RU2802161C1 - Method for determining the dose of combined uv and ir exposure to human skin - Google Patents

Abstract

FIELD: health tools.

SUBSTANCE: determination of the recommended safe time of human skin exposure to sunlight in order to prevent skin diseases, including skin cancer. The claimed method for determining the dose of combined UV and IR exposure to human skin consists in obtaining and subsequent processing of data from an IR exposure sensor, a UV exposure sensor on the subject's skin. The method is based on an individual evaluation algorithm, including simultaneously determining the intensity of UV and IR ranges, the time of exposure to the skin of the examined, age indicators, and also taking into account the color characteristic of the skin of the examined, to calculate the safe values of the current and cumulative radiation components by obtaining the results of the examination in real time, allowing to take into account the data obtained jointly and simultaneously from two UV and IR sensors, allowing to determine both the negative impact and the positive impact on human skin, as well as to determine the individual threshold value of the dose of combined UV and IR exposure to human skin, assessing the risks of combined UV and IR exposure to human skin when using protective and preventive agents.

EFFECT: determining the effect of a dose of the combined UV and IR components of the solar spectrum on human skin to develop a calculation algorithm and a device for determining the cumulative dose of UV and IR radiation received by a person and estimating the recommended time spent under the influence of UV and IR radiation.

1 cl, 2 ex, 3 dwg

Description

The greatest negative impact on human skin in the form of photodamage, burns and cancer is caused by the ultraviolet A (UV-A; 290-400 nanometers) of the solar spectrum. The infrared component of the spectrum (IR-A, IR-B, IR-C; 0.76-1000 microns), when a certain power threshold is reached, also has a significant biological effect on human skin and leads to an increase in temperature, since IR radiation is absorbed and is converted into heat. The skin is a strongly scattering medium, since it consists of a large number of scattering centers randomly distributed in the volume, the dimensions of which in most cases are commensurate with the wavelength of the applied optical radiation. Skin scattering is most significant in the wavelength range from 600 to 1500 nm.

The degree of light scattering also depends on the optical properties of the skin. The skin, like other biological tissues, is characterized by its own spectral dependence of the absorption of optical radiation, in particular, the skin intensively absorbs radiation from the ultraviolet and adjacent visible spectrum, as well as rays with a wavelength of more than 1400-2000 nm. The smallest absorption of light by the skin is observed in the wavelength range from 800 to 1200 nm. The skin contains chromophores that absorb light in the visible and near ultraviolet regions. These include vitamins, flavins, flavin enzymes, hemoglobin, melanin, carotenoids, etc. In the infrared region, skin absorption is determined mainly by water.

It can be noted that melanin has the highest absorption coefficient in the epidermis, and hemoglobin and oxyhemoglobin in the dermis. The nature and consequences of the interaction of optical radiation with the human body is also determined by its penetrating ability, which largely depends on the optical properties of the skin. The depth of penetration of light increases with the transition from ultraviolet radiation to visible (orange): from 0.7-0.8 to 2.5 mm, and for the red radiation range it already corresponds to 20-30 mm. In the near infrared range of optical radiation, the penetrating power reaches its maximum values (60-70 mm), and then sharply decreases again. An increase in skin temperature increases light scattering in the dermis and reduces it in the subcutaneous fat layer.

There are a large number of factors that affect the interaction of the skin with UV and IR radiation: light reflection by slightly pigmented skin reaches 43-55%; Body temperature; the gender of the person; age; circulatory condition.

Pigmented skin reflects optical radiation 6-8% less. In men, the reflection coefficient is 5-7% lower than in women. Cooling the skin area causes a decrease in light reflection by 10-15%.

The combined effect of UV and IR exposure on human skin is the subject of a separate study, since, depending on the parameters, it can have both a positive and a negative effect on the skin.

The purpose of the present invention is to create a method for determining the dose of combined UV and IR exposure to human skin, taking into account individual parameters.

A known method for controlling the level of solar radiation in the UV range and a device for its implementation (RU 2 094 820 C1), which provides for setting the threshold value for converting UV radiation into visible radiation, changing the specific value of the flux of converted UV radiation until its conversion threshold is passed and registration of radiation of the visible spectrum at the transition of a given threshold.

The disadvantage of this method is the determination of only one of the components of the solar spectrum, leading to negative consequences for human health: UV radiation, as well as the inability to take into account the degree of pigmentation of the skin of a particular person, his age and other risk factors.

Known system used to calculate the dose of solar radiation in a given range of wavelengths: a wearable device equipped with sensors capable of detecting position data of one or more points of the body in accordance with at least the azimuth and inclination relative to a vertical line; a geolocation sensor associated with said person; remote computing unit, functionally associated with satellite devices; mobile telecommunications device located near a person (RU 2 750 058 C2).

The disadvantage of this method is the measurement of only a certain range of UV light and taking it into account when calculating the recommended period of a person's stay under the influence of solar radiation. It is known that the IR component has a significant thermal effect and significantly affects the perception of UV radiation, and in different situations it can both enhance and weaken the damaging effect of the UV component of the solar spectrum.

As a prototype, a device is considered for determining the recommended time a person is under the influence of ultraviolet irradiation (RU 2 150 973 C1), which contains a photodetector for measuring the biologically effective intensity of UV irradiation, a photodetector for measuring the light reflectance of the skin and a device with recommended times for a person to be under exposure to UV radiation, calculated on the basis of the obtained measurement results using the mathematical formula: Ti=Ai/KJi, where Ti is the recommended time for a person to stay under the influence of UV radiation to exclude (implement) the occurrence of the i-th medical and biological effect, expressed in seconds ; Ai - multiplier (for the i-th biomedical effect and the wavelength range on which the skin light reflectance is measured), expressed in J/m ² ; K is the light reflectance of the user's skin; Ji - biologically effective intensity of UV irradiation reaching a person (for the i-th biomedical effect), expressed in W/m ² .

The disadvantage of this invention is the measurement of a given range of UV light and taking it into account when calculating the recommended period of a person's stay under the influence of solar radiation, while the effect of thermal radiation from the solar spectrum is not taken into account. To eliminate this drawback, the claimed method is proposed for determining the dose of combined UV and IR exposure to the skin, taking into account individual human parameters, which takes into account the current and cumulative part of the solar radiation ranges.

The purpose of the present invention is achieved due to the fact that along with the ultraviolet radiation sensor implemented in the prototype, an additional infrared radiation sensor and programs for joint processing of data from two sensors are used. Any computer, such as a personal computer or a smartphone, can act as a computing device. A block diagram of the interaction of the components of the device for determining the cumulative dose of UV and IR radiation received by a person and estimating the recommended time spent under the influence of UV and IR irradiation is illustrated in FIG. 3.

To achieve a technical result, a method for determining the dose of combined UV and IR exposure to human skin, which consists in obtaining and subsequent processing of data from an IR exposure sensor, a UV exposure sensor on the skin of the subject, characterized in that the method is based on an individual evaluation algorithm, including simultaneously determining the intensity of UV and IR ranges, the time of exposure to the skin of the examined, age indicators, and also taking into account the color characteristics of the skin of the examined, to calculate the safe values of the current and cumulative radiation components by obtaining the results of the examination in real time, allowing to take into account the data obtained jointly and simultaneously from two UV and IR sensors, which make it possible to determine both a negative effect on human skin and a positive effect, as well as to determine the individual threshold value of the dose of combined UV and IR exposure to human skin, assessing the risks of combined UV and IR effects on human skin when using protective and prophylactic agents.

Unlike analogs and prototype, in the present invention, to determine the recommended safe time for exposure to sunlight on human skin, two ranges are measured: UV and IR components of the spectrum, and the parameters of the individual sensitivity of a particular person to solar radiation are taken into account in the calculation, which is relevant and an important task from the point of view of the prevention of skin diseases, including skin cancer.

A novelty is the algorithm for calculating the safe cumulative dose of UV and IR radiation received by human skin. The device for determining these parameters takes into account the individual parameters of human skin, including the degree of pigmentation.

The technical result of the method consists in determining the effect of the dose of the combined UV and IR components of the solar spectrum on human skin, developing a calculation algorithm and a device for determining the cumulative dose of UV and IR radiation received by a person and estimating the recommended time spent under the influence of UV and IR irradiation.

The recommended exposure time to UV and IR irradiation according to the present invention is calculated by the formula:

Where - the coefficient of age, is determined empirically for each age group, - the time recommended by WHO for each Fitzpatrick skin phototype at the current value of the UV index, UVI - UV index.

The cumulative UV dose as a percentage of the recommended dose is calculated at least once per minute using the formula:

Where - coefficient of synergy of the joint influence of UV and IR radiation.

The cumulative dose of IC as a percentage of the recommended one is calculated at least once per minute according to the formula:

Where - the area of the irradiated surface of the body m ² , - current level of IR radiation in W/ ^m2 , - coefficient of resistance to IR radiation for each Fitzpatrick skin phototype, is the maximum recommended exposure dose.

Individualization of parameters consists in a quantitative assessment of factors affecting the interaction of the skin with UV and IR radiation

Example 1. Subject at the age of 23, after measuring the level of UV radiation and determining it as high on a 10-point assessment of the intensity level (measured value = 6), the maximum safe residence time was determined while maintaining the existing UV intensity up to 50 minutes. The level of IR radiation was 40 percent with this combination of available indicators, so the current parameters are safe (Fig. 1). Negative effects on the skin of the subject are not detected. The cumulative part is that after a combined exposure of more than 50 minutes, there will be a synergistic effect and an increase in the negative impact on the skin.

Example 2. An examinee with skin type 2, after measuring the level of UV radiation and determining the intensity level as high by 10 points -5, the maximum safe residence time was determined while maintaining the existing intensity of the UV index 1.2 up to 60 minutes (Fig. 2). The risk of sunburn was determined to be low. The level of IR radiation was 60 percent, with this combination of available indicators, the current parameters are safe for exposure times up to 60 minutes. Negative effects on the skin of the subject are not detected. The cumulative part is that after a combined exposure of more than 60 minutes, there will be a synergistic effect and an increase in the negative impact on the skin.

Literature

1. Skin (structure, function, general pathology and therapy). Ed. Chernukha A.M., Frolova E.P. M.: Medicine; 1982. [Kozha (stroenie, funktsiya, obshchaya patologiya i terapiya). Ed by Chernukh A.M., Frolov E.P. M.: Meditsina; 1982. (In Russ.)].

2. Myadelets O.D., Adaskevich V.P. Morphofunctional dermatology. M.: Medlit; 2006. [Myadelets OD, Adaskevich VP. Morfunktsional'naya dermatology. M.: Medlit; 2006. (In Russ.)].

3. Montagna W, Parackal P. The structure and function of skin. N.Y.: Academic Press; 1974.

4. Kirichinsky A.R. Reflex physiotherapy. K.: Medgiz; 1959. [Kirichinskiy AR. Reflectornaya fizioterapiya. Kiev: Medgiz; 1959. (In Russ.)].

5. Ulashchik V.S. Skin receptors and therapeutic physical factors. Issues of balneology, physiotherapy and physiotherapy [54, 56, 61]. QUESTIONS OF CURORTOLOGY, PHYSIOTHERAPY AND THERAPEUTIC PHYSICAL CULTURE, 1, 2018.

Claims (1)

A method for determining the dose of combined UV and IR exposure to human skin, which consists in obtaining and subsequent processing of data from an IR exposure sensor, a UV exposure sensor on the skin of the subject, characterized in that the method is based on an individual assessment algorithm, including simultaneously determining the intensity of UV and IR ranges, the time of exposure to the skin of the examined, age indicators, and also taking into account the color characteristics of the skin of the examined, to calculate the safe values of the current and cumulative radiation components by obtaining the results of the examination in real time, allowing to take into account the data obtained jointly and simultaneously from two UV and IR sensors, which allow to determine both the negative impact on human skin and the positive impact, as well as to determine the individual threshold value of the dose of combined UV and IR exposure to human skin, assessing the risks of combined UV and IR exposure to human skin when using protective and prophylactic agents.