker for a range of diseases and can be used to measure the autofluorescence of the skin by non-invasive methods, The damage can be assessed. Therefore, the final glycation end product (AGE) predicts long-term complications in age-related diseases. Specifically, the amount of autologous skin fluorescence increases in patients with diabetes and renal failure, and is associated with the progression of vascular complications and coronary heart disease (CHD). This accumulation of the final glycation end product (AGE) can be measured noninvasively by skin autologous fluorescence and can be used as a noninvasive clinical tool to assess the risk of long-term vascular complications in the environment associated with diabetes and the accumulation of final glycation end products (AGEs) useful.

As a method and an apparatus proposed for evaluating the final glycation end product (AGE) by skin autofluorescence (AF) measurement, U.S. Patent Application Publication No. 2004-186363 (hereinafter referred to as Document 1) (AGE) is measured by measuring the final glycation end product (AGE).

In Document 1, the excitation light source is a black glass fluorescent lamp that emits light in the ultraviolet region in the wavelength range of 300-420 nm. Collecting and recording light is performed by an optical fiber spectrometer. To increase the measurement area, the end face of the optical fiber is placed at a distance (d: 5-9 mm) from the transparent window of the equipment. To reduce the influence of reflected light from the skin, Direction.

Specifically, in Document 1, the end surface of an optical fiber collecting light is arranged at a distance from the target portion so as to increase the light collecting area, and the target portion area measured in this case is about 0.4 cm 2.

However, in this case, there is a problem that the fluorescence signal collected is greatly reduced by increasing the measurement distance d to increase the area of the measurement target site. Therefore, in the case of the conventional document 1, there is a problem that the reliability of data detection is deteriorated due to the limit of the size of the measurable skin area. In particular, this accuracy problem is largely seen in areas of heterogeneous skin, such as skin spots, blood vessels, wounds, and the like.

On the other hand, U.S. Published Patent Application No. 2008-103373 (hereinafter referred to as Document 2) discloses a similar device for measuring the final glycation end product (AGE) for screening diabetic patients. The equipment of Document 2 is configured to perform fluorescence measurement on the haemocytic skin with an optical fiber spectroscope as in Document 1. However, unlike in Document 1, in Document 2, the optical fiber probes are formed in the form of bundles composed of several branch lines.

In the apparatus of Document 2, ultraviolet light and blue light emitted from the light emitting diodes are irradiated to the bottom of the subject through the optical fiber probe, and skin fluorescence and diffuse reflected light from the subject are collected through the probe. The collected light is wavelength dispersed in the spectroscope and detected by a linear array detector. Two of the branch lines of the fiber optic probe (illumination fibers, channel 1 and channel 2) illuminate the target site, and the third collection fibers transmit the light from the object to the multichannel spectroscope. The end surface of the tissue interface where the bundle of optical fiber probe wires is bonded is brought into contact with the skin part to be irradiated.

One of the fiber optic probe wires selects light from the white light LED for the reflected light spectrum measurement and another LED selects the appropriate LED among the LEDs that emits light within the blue light spectrum range from ultraviolet to the switching device to emit light do. Various wavelengths can be selected to select the optimal fluorescence excitation condition. The reflected light spectrum measurement is used to detect the self fluorescence caused by the influence of melanin and hemoglobin and correct the measurement result. Each optical fiber bundle in the optical fiber bundle is arranged in a predetermined order, and the optical fibers coming out from each of the three branch lines in the bundle of optical fiber bundles are arranged in the order of b = 0.5 mm in the form of a mosaic.

However, in Document 2, since the light is irradiated to the bottom of the subject through the optical fiber probe, the optical fiber probe includes the optical fiber probe as the light transmission medium, which causes inherent problems of the optical fiber probe. That is, the optical fiber has a problem in that transmission loss is generated for each specific wavelength depending on the characteristics of its own medium, and further optical design and optical system are required to make the light generated from the light source incident on the optical fiber total reflection condition.

In addition, since the devices of the above documents 1 and 2 commonly use an optical fiber in a light receiving part for receiving light, inherent problems of the optical fiber probe itself in the light receiving part coexist, and in these documents, an optical fiber spectrometer and a linear array detector It is disadvantageous in that the detection area occupied by the linear array detector of the autofluorescence signal wavelength of the final glycation product becomes relatively small. Therefore, the detected fluorescence signal is dispersed and the light intensity of the wavelength to be detected by the linear array detector becomes relatively small. Also, since the optical fiber probe and the optical fiber spectroscope are included, there is a problem that the facility can not be downsized.

On the other hand, in measuring skin fluorescence to diagnose diseases such as diabetes, in addition to a reflected light detection method for detecting reflected light and skin fluorescence in a region where light irradiated to the skin is reflected, the transmitted light and the transmitted light It is possible to consider a transmitted light detection method for detecting skin fluorescence at the measured position.

In this transmission light detection method, in order to measure intrinsic fluorescence intensity generated from the skin, the target skin to be measured is transmitted through the irradiation light, and light should be detected from the opposite skin of the target skin.

In general, the target skin area that can be considered as the transmitted light detection method is as follows. First, in the case of the earlobes, the thickness of the earlobe is about 3 mm, and the loss of the transmitted light is large, and the influence of the light absorbing blood is very large. In the case of fingers, when measured between the fingernail and the skin opposite to the fingernail, it is greatly influenced by the fluorescence generated in the fingernail. On the other hand, when measuring the fluorescence between the direction perpendicular to the nail and the skin on the opposite side of the nail, the light path becomes longer and the loss rate becomes larger. On the other hand, the measurement of the skin between the fingers, especially the skin between the thumb and the index finger, has the following advantages. First, the loss of light is not as large as 1 mm in thickness, and second, the influence of blood is small. Third, the effect of skin pigment is small and it is convenient to measure at the end.

On the other hand, the fluorescence intensity generated from the skin is influenced not only by the fluorescent substance contained in the skin, but also by the scattering and light absorption properties of light generated in the skin, even in the case of performing selective diagnosis on such a body part.

Therefore, since errors are caused by the measurement due to the scattering and the light absorption properties of light, it is necessary to correct such errors in order to accurately detect skin fluorescence due to fluorescence excitation. In particular, when diagnosing a disease such as diabetes from a skin fluorescence measurement, since the difference in the numerical value between the person having the disease and the person having the disease among the subject is not large enough to offset the error, A device capable of detecting the skin fluorescence signal more accurately is required even when the measurement is performed.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method for measuring fluorescence of ultrasound (AGE) from skin, The present invention provides a transmitted-light detection type skin fluorescence measurement apparatus capable of detecting a skin fluorescence signal having enhanced accuracy by detecting skin fluorescence detected together with the transmitted light in fluorescence and calculating a corrected skin fluorescence signal therefrom.

In addition, the present invention provides a transmitted light detection type skin fluorescence measurement device capable of accurately diagnosing a diagnostic factor such as a final glycation end product (AGE) from a corrected skin fluorescence calculation value, thereby improving diagnoses for diseases such as diabetes mellitus.

In addition, the present invention provides a transmitted light detection type skin fluorescence measurement device in which an optical system and a light source system can be simply configured so that the diagnostic process can be easily performed.

In order to accomplish the above object, the present invention provides a method of measuring a position of an object to be measured, the method comprising: a first light source configured to irradiate a standard specimen or a measurement object with light and detect light, A second light source for emitting light having a wavelength different from that of the first light source; A first photodetector and a second photodetector arranged to detect transmitted light from the first light source and the second light source and detecting two different wavelengths of the fluorescence signal and the transmitted light signal; A light source switching controller for controlling on / off of the first light source and the second light source; And an arithmetic unit for calculating the skin fluorescence signal corrected from the fluorescence signal and the transmitted light signal detected from the first photodetector and the second photodetector, and the second light source is excited by the excitation light from the first light source And irradiates light of a wavelength band of emitted skin fluorescence.

The light source switching control unit controls switching of the first light source and the second light source so that the lighting state of the first light source and the second light source are temporally separated. do.

In addition, the switching control unit may continuously and repeatedly turn on and off the first light source and the second light source to detect the fluorescence signal and the transmitted light signal for the first light source and the transmitted light signal for the second light source, respectively And a transmitted-light detection type skin fluorescence measurement device.

In addition, a measurement object and a standard specimen may be selectively positioned on an optical path of the first light source and the second light source.

Also, the first light source irradiates light having a wavelength of 370 nm ± 20 nm.

The second light source irradiates light having a wavelength of 440 nm ± 20 nm.

The switching control unit controls the first light source and the second light source to be turned off before the respective light sources are turned on.

When the switching controller turns off both the first light source and the second light source, the first photodetector and the second photodetector measure a dark signal, the operation unit stores the measured dark signal, And the fluorescence signal and the transmitted light signal detected from the fluorescence measurement device are compensated.

The switching control unit controls the first light source unit and the second light source unit to repeatedly turn on and off at a cycle of 10 to 100 Hz.

The apparatus further includes a photodetector switching control unit for controlling on / off of the first photodetector and the second photodetector.

An optical sensor including the first light source, the second light source, the first photodetector, and the second photodetector; And a main body including the calculation unit, which is configured to be electrically connectable to the optical sensor.

The optical sensor may further include a first fixing unit connected to the first light source and the second light source, a second fixing unit connected to the first optical detector and the second optical detector, and the first fixing unit and the second fixing unit And an insertion space is formed between them while facing each other.

Also, the optical sensor may include a memory for storing the detected information.

Further, the optical sensor includes a common light source optical guide for commonly transmitting light emitted from the first light source and the second light source.

Also, the optical sensor may include a common detection light guide for commonly transmitting transmitted light and skin fluorescence to the first photodetector and the second photodetector.

The optical sensor may further include a first dichroic mirror disposed on the optical path so as to transmit the respective lights emitted from the first light source and the second light source to the common light source optical guide. Type skin fluorescence measurement device.

The optical sensor may further include a second dichroic mirror disposed on an optical path for separating light transmitted from the common detection light guide and transmitting the separated light to the first optical detector and the second optical detector. A transmitted light detection type skin fluorescence measurement device is provided.

A light source filter is provided between the first light source and the first dichroic mirror so as to pass light of the first wavelength emitted from the first light source and suppress light of the second wavelength emitted from the second light source And a transmitted-light detection type skin fluorescence measurement device.

And an objective lens for focusing the light emitted from the first light source and the second light source is provided between the first light source and the second light source and the first dichroic mirror, A skin fluorescence measurement device is provided.

Further, a first detection filter is provided between the second dichroic mirror and the first photodetector for passing light of a first wavelength and suppressing light of a second wavelength, and the first dichroic mirror and the second dichroic mirror And a second detection filter for suppressing light of a first wavelength and transmitting light of a second wavelength is provided between the second photodetector.

The first dichroic mirror is disposed between the first photodetector and the second dichroic mirror, and the second dichroic mirror is disposed between the first photodetector and the second dichroic mirror. And a lens is provided on the surface of the skin fluorescence measuring device.

The optical sensor may further include a first light source optical guide for transmitting light emitted from the first light source and a second light source optical guide for transmitting light emitted from the second light source. A fluorescence measurement device is provided.

The optical sensor may include a first detection light guide for transmitting the transmitted light and the skin fluorescence to the first photodetector and a second detection light guide for transmitting the transmitted light and the skin fluorescence to the first photodetector and the second photodetector. A measuring device is provided.

A light source filter is provided between the first light source and the first light source light guide for transmitting light of the first wavelength emitted from the first light source and suppressing light of the second wavelength emitted from the second light source And a transmitted-light detection type skin fluorescence measurement device.

A first detection filter for passing light of a first wavelength and suppressing light of a second wavelength is provided between the first light source optical guide and the first optical detector, And a second detection filter for suppressing light of the first wavelength and transmitting light of the second wavelength is provided between the two photodetectors.

It is preferable that a first light source and a second light source are provided at the distal end of the first fixing part so that the first light source and the second light source can directly irradiate light to the object to be measured, Wherein the first photodetector and the second photodetector are provided to detect transmitted light and skin fluorescence directly from the first photodetector and the second photodetector. do.

The first photodetector and the second photodetector are characterized in that band filters for distinguishing the first wavelength lambda 1 and the second wavelength lambda 2 before the two sectors of the photodetector composed of two sectors are respectively located And a transmitted-light detection type skin fluorescence measurement device.

The first fixing part and the second fixing part are fabricated in a clip shape so that the first fixing part and the second fixing part can be fixed while pressing the measurement object.

In addition, the optical sensor is equipped with a movable standard specimen, and when the measurement object is removed from the insertion space between the first fixing unit and the second fixing unit, the standard specimen is moved to be positioned in the insertion space And a transmitted-light detection type skin fluorescence measurement device.

The optical sensor performs measurement on the skin when the skin to be measured is located in the insertion space, and performs measurement on the standard specimen when the measurement object is removed and the standard specimen is located in the insertion space. Type skin fluorescence measurement device.

The optical sensor is configured to store measured results of skin and standard specimens to be measured, and to transmit detection information on the stored skin and standard specimen to the main body to calculate corrected skin fluorescence values in the arithmetic unit. And a transmitted-light detection type skin fluorescence measurement device.

The main body further includes a display unit, and the display unit outputs the corrected skin fluorescence signal calculated by the calculation unit.

In addition, the operation unit calculates the skin fluorescence value corrected by the following formula: < EMI ID = 1.0 >

_{Formula: AF corr = K [I (} λ2, t1) / I 0 (λ2, t1)] / {[T (λ1)] ^k1 [T (? 2)]} ^k2

(Where, T (λ1) = I ( λ1, t1) / I 0 (λ1, t1): diffuse transmission coefficient at the excitation wavelength

T (λ2) = I (λ2 , t2) / I 0 (λ2, t2): spread transmission coefficient at the radiation wavelength

I (λ2, t1): Intrinsic fluorescence (skin fluorescence) signal value of skin tissue

I (λ1, t1): Transmitted light signal value of skin tissue at excitation wavelength

I (λ2, t2): Transmitted light signal value of skin tissue at the wavelength of emitted light

k1, k2: the exponential coefficient of the calibration function for the excitation and emission wavelengths

I ₀ (λ 2, t 1): Intrinsic fluorescence signal value in standard specimen

I ₀ (λ 1, t 1): the transmitted light signal value in the standard specimen at the excitation wavelength

I ₀ (λ 2, t 2): Transmitted light signal value at standard wavelength at the wavelength of emitted light)

As described above, the transmitted light detection type skin fluorescence measuring apparatus according to the present invention has the following effects.

First, in the present invention, it is possible to easily diagnose diabetic diseases by evaluating autofluorescence of the skin. Mass screening for identification of potential diabetic patients is possible, and risk of heart-vessel and related complications can be predicted.

Secondly, in the present invention, in measuring skin fluorescence, a method of measuring transmitted light can be used to fundamentally eliminate the cause of error due to mirror reflection on the surface of the skin, while it is possible to remove skin roughness, scars, The effect of internal factors such as external factors, pigmentation of skin and hemoglobin of blood is minimized, so that it is possible to diagnose an accurate disease through this.

Third, in the present invention, errors due to scattering and absorption of light generated in the skin can be easily corrected, so that it is possible to accurately measure skin fluorescence, thereby enabling accurate diagnosis of diseases.

Fourthly, according to the present invention, the light source and the light detector and the light detector and the light detector and the detector are simple in construction and can be manufactured in a small size. If the light source and the light detector are placed on the object to be measured, By non-invasively detecting the corrected skin fluorescence signal through the switching control, it is possible to perform an immediate diagnosis and improve the reliability of the signal, thereby improving the accuracy of diagnosis.

FIG. 1 is a view illustrating the principle of measurement of a transmitted-light detection type skin fluorescence measurement apparatus according to the present invention, in which light input from a light source and light detected by a light detector are classified by time,
FIG. 2 is a schematic view of a first embodiment of a transmitted-light detection type skin fluorescence measurement apparatus according to the present invention,
FIG. 3 is a schematic view showing a second embodiment of a transmitted-light detection type skin fluorescence measurement apparatus according to the present invention,
FIG. 4 shows a schematic configuration of a transmitted-light detection type skin fluorescence measuring apparatus according to a third embodiment of the present invention.

The present invention relates to a skin fluorescence measuring apparatus for irradiating excitation light to the skin for the purpose of diagnosing diseases such as diabetes and detecting skin fluorescence generated thereby. In particular, The present invention provides a transmitted-light detection type skin fluorescence measurement device capable of precisely measuring skin fluorescence information corrected from transmitted fluorescence light and skin fluorescence information at a position where the transmitted light is detected.

For this purpose, in the present invention, the measurement object and the standard specimen to be actually diagnosed are sequentially measured, and the information obtained from the measurement object and the information obtained from the standard specimen are compared with each other in order to eliminate the individual deviation of the measurement object There is also provided a transmitted-light detection type skin fluorescence measurement device capable of providing a calibrated skin fluorescence value by sequentially controlling on / off of a light source and a photodetector according to a predetermined condition required in the process.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a transmitted-light detection type skin fluorescence measuring apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In order to measure the fluorescence emitted from the skin, it is necessary to consider factors affecting the fluorescence measured together with the selection of the skin subject. Fluorescence measured depends not only on the fluorescent material contained in the skin but also on the scattering and light absorption properties of the light generated in the skin. In particular, there is a need to correct the fluorescence values measured in consideration of the excitation wavelength to be excited to excite the fluorescent material and the light absorption and light scattering effect at the fluorescence wavelength generated in the fluorescent material. Therefore, the following empirical equations can be considered to reduce the influence of the optical components affecting the fluorescence intensity.

AF _corr = AF / (T ₁ ^k1 T ₂ ^k2 ) - Equation (1)

Measured to obtain the corrected fluorescence intensity AFcorr where fluorescence intensity AF was divided by this diffusion transmitted light values T ₁ and T ₂ values of the transmitted light diffused radiation (emissioin) in the fluorescence wavelength band. The two diffuse transmission light values are adjusted by the orders k1 and k2 without order.

In the present invention, Equation (1) is used to obtain skin fluorescence values corrected by the transmitted light detection method, and specific values are introduced to actually obtain corrected fluorescence values through experiments.

I (λ2, t1): Intrinsic fluorescence (skin fluorescence) signal value of skin tissue

I (λ1, t1): Transmitted light signal value of skin tissue at excitation wavelength

I (λ2, t2): Transmitted light signal value of skin tissue at the wavelength of emitted light

k1, k2: the exponential coefficient of the calibration function for the excitation and emission wavelengths

The relationship of the corrected skin fluorescence value newly induced by the transmitted light detection method is as follows.

AF _tissue = [I (λ2, t1)] / [I (λ1, t1) ^k1I (λ2, t2) ^k2 ]; k1, k2 < 1: - (2)

Here, AF _tissue is a correction signal of the intrinsic fluorescence of the skin tissue.

The light measurements are repeated periodically at different time intervals t1 and t2, and the obtained measurement results are averaged to improve accuracy. Measurements are recorded in the form of time diagrams to track changes in a timely manner.

On the other hand, there is a need for calibrations for deviations that depend on the instrument and calibration measurements for comparison with the results obtained from different specimens. Therefore, in the present invention, the same measurement was performed by introducing a standard specimen together with the measurement of the skin tissue. In order to increase the measurement accuracy, the transmitted light signal values I ₀ (λ 1, t 1) and I ₀ (λ 2, t 2) of the standard specimen fluorescence intensity I ₀ (λ 2, t 1) .

The signal values generated during the measurement of the introduced standard specimen are indicated as follows, similar to the target skin tissue symbol.

I ₀ (λ 2, t 1): Intrinsic fluorescence signal value in standard specimen

I ₀ (λ 1, t 1): the transmitted light signal value in the standard specimen at the excitation wavelength

I ₀ (λ 2, t 2): Transmitted light signal value at standard wavelength at the wavelength of emitted light

The processing of the signal obtained from the standard specimen is also applied through the following equation (3) similarly to equation (2).

_{AF reference = [I 0 (λ2} , t1)] / [I 0 (λ1, t1) k1 I 0 (λ2, t2) k2] - Formula (3)

The results obtained by dividing the AF _tissue by the AF _reference are as follows. The normalized and finally corrected intrinsic fluorescence values are as follows.

AF _corr = K (AF _tissue / AF _reference )

_{AF corr = K [I (λ2} , t1) / I 0 (λ2, t1)] / {[I (λ1, t1) / I 0 (λ1, t1)] k1 [I (λ2, t2) / I 0 ( ? 2, t2)]} ^k2 - Equation (5)

(Where K is the ratio factor taking into consideration the characteristics of the standard specimen used).

Expression (5) can be simplified as follows.

_{AF corr = K [I (λ2} , t1) / I 0 (λ2, t1)] / {[T (λ1)] k1 [T (λ2)]} k2 - (6)

T 1 (λ 1) = I (λ 1, t 1) / I ₀ (λ 1, t 1)

T (λ2) = I (λ2 , t2) / I 0 (λ2, t2): spread transmission coefficient at the radiation wavelength

Therefore, in the transmitted light detection type skin fluorescence measurement apparatus according to the present invention, the calibrated skin fluorescence value is calculated through the above calculation process.

In this regard, the principle proposed for measurement is described in detail in Fig.

FIG. 1 is a time chart illustrating the principle of the measurement of the transmitted light detection type skin fluorescence measurement apparatus according to the present invention, in which light input from a light source and light detected by a photodetector are represented by time. As shown in FIG. 1, In the detection type skin fluorescence measurement apparatus, the first condition for irradiating the light corresponding to the wavelength range of the excitation light (first wavelength,? ₁ ) as the input and the first condition for the wavelength range of the skin fluorescence (second wavelength,? ₂ ) The second condition for irradiating the light corresponding to the first condition is temporally separated and the measurements under the first condition and the second condition are continuously performed. The wavelength range of the irradiation light corresponding to the first condition and the second condition may be selectively configured according to the skin fluorescence to be detected. For example, considering the case of detecting skin fluorescence for AGE as a preferred embodiment of the present invention , Light having a first wavelength of 370 nm ± 20 nm can be used as the excitation light for fluorescence excitation under the first condition and a second wavelength having a wavelength of 440 nm ± 20 nm corresponding to the wavelength of the skin fluorescence for AGE under the second condition Light can be selectively used.

That is, by using an optical sensor including light sources emitting light of two different wavelengths and a photodetector detecting light of two different wavelengths, a skin tissue corresponding to an object to be measured in a diagnostic observation process, Or calibration is made by contacting the reference sample with the optical sensor.

Regarding the measurement process, FIG. 1 (a) shows a time diagram of operation showing that each light source for two different wavelengths is operating in a temporally separate manner. At this time, it is configured such that the light? (? 1, t1) emitted from the first light source as the excitation light source and the light? (? 2, t2) from the second light source as the standard light source of the other wavelength range are present in different and non- It is important to do.

On the other hand, FIG. 1 (b) shows an operation time diagram for two photodetectors. Two signals for excited skin fluorescence and transmitted light are generated at the same time interval in which the light? (? 1, t1) from the first light source is irradiated. That is, the two signals generated at the excitation wavelength are the transmitted light signal I (λ1, t1) and the excited fluorescence signal I (λ2, t1).

On the other hand, only a single signal is formed at the time when the light? (? 2, t2) by the second light source irradiates light. That is, in the signal generated by the second light source, only the transmitted light signal I (? 2, t2) is detected in the wavelength range of the irradiated light.

Therefore, in the transmitted-light detection type skin fluorescence measurement apparatus according to the present invention, as shown in Fig. 1, the light irradiation by the first light source and the light irradiation by the second light source are separated temporally, A signal detected from the photodetector is collected at each light irradiation, and then the calculated signal is calculated through the above equation to calculate the calibrated skin fluorescence value.

FIGS. 2 to 4 illustrate an embodiment of a transmitted-light detection type skin fluorescence measurement apparatus according to a preferred embodiment of the present invention, which is implemented according to the above-described measurement principle.

2 to 4, the transmitted light detection type skin fluorescence measurement apparatus according to the present invention includes an optical sensor that irradiates excitation light to the skin and can detect skin fluorescence and the like, , And a main body for analyzing the information detected from the optical sensor and displaying the information.

However, if it is only one of the preferred embodiments of the present invention that the optical sensor and the main body are separately structured as described above, a separate sensor may be formed instead of a separate main body, if necessary. It can also be produced by connecting.

The transmitted light detection type skin fluorescence measurement apparatus according to the present invention is configured to include a light source and a photodetector to irradiate light to an object to be measured and detect skin fluorescence or the like generated by the irradiated light.

Particularly, in the present invention, in order to correct the detected skin fluorescence value and provide an accurate skin fluorescence value, two light sources for irradiating light of different wavelengths and two light sources for transmitting light of different wavelengths and skin fluorescence And a plurality of photodetectors capable of detecting the photodetector.

Specifically, these two light sources is the excitation light wavelength (the first wavelength, λ ₁₎ first light source and the excitation wavelength (second wavelength, λ ₂₎ of skin fluorescence generated by the light, which emits light corresponding to the And a second light source for emitting the corresponding light, and the two photodetectors are installed at positions capable of detecting transmitted light for the first light source and the second light source.

These two photodetectors include a first photodetector for detecting the transmitted light (? ₁ ) for the excitation light from the first light source, a skin fluorescence (? ₂ ) generated by the excitation light, and a transmitted light and a second photodetector for detecting the second wavelength? ₂ .

Therefore, the two light sources and the photodetector are disposed at positions capable of simultaneously detecting the transmitted light and the skin fluorescence, and are preferably disposed at the ends of the optical sensor so as to form a space into which the measurement object or the standard specimen can be inserted. The photodetectors can be arranged to face each other.

In this case, the light source and the photodetector do not need to be disposed directly facing each other. When the light source and the photodetector are connected by optical signal transmission means such as a light guide, the distal end portion where light is irradiated and the distal end portion where light is detected are arranged to face each other It suffices.

Therefore, in the transmitted light detection type skin fluorescence measurement apparatus according to the present invention, a light guide is disposed between the insertion spaces in which the measurement object is located in the light source, and light can be transmitted from the light source to the skin or the standard specimen, . In addition, a light guide may be disposed between the insertion space and the photodetector so that transmitted light and skin fluorescence transmitted through the skin can also be transmitted to the photodetector through the light guide.

The optical sensor including the light source and the photodetector may be configured to transmit light and detect an optical signal to a measurement object, and the end of the optical sensor may be configured to contact the skin or the standard specimen to be measured.

The optical sensor may have a clamping configuration in which a first fixing part on a light source side to which light is irradiated from a light source and a second fixing part on a light detecting side to detect light face each other and form an insertion space therebetween.

Therefore, when the measurement object is positioned in the insertion space between the first fixing part and the second fixing part, which are in the form of a clamp, light irradiation and light detection are performed on the measurement object.

In the case where there is no object to be measured in the insertion space, the standard specimen can be inserted into the insertion space, and the inserted standard specimen is subjected to light irradiation and light detection. The standard specimen can be configured to be automatically inserted into the insertion space. In this case, when the measurement target is removed from the insertion space after light irradiation and photo detection are performed on the measurement target, the standard specimen is automatically inserted It is preferable to perform the light irradiation and the light detection on the standard specimen.

At this time, the standard specimen can be selected to have optical characteristics of fluorescence and diffusion transmission similar to the body tissue to be measured.

Meanwhile, the transmitted light detection type skin fluorescence measurement apparatus according to the present invention may include a light source switching control unit for controlling on / off of the first light source and the second light source, and more preferably, And a photodetector switching control section capable of controlling on / off of the second photodetector.

The light source switching control unit and the photodetector switching control unit perform switching control so that each light source and the photodetector can operate correctly according to detection conditions of emitted skin fluorescence and transmitted light in order to precisely calibrate and calculate the skin fluorescence value.

That is, the light source switching control section controls the on / off of the light source, that is, the light source is turned on or off according to the light irradiation condition in the transmitted light detection type skin fluorescence measurement apparatus. For example, ₁ ) is irradiated to the object to be measured, the second light source is extinguished and the first light source is turned on so that each light source is controlled to switch so that only the first light source irradiates the light of the first wavelength range, and the other wavelength bands of the radiation (λ ₂₎ gekkeum to the second condition for irradiating the measurement target and off the first light source, the light irradiation of a second wavelength from the second light source only to occur a second light source is being lit, the respective light source Can be configured.

Similarly, the photodetector switching controller also controls on / off of the photodetector in accordance with each measurement condition, and turns on / off the power of the photodetector for detecting the light of the wavelength band to be detected under the current measurement condition .

In particular, in the case of configuring the photodetector switching control section, it is necessary to detect the optical signal for the second wavelength in both the first condition for irradiating the excitation light of the first wavelength band and the second condition for irradiating the radiation light of the second wavelength band It is preferable that the second photodetector for optical detection of the bar and the second wavelength continuously maintains the ON state.

During the entire measurement process including the first condition and the second condition, the switching control for the light source is sequentially performed for a predetermined time, and the switching cycle of each light source is controlled by the flow rate It is preferable that the switching control is performed at a high frequency of 10 to 100 Hz so that the change of the transmittance does not affect the measurement. In this process, all the light sources are turned off before the light irradiation and the light detection are performed, and then the level of the dark signal is evaluated to automatically compensate for light leaking from the outside.

In the transmitted light detection type skin fluorescence measuring apparatus according to the present invention, an optical filter may be optionally installed in front of the light source and the photodetector. The optical filter may be installed on the optical path of the light source so that only the light of a desired wavelength range can be irradiated through the light source, or may be installed in front of the optical detector so that only light of the wavelength band to be detected by the optical detector can enter into the optical detector. have.

Meanwhile, the transmitted light detection type skin fluorescence measurement apparatus according to the present invention may include a main body configured to be connectable to an optical sensor including two light sources and two photodetectors, And calculating the size of the skin fluorescence that has been corrected from the information obtained.

The main body may be configured to be connected to the optical sensor by wired / wireless connection so as to receive the information detected from the optical sensor. The calculation unit of the main body may perform an arithmetic operation as described above to calculate the corrected skin fluorescence value can do.

In addition, the main body may include a display unit for outputting information on the skin fluorescence signal, and the display unit may output the corrected skin fluorescence signal calculated by the operation unit to the outside.

Therefore, in the transmitted light detection type skin fluorescence measuring apparatus according to the present invention having such a configuration, when the measurement object is located in the insertion space of the optical sensor, the optical sensor performs the light irradiation and the light detection process on the measurement object, The standard specimen is inserted into the standard specimen and the light irradiation process and the light detection process performed on the standard specimen are performed in the same manner.

The measured information about the object to be measured and the standard specimen is transmitted to an operation unit of the main body, and the operation unit calculates the corrected skin fluorescence value for the actual measurement target using the information about the transmitted fluorescence signal and the transmitted light signal. The calculated result is displayed externally through the display unit formed on the main body.

The measurements are repeated at regular intervals, and all of the repeated measurement results are stored in the optical sensor through the memory, and the stored information is stored in the arithmetic unit to perform the arithmetic operation in which the correction is performed. At this time, the repeated measurement results may be calculated as an average value and used for the calculation, and preferably, the measurement results may be stored in the form of a time diagram in order to track changes in the measurement results.

2, the first light source 111 and the second light source 112 are measured by a common light guide in FIG. 2. In FIG. 2, And a common photodetector light guide is arranged on the opposite side of the common light source light guide, and the first photodetector 121 and the second light And an optical sensor 100 configured to transmit transmitted light and skin fluorescence to a detector.

As shown in FIG. 2, light emitted from the first light source 111 and the second light source 112 enters the common light source light guide 117 through the lens. The light source may be an LED, a laser diode or other light sources that provide sufficient light brightness in the excitation and emission wavelength range. A light source filter 114 is provided between the first light source 111 and the common light source light guide 117 so as to suppress the second wavelength? 2 light generated from the second light source 112. The second light source 112 is not required to have a separate filter, and the second detection filter 125 is provided before the second optical detector 122. Accordingly, the wavelength range of the light emitted from the second light source 112 may be larger than the wavelength range passing through the second detection filter 125. For example, the white light LED may be used as the second light source 112.

Light generated from the first light source 111 and the second light source 112 enters the common light source optical guide 117 through the first dichroic mirror 113. At this time, The objective lenses 115 and 116 can be provided between the respective light sources. At this time, the first dichroic mirror 113 reflects the first wavelength? 1 light, which is the short wavelength light, and the second wavelength? 2, which is the long wavelength light, under the condition that the second wavelength? 2 is larger than the first wavelength? Light passes through. Conversely, the first dichroic mirror 113 may be configured to pass a short wavelength and reflect a long wavelength. In this case, the positions of the first light source 111 and the second light source 112 must be changed. The power of the first light source 111 and the second light source 112 may be supplied while being switched by a light source switching controller and preferably supplied through a relay switch in a driver module 134 as shown in FIG. The power supply to the first light source 111 and the second light source 112 proceeds alternately.

When the measurement object T is located in the insertion space of the optical sensor 100, the optical sensor 100 performs a light irradiation process and an optical detection process on the measurement target T, Then, the standard specimen R is automatically inserted, so that the light irradiation and light detection processes performed on the standard specimen R are performed in the same manner.

The measured information about the measurement object T and the standard specimen R is transmitted to the operation unit 210 of the main body 200. The operation unit 210 uses the information about the transmitted fluorescence signal and the transmitted light signal, The corrected skin fluorescence value for the measurement object is calculated. The calculated result is displayed outside through the display unit 220 formed on the main body 200.

2, the light entered through the common detection light guide 128 enters the first and second photodetectors 121 and 122 through the same optical system as the objective lenses 126 and 127 Goes. The role of distributing the light to the first photodetector 121 and the second photodetector 122 is performed by the second dichroic mirror 123. The second dichroic mirror 123 can be configured to reflect short-wavelength light as in the first dichroic mirror 113 and to transmit the long-wavelength light in the opposite direction. As in the case of changing the positions of the first light source 111 and the second light source 112 in the first dichroic mirror 113, the positions of the first light source 111 and the second light source 112 If the position is changed, the corresponding wavelength passing and reflection characteristics can be reversed. At this time, the objective lenses 126 and 127 have a function of effectively collecting light in the photodetector.

In addition, a filter may be provided in front of the photodetector. The first detection filter 124 installed in front of the first photodetector 121 is configured to pass the spectral component of the first wavelength? 1 and suppress the second wavelength? 2 spectral component. While the second detection filter 125 is configured to pass the second wavelength? 2 spectral component and suppress the first wavelength? 1 spectral component.

The transmitted light detection type skin fluorescence measurement apparatus according to the present invention includes an electronic control module (ECM) 100 for controlling irradiation of light from a light source in the optical sensor 100, processing the detected optical signal, , 130).

The signals sent from the first photodetector 121 and the second photodetector 122 enter analog-to-digital converters 131 and 132 belonging to the electronic control module 130 and then transmitted to a data transfer module (DTM 133, and a bidirectional bus to the operation unit 210 of the main body. Here, the data transmission module 133 serves as a multiplexer by time division control transmission of a digital signal, and selects data. The synchronization function of the data transfer module and the relay switch is performed by a bidirectional bus from the main body.

The main body 200 controls the driver module 134 corresponding to the light source switching control unit and can control the access module of the standard specimen R through the measurement inserting unit. In addition, the main body calculates a corrected fluorescence value according to the above-described equation by performing statistical processing of signals, and can perform operations related to signal processing, control, and data input, and outputs a work result through the display unit 220 .

Meanwhile, in a preferred embodiment of the present invention, light having a first wavelength of 370 nm ± 20 nm can be used as excitation light for fluorescence excitation for skin fluorescence detection for AGE, and as the synchrotron radiation, It is possible to use light having the second wavelength of 440 nm 20 nm corresponding thereto.

In this case, the first light source 111 may be a light emitting diode that emits light of a first wavelength range of 370 nm ± 20 nm, and the second light source 112 may emit light of a second wavelength range of 440 nm ± 20 nm Emitting diodes. The first photodetector 121 may be a photodiode for detecting light in a first wavelength band and the second photodetector 122 may be a photodiode for detecting light in a second wavelength band.

FIG. 3 illustrates another embodiment of a transmitted-light detection type skin fluorescence measurement apparatus according to the present invention, and is related to a structure in which a pair of optical guides are provided individually on the light source side and the optical detector side, respectively.

That is, as shown in FIG. 2, the transmitted light detection type skin fluorescence measurement apparatus according to FIG. 3 commonly includes a first light source, a second light source, a first photodetector, a second photodetector and an electronic control module, The individual light guides are connected to the respective light sources and the photodetector side instead of the common light guide to constitute the optical transmission.

3, the first light source light guide 314 and the second light source light guide 315 are connected to the first light source 311 and the second light source 312, respectively, and on the opposite side thereof, The light guide 325 and the second detection light guide 326 are connected to the first photodetector 321 and the second photodetector 322, respectively.

Accordingly, light is transmitted through each of the light guides for light irradiation and light detection. In this embodiment, a dichroic mirror for collecting or dispersing light is not necessary as in the example of FIG.

In the example of Fig. 3, light is not transmitted through an optical system such as a dichroic mirror, and the light guide can be directly connected to the light source or the photodetector, so that the structure like the objective lens for focusing the light is not required.

The data transmission module 333 includes a light source filter 313, first and second detection filters 323 and 324, analog-to-digital converters 331 and 332, an operation unit 410 and a display unit 420, And the main body 400 including the main body 400 are as described above with reference to FIG.

In another embodiment of the transmitted-light detection type skin fluorescence measuring apparatus according to the present invention, in FIG. 4, a light source and a photodetector constitute the most terminal of the optical sensor, For example.

Accordingly, in the embodiment of FIG. 4, the first light source 511 and the second light source 512 located on the same chip generate light of the first wavelength lambda 1 and the second wavelength lambda 2, respectively, If the light source 511 does not include the spectral component of the second wavelength lambda 2, a filter is not required.

In the embodiment of FIG. 4, the photodetector is composed of two sectors, and band filters for dividing the first wavelength lambda 1 and the second wavelength lambda 2 before the two sectors are located, so that the first photodetector 521 and the second And constitutes a photodetector 522. The electronic control module sequentially turns on and off the first light source 511 and the second light source 512 and also controls and synchronizes the optical detection signals received from the optical detector by the two channels in a time division manner.

Meanwhile, in the embodiment of FIG. 4, the light source side and the photodetector side end portions may be formed in a clip shape so that the measurement target can be fixed while being pressed while the light source and the photodetector are positioned corresponding to each other. have. In this case, the measurement object is inserted into the light source sensor of the clip type, and then the light irradiation process and the light detection process are performed on the measurement object, and the standard specimen is automatically inserted into the clip after the measurement object is removed. The same procedure as the light irradiation and the light detection process is performed on the standard specimen.

And then transmits information about the optical signal measured by the main body 600, which is fixed through the communication module, to the corresponding digital signal, and the calculator 610 of the main body uses the information about the transmitted fluorescence signal and the transmitted light signal Thereby calculating the corrected skin fluorescence value for the actual measurement target. The calculated result is displayed externally through the display unit 620 formed on the main body 600.

While the present invention has been described with reference to the preferred embodiments thereof, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. There will be. In addition, many modifications may be made to the particular situation or material within the scope of the invention, without departing from the essential scope thereof. Therefore, the present invention is not limited to the detailed description of the preferred embodiments of the present invention, but includes all embodiments within the scope of the appended claims.

100: optical sensor 200:
111: first light source 112: second light source
113: first dichroic mirror 114: light source filter
115, 116: objective lens 117: common light source light guide
121: first optical detector 122: second optical detector
123: second dichroic mirror 124: first detection filter
125: second detection filter 126, 127: objective lens
128: Common detection light guide 130: Electronic control module
131, 132: analog-to-digital converter 133: data transmission module
134: Driver module 210: Operation unit
220:
300: optical sensor 400:
311: first light source 312: second light source
313: Light source filter 314: First light source light guide
315: first light source optical guide 321: first optical detector
322: second photodetector 323: first detection filter
324: second detection filter 325: first detection light guide
326: second detection light guide 330: electronic control module
331, 332: Analog-to-digital converter 333: Data transfer module
334: Driver module 410: Operation unit
420:
511: first light source 512: second light source
521: first photodetector 522: second photodetector
530: Electronic control module 531, 532: Analog-to-digital converter
533: Data transfer module 534: Driver module
600: main body 610:
620:
T: Measurement object (skin) R: Standard specimen

Claims (33)

A standard specimen or an object to be measured,
A first light source for emitting excitation light;
A second light source for emitting light of a wavelength band of the skin fluorescence excited and excited by the excitation light from the first light source;
A first photodetector for detecting transmitted light with respect to light emitted from the first light source;
A second photodetector for detecting transmitted fluorescence of light emitted from the second light source and skin fluorescence emitted by the light emitted from the first light source;
A light source switching controller for controlling the blinking of the first light source and the second light source;
And a calculation unit for calculating the skin fluorescence signal corrected from the fluorescence signal and the transmitted light signal detected from the first photodetector and the second photodetector,
Wherein the light source switching control unit controls switching between the first light source and the second light source such that the first light source and the second light source are kept on for different time periods.
delete The method according to claim 1,
The light source switching control unit sequentially detects the first light source and the second light source so as to sequentially detect the fluorescence signal and the transmitted light signal for the first light source and the transmitted light signal for the second light source, Wherein the skin fluorescence measurement device comprises:
The method according to claim 1,
Wherein the measurement object and the standard specimen are selectively positioned on the optical path of the first light source and the second light source.
The method according to claim 1,
Wherein the first light source irradiates light having a wavelength of 370 nm ± 20 nm.
The method according to claim 1,
Wherein the second light source irradiates light having a wavelength of 440 nm ± 20 nm.
The method according to claim 1,
Wherein the light source switching control unit controls both the first light source and the second light source to be turned off before the respective light sources are turned on.
The method of claim 7,
Wherein when the light source switching control unit extinguishes both the first light source and the second light source, the first photodetector and the second photodetector measure a dark signal, the operation unit stores the measured dark signal, And compensates for the detected fluorescence signal and the transmitted light signal.
The method according to claim 1,
Wherein the light source switching control unit controls the first light source unit and the second light source unit to be repeatedly turned on and off at a cycle of 10 to 100 Hz.
The method according to claim 1,
Further comprising a photodetector switching control unit for controlling on / off of the first photodetector and the second photodetector.
The method according to claim 1,
An optical sensor including the first light source, the second light source, the first photodetector, and the second photodetector;
And a body including the calculating unit, the body being configured to be electrically connected to the optical sensor.
The method of claim 11,
The optical sensor includes a first fixing part connected to the first light source and the second light source, a second fixing part connected to the first photodetector and the second optical detector, and the first fixing part and the second fixing part face each other And forms an insertion space therebetween while viewing the skin fluorescence measurement device.
The method of claim 11,
Wherein the optical sensor includes a memory for storing the detected information.
The method of claim 11,
Wherein the optical sensor includes a common light source optical guide for commonly transmitting light emitted from the first light source and the second light source.
15. The method of claim 14,
Wherein the optical sensor includes a common detection light guide for commonly transmitting transmitted light and skin fluorescence to the first photodetector and the second photodetector.
15. The method of claim 14,
Wherein the optical sensor is provided with a first dichroic mirror on an optical path so as to transmit each light emitted from the first light source and the second light source to the common light source optical guide. Fluorescence measuring device.
18. The method of claim 16,
Wherein the optical sensor is provided with a second dichroic mirror on an optical path for separating the light transmitted from the common detection light guide and transmitting the separated light to the first photodetector and the second photodetector. Type skin fluorescence measuring device.
18. The method of claim 16,
A light source filter is provided between the first light source and the first dichroic mirror for transmitting light of a first wavelength emitted from the first light source and suppressing light of a second wavelength emitted from the second light source To be measured.
18. The method of claim 16,
And an objective lens for focusing the light emitted from the first light source and the second light source is provided between the first light source and the second light source and the first dichroic mirror. Measuring device.
18. The method of claim 17,
A first detection filter is provided between the second dichroic mirror and the first photodetector for passing light of a first wavelength and suppressing light of a second wavelength, And a second detection filter for suppressing the light of the first wavelength and transmitting the light of the second wavelength is provided between the two photodetectors.
18. The method of claim 17,
And an objective lens for focusing the light having passed through the second dichroic mirror to the first photodetector and the second photodetector is provided between the first photodetector and the second photodetector and the second dichroic mirror And the skin fluorescence measurement device is provided with a plurality of light sources.
The method of claim 11,
Wherein the optical sensor includes a first light source light guide for transmitting light emitted from the first light source and a second light source light guide for transmitting light emitted from the second light source. Device.
23. The method of claim 22,
Wherein the optical sensor includes a first detection light guide for transmitting transmitted light and skin fluorescence to the first photodetector and a second detection light guide for transmitting the transmitted light and the skin fluorescence to the first photodetector and the second photodetector, .
23. The method of claim 22,
Wherein a light source filter is provided between the first light source and the first light source light guide for transmitting light of a first wavelength emitted from the first light source and suppressing light of a second wavelength emitted from the second light source A skin fluorescence measuring device.
24. The method of claim 23,
Wherein a first detection filter is provided between the first light source light guide and the first light detector so as to pass light of a first wavelength and suppress light of a second wavelength, And a second detection filter for suppressing light of a first wavelength and transmitting light of a second wavelength is provided between the detectors.
The method of claim 12,
Wherein a first light source and a second light source are provided at the ends of the first fixing unit, the first light source and the second light source are configured to directly irradiate light to the measurement object, and at the end of the second fixing unit, Wherein the first photodetector and the second photodetector are provided to detect transmitted light and skin fluorescence directly from the first photodetector and the second photodetector.
27. The method of claim 26,
The first photodetector and the second photodetector are respectively characterized in that band filters for distinguishing the first wavelength lambda 1 and the second wavelength lambda 2 before the two sectors of the photodetector composed of two sectors are respectively located Transmitted light detection type skin fluorescence measurement device.
27. The method of claim 26,
Wherein the first fixing part and the second fixing part are manufactured in a clip shape so as to be fixed while pressing the measurement target.
The method of claim 12,
Wherein the optical sensor is mounted with a movable standard specimen and the standard specimen is moved to be positioned in the insertion space when the measurement object is removed from the insertion space between the first fixing unit and the second fixing unit A skin fluorescence measuring device.
29. The method of claim 29,
Wherein the optical sensor performs measurement on the skin when the skin to be measured is located in the insertion space and performs measurement on the standard specimen when the measurement object is removed and the standard specimen is located in the insertion space, Fluorescence measuring device.
32. The method of claim 30,
Wherein the optical sensor is configured to store measured results of skin and standard specimens to be measured and to transmit detected information about the stored skin and standard specimen to the main body to calculate the corrected skin fluorescence value in the arithmetic unit, Detection type skin fluorescence measurement device.
The method of claim 11,
Wherein the main body further comprises a display unit, and the display unit outputs the corrected skin fluorescence signal calculated by the calculation unit.
The method according to claim 1,
Wherein the calculation unit calculates the skin fluorescence value corrected by the following equation.
_{Formula: AF corr = K [I (} λ2, t1) / I 0 (λ2, t1)] / {[T (λ1)] ^k1 [T (? 2)]} ^k2
(Where, T (λ1) = I ( λ1, t1) / I 0 (λ1, t1): diffuse transmission coefficient at the excitation wavelength
T (λ2) = I (λ2 , t2) / I 0 (λ2, t2): spread transmission coefficient at the radiation wavelength
I (λ2, t1): Intrinsic fluorescence (skin fluorescence) signal value of skin tissue
I (λ1, t1): Transmitted light signal value of skin tissue at excitation wavelength
I (λ2, t2): Transmitted light signal value of skin tissue at the wavelength of emitted light
k1, k2: the exponential coefficient of the calibration function for the excitation and emission wavelengths
I ₀ (λ 2, t 1): Intrinsic fluorescence signal value in standard specimen
I ₀ (λ 1, t 1): the transmitted light signal value in the standard specimen at the excitation wavelength
I ₀ (λ 2, t 2): Transmitted light signal value at standard wavelength at the wavelength of emitted light)

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