RU2007137558A - METHOD AND DEVICE FOR MICRO-CALORIMETRIC MEASUREMENT OF SPEED OF LOCAL METABOLISM OF TISSUE, WATER CONTENT IN CELLULAR TISSUE, CONCENTRATION OF BIOCHEMICAL COMPONENTS OF BLOOD AND SESSION OF THE SYSTEM - Google Patents

Abstract

1. The method of microcalorimetric measurement of tissue metabolism intensity, characterized in that locally measure the heat transfer through the surface of a limited area of the skin by measuring the heat transfer heat flux density due to the temperature gradient, the heat transfer due to evaporative cooling during imperceptible perspiration, and the external pressure on the surface controlled area, and thus determine the value of heat production (thermal effect) and speed l local metabolism in the volume of tissue located under a controlled area of the skin surface using a calibration procedure. ! 2. The method according to claim 1, characterized in that the external pressure is determined by atmospheric pressure, the value of which is measured. ! 3. The method according to claim 1, characterized in that the skin is located on the wrist. ! 4. The method according to claim 1, characterized in that it further comprises measuring air humidity. ! 5. The method according to claim 1, characterized in that it further comprises measuring the surface temperature of the skin. ! 6. The method according to claim 1, characterized in that the level of glucose in the blood is determined by the metabolic rate of the local tissue site. ! 7. The method according to claim 6, characterized in that they determine the level of glucose in the blood, and calibration parameters are determined by invasive measurements of the level of glucose in the blood. ! 8. The method according to claim 6 or 7, characterized in that the glucose content in the blood is continuously measured under the conditions of a glucose tolerance test and the sensitivity of the tissue to insulin is determined. ! 9. The method according to claim 8, characterized in that the sugar curve

Claims (277)

1. The method of microcalorimetric measurement of tissue metabolism intensity, characterized in that locally measure the heat transfer through the surface of a limited area of the skin by measuring the heat transfer heat flux density due to the temperature gradient, the heat transfer due to evaporative cooling during imperceptible perspiration, and the external pressure on the surface controlled area, and thus determine the value of heat production (thermal effect) and speed l local metabolism in the volume of tissue located under a controlled area of the skin surface using a calibration procedure. 2. The method according to claim 1, characterized in that the external pressure is determined by atmospheric pressure, the value of which is measured. 3. The method according to claim 1, characterized in that the skin is located on the wrist. 4. The method according to claim 1, characterized in that it further comprises measuring air humidity. 5. The method according to claim 1, characterized in that it further comprises measuring the surface temperature of the skin. 6. The method according to claim 1, characterized in that the level of glucose in the blood is determined by the metabolic rate of the local tissue site. 7. The method according to claim 6, characterized in that they determine the level of glucose in the blood, and calibration parameters are determined by invasive measurements of the level of glucose in the blood. 8. The method according to claim 6 or 7, characterized in that the glucose content in the blood is continuously measured under the conditions of a glucose tolerance test and the sensitivity of the tissue to insulin is determined. 9. The method according to claim 8, characterized in that the sugar curve is recorded under conditions of physical impact on a controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field. 10. The method according to claim 1, characterized in that they determine the pressure in the microcirculation system. 11. The method according to claim 10, characterized in that they measure the dependence of the density of the water flow through the RSE on external pressure and determine the average capillary pressure, the minimum pressure in the microcirculation system, the maximum pressure in the microcirculation system, the osmotic pressure of the intercellular tissue, the permeability of the intercellular tissue to water and biochemical blood components. 12. The method according to claim 1, characterized in that the tissue (osmotic) pressure of the intercellular substance is determined. 13. The method according to claim 1, characterized in that determine the amount of water in the intercellular substance. 14. The method according to claim 1, characterized in that they determine the elastic pressure of the intercellular substance. 15. The method according to claim 1, characterized in that determine the resulting transcapillary flow of water. 16. The method according to claim 1, characterized in that the osmotic pressure of blood plasma is determined. 17. The method of microcalorimetric measurement of the intensity of tissue metabolism according to claim 1, characterized in that the local heat production of the tissue is determined by measuring the density of the water flow (water transport rate) through the surface of a limited area of the skin during imperceptible perspiration and ambient temperature, and thus determine the thermal the effect and metabolic rate in the volume of tissue located under the specified area of the skin. 18. The method according to 17, characterized in that measure the total amount of water evaporating from the surface of a limited area of the skin into a closed cavity. 19. The method according to p. 18, characterized in that the total amount of water and its rate of change is determined by measuring the amount of water in a closed cavity located above the controlled surface of the skin without mechanical contact and having diffusion and thermal contact with it. 20. The method according to p. 18, characterized in that the total amount of water and its rate of change is determined by measuring the amount of water in a closed cavity located on the surface of the skin with a metered pressure. 21. The method according to p. 18 or 19, characterized in that the total amount of water in a closed cavity is determined using spectroscopy methods. 22. The method according to item 21, wherein the total amount of water in a closed cavity is determined using optical acoustic spectroscopy methods. 23. The method according to p. 18 or 19, characterized in that the total amount of water in a closed cavity is determined using electrometric methods. 24. The method according to p. 18 or 19, characterized in that the total amount of water in a closed cavity is determined using methods of thermometry. 25. The method according to p. 18 or 19, characterized in that the total amount of water in a closed cavity is determined using electrochemical methods. 26. The method according to p. 18, characterized in that the total amount of water and its rate of change is determined by measuring the amount of water in the volume of tissue under a controlled surface area, limited by a waterproof applicator applied to the surface with a metered pressure. 27. The method according to p, characterized in that the total amount of water and its rate of change is determined by measuring the amount of water in the intercellular substance. 28. The method according to p, characterized in that the total amount of water and its rate of change is determined by measuring the amount of water in the stratum corneum of the epidermis. 29. The method according to p, characterized in that the amount of water and its rate of change is determined by measuring the electrical characteristics of the stratum corneum of the epidermis. 30. The method according to clause 29, wherein the amount of water and its rate of change is determined by measuring the electrical conductivity of the stratum corneum of the epidermis. 31. The method according to clause 29, wherein the amount of water and its rate of change is determined by measuring the dielectric constant of the stratum corneum of the epidermis. 32. The method according to p. 30 or 31, characterized in that the measurements are carried out using impervious to water electrodes applied to the skin surface with a metered pressure, at least one of which is dry. 33. The method according to p, characterized in that the amount of water in the stratum corneum of the epidermis is determined by measuring the spectral characteristics of the stratum corneum of the epidermis. 34. The method according to p, characterized in that the amount of water in the stratum corneum of the epidermis is determined by measuring the reflection coefficient of electromagnetic radiation from the surface of the stratum corneum of the epidermis. 35. The method according to p, characterized in that the amount of water in the stratum corneum of the epidermis is determined by measuring the absorption coefficient of electromagnetic radiation of the stratum corneum of the epidermis. 36. The method according to p, characterized in that the amount of water in the stratum corneum of the epidermis is determined by measuring the thermophysical characteristics of the stratum corneum of the epidermis. 37. The method according to clause 36, wherein the amount of water in the stratum corneum of the epidermis is determined by measuring the thermal diffusivity. 38. The method according to p. 26, characterized in that they determine the local heat production of the body by measuring the temperature of the tissue and the temperature of the surrounding air. 39. The method according to § 38, characterized in that after applying a waterproof applicator to the surface of a limited area of the skin, the skin surface temperature is measured. 40. The method according to 17, characterized in that it further measures atmospheric pressure. 41. The method according to 17, characterized in that the skin is located on the wrist. 42. The method according to 17, characterized in that it provides for the measurement of humidity. 43. The method according to 17, characterized in that it comprises measuring the surface temperature of the skin. 44. The method according to 17, characterized in that it provides for a calibration procedure. 45. The method according to 17, characterized in that the intensity of metabolism of a local tissue site determines the level of glucose in the blood. 46. The method according to item 45, wherein determining the level of glucose in the blood, and calibration parameters are determined by invasive measurements of the level of glucose in the blood. 47. The method according to item 45 or 46, characterized in that in a continuous mode measure the glucose level in the blood under the conditions of the glucose tolerance test and determine the sensitivity of the tissue to insulin. 48. The method according to clause 47, wherein the sugar curve is recorded under conditions of physical impact on the controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field. 49. The method according to 17, characterized in that they determine the pressure in the microcirculation system. 50. The method according to 49, characterized in that they measure the dependence of the density of the water flow through the RSE on external pressure and determine the average capillary pressure, the minimum pressure in the microcirculation system, the maximum pressure in the microcirculation system, the osmotic pressure of the intercellular substance, the permeability of the intercellular substance to water and biochemical blood components. 51. The method according to 17, characterized in that determine the tissue (osmotic) pressure of the intercellular substance. 52. The method according to 17, characterized in that determine the amount of water in the intercellular substance. 53. The method according to § 52, characterized in that the dependence of the amount of water in the intercellular tissue on the external physical factor is measured and the amount of water that provides swelling of the intercellular substance is determined. 54. The method according to item 53, wherein the external physical factor is selected from the group including external pressure, local decompression, heating, cooling, electric current and magnetic field. 55. The method according to item 53, characterized in that they measure additional parameters that determine the state of the intercellular substance. 56. The method according to item 55, wherein the additional parameter is selected from the group including blood sugar, air temperature and atmospheric pressure. 57. The method according to item 53, wherein the dependence of the amount of water in the intercellular tissue on the external pressure is measured and the average capillary pressure, the minimum and maximum pressure in the microcirculation system, the osmotic pressure of the intercellular tissue, the filtration coefficient for water and biochemical blood components are determined. 58. The method according to any one of paragraphs.52-57, characterized in that according to the amount of water in the intercellular tissue, a pathological condition of the intercellular tissue is diagnosed. 59. The method according to any one of paragraphs.52-57, characterized in that the amount of water in the intercellular tissue is used to visualize and measure the magnitude of the effect of pharmacological and cosmetic preparations on the tissue site. 60. The method according to 17, characterized in that they determine the elastic pressure of the intercellular substance. 61. The method according to 17, characterized in that they determine the resulting transcapillary flow of water. 62. The method according to 17, characterized in that determine the osmotic pressure of blood plasma. 63. The method according to p, characterized in that the method comprises the following stages: applying a waterproof applicator with metered pressure to the surface of the local area of the RSE; continuous measurement of blood glucose under the conditions of a glucose tolerance test and determination of tissue sensitivity to insulin. 64. The method according to item 63, wherein the sugar curve is recorded under conditions of physical impact on a controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field. 65. The method according to item 45, wherein the method comprises measuring glucose in a continuous mode with a standard glucose tolerance test with the construction of a sugar curve, and the sugar curve is recorded under conditions of physical impact on a controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field, and according to the characteristics of the sugar curve and its changes during exercise, they diagnose a prediabetic or diabetic state and determine the sensitivity of the tissue to insulin. 66. The method according to item 53, wherein the method comprises the following steps: measuring a parameter characterizing the state of the tissue site, where the parameter characterizing the state of the tissue is the amount of water in the intercellular substance; measure the dependence of the parameter characterizing the state of the tissue from the effects of an external physical factor; and determine the deviation of the state of the tissue site from the norm and the degree of violation. 67. The method according to p, characterized in that according to the dependence of the amount of water in the intercellular substance from external influences determine the amount of water, which determines the swelling of the intercellular tissue. 68. The method according to p. 66 or 67, characterized in that the exposure to a physical factor is selected from the group including thermal exposure (heating and cooling), external pressure, local decompression, electric current and magnetic field. 69. The method according to p. 66 or 67, characterized in that they measure additional parameters that determine the state of local tissue. 70. The method according to p, characterized in that the additional parameter is selected from the group including air temperature, blood sugar and atmospheric pressure. 71. The method according to p, characterized in that it further determines the spatial heterogeneity of the measured parameter and localize the tissue region with an altered state of the intercellular substance by the characteristics of the heterogeneity and determine the degree of violation. 72. The method according to p, characterized in that the spatial heterogeneity is determined using two or more sensors. 73. The method according to p, characterized in that apply the method of mapping the registered parameter. 74. The method according to p, characterized in that the mapping is carried out using a multi-channel sensor system or scanning method. 75. The method according to p, characterized in that the localization of the site with the changed characteristics is carried out previously using additional diagnostic methods. 76. The method according to item 75, wherein the additional diagnostic method is selected from the group of methods, including x-ray, ultrasound, mechanical, electrometric, optical and chemical methods. 77. The method according to any one of paragraphs.66-76, characterized in that it is intended for the diagnosis of diseases characterized by a change in the state of intercellular tissue. 78. The method according to p, characterized in that it is intended for the diagnosis of a pathological condition characterized by swelling of the tissue. 79. The method according to p, characterized in that it is intended to diagnose the effect of the "orange peel". 80. The method according to p, characterized in that it is intended for the diagnosis of the pathological condition of internal organs and tissues. 81. The method according to p, characterized in that it is intended for the diagnosis of malignant tumors. 82. The method according to p, characterized in that it is intended for the diagnosis of malignant tumors of internal organs and mammary gland. 83. The method according to p, characterized in that it is intended to diagnose the functional state of the skin area. 84. The method according to any one of paragraphs 53, 54, 66, characterized in that the method further comprises the following steps: measuring a parameter characterizing the state of the tissue site, where the parameter characterizing the state of the tissue site is the amount of water in the intercellular substance; determination by the values of the parameter and setting the mode and dose (intensity) of the physical impact; dosed effect of physical factors on the local tissue site. 85. The method of claim 84, wherein said parameters are air temperature and glucose content. 86. The method according to p. 84 or 85, characterized in that the specified physical effect is selected from the group including mechanical and electromagnetic effects. 87. The method according to p, characterized in that the specified physical effect is selected from the group including local decompression, external pressure, heating, cooling, electric current and magnetic field. 88. The method according to p. 84 or 85, characterized in that the mode and intensity of exposure is determined and set in advance according to a given program and the effect is further carried out without measuring a parameter characterizing the state of the tissue site. 89. The method according to p. 84 or 85, characterized in that it is intended to activate local tissue metabolism. 90. The method according to p, characterized in that it is intended to stimulate the growth of tissue cells. 91. The method according to p. 90, characterized in that it is intended to stimulate the growth of breast tissue cells. 92. The method according to p. 84 or 85, characterized in that it is intended to eliminate the effect of "orange peel" on the skin. 93. The method according to p. 84 or 85, characterized in that it is intended for the treatment of obesity. 94. The method according to p. 84 or 85, characterized in that it is intended for the prevention of type 2 diabetes. 95. The method according to p. 84 or 85, characterized in that it is intended for the treatment of erectile dysfunction. 96. The method according to p, characterized in that it is intended for the treatment of osteochondrosis. 97. The method according to p. 84 or 85, characterized in that in the process of exposure to further control the intensity of local metabolism and / or microcirculation of the tissue site that is affected. 98. The method according to p. 84 or 85, characterized in that the physical impact is local decompression (compression). 99. The method according to p, characterized in that the depth of the drainage effect on the tissue and the volumetric flow of tissue fluid and lymphatic drainage are set and adjusted by adjusting the exposure mode. 100. The method according to p. 99, characterized in that the depth of the drainage exposure is set and adjusted by adjusting the amount of decompression (compression), and the volumetric flow of tissue fluid and lymphatic drainage is regulated by adjusting the frequency and duty cycle of the pneumatic pulses. 101. The method according to any one of claims 68-100, characterized in that the blood pressure is additionally measured and a decompression value is set depending on the pressure value and the tissue thickness. 102. The method according to any one of Claims 45 or 46, characterized in that a parameter characterizing the cardiovascular system and determined by the blood glucose is measured, and the blood glucose is determined from the air temperature and the calibration curve of this parameter. 103. The method according to p. 102, characterized in that the parameter characterizing the cardiovascular system is selected from the group including heart rate, cardiac output, blood flow velocity in a controlled area of the tissue, blood pressure, pressure in the microcirculation system, capillary pressure, the magnitude of the resulting transcapillary flow, tissue (osmotic) pressure of the intercellular tissue, elastic pressure of the intercellular tissue (stress of elastic deformation), hydraulic resistance of the capillary rows or the amount of water in the intercellular tissue. 104. The method according to p, characterized in that the elastic pressure is determined by measuring the elastic moduli of the tissue. 105. The method according to p. 103, characterized in that the measurement of the magnitude of the transcapillary flow is based on measuring the density of the water flow through the RSE or the amount of water in the RSE. 106. The method according to p. 104, characterized in that by continuously measuring a parameter characterizing the cardiovascular system, continuous monitoring of blood glucose is carried out. 107. The method according to p, characterized in that the continuous monitoring of blood glucose is carried out under physiological load on a controlled area of tissue. 108. The method according to p. 107, characterized in that the physiological load is local muscle load. 109. The method according to p. 107, wherein the physiological load is venous or arterial occlusion. 110. The method according to p, characterized in that it is intended for recording the results of the glucose tolerance test (sugar curve). 111. The method according to p. 102, characterized in that it is intended for the diagnosis of prediabetic state. 112. The method according to p. 102, characterized in that it is intended to determine the insulin resistance of the tissue site. 113. The method according to p. 102, characterized in that the sugar curve is recorded under conditions of physical impact on the controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field. 114. The method according to p. 107, characterized in that the sugar curve is recorded under conditions of physical impact on a controlled tissue site, and the physical effect is selected from the group including heating, cooling, external pressure, local decompression, electric current or magnetic field. 115. The method according to p. 102, characterized in that said method comprises the following steps: measuring air temperature and blood glucose; measuring at least one quantitative parameter characterizing the cardiovascular system; determination of the calculated value of the quantitative parameter of the cardiovascular system from the measured values of glucose in the blood and air temperature; diagnosis by determining the deviations of the measured quantitative parameter of the cardiovascular system from the calculated norm. 116. The method according to p. 115, characterized in that the parameter characterizing the cardiovascular system is a parameter selected from the group including the heart rate, the value of the cardiac output, blood pressure, pressure in the microcirculation system, the resulting transcapillary flow , the amount of water in the intercellular substance or the osmotic pressure of the intercellular substance. 117. The method according to p, characterized in that the capillary pressure is measured and deviations of the blood pressure in the circulatory system from the norm are determined. 118. The method according to any one of paragraphs.115-117, characterized in that it is intended for the diagnosis of cardiovascular diseases. 119. The method according to p, characterized in that it is intended for the diagnosis of hypertension. 120. The method according to p, characterized in that it is intended for the diagnosis of hypotension. 121. The method according to p, characterized in that the value of the resulting transcapillary flow is determined by measuring the density of the water flow through the RSE or the amount of water in the RSE. 122. The method according to p, characterized in that the amount of water in the intercellular tissue is determined by measuring the density of the flow of water through the RSE or the amount of water in the RSE. 123. The method according to p. 115, characterized in that it is designed to determine deviations from the norm of the parameters of local metabolism. 124. The method according to p. 123, characterized in that it is intended to diagnose the functional state of the tissue site. 125. The method according to p. 124, characterized in that it is intended for the diagnosis and monitoring of the functional state of the cardiovascular system in patients with diabetes. 126. The method according to p. 124, characterized in that it is intended for the diagnosis and monitoring of obesity and impaired transport of tissue fluid and lymphatic drainage. 127. The method according to p. 124, characterized in that it is intended for the diagnosis and monitoring of age-related changes in tissue. 128. The method according to p. 124, characterized in that it is intended for the diagnosis and monitoring of the functional state of the skin. 129. The method according to p. 124, characterized in that it is intended for the diagnosis and monitoring of treatment of malignant tumors. 130. The method according to p, characterized in that it is intended for the diagnosis and monitoring of treatment of breast cancer. 131. The method according to p. 129 or 130, characterized in that the mapping of a parameter characterizing microcirculation by multichannel measurements or scanning is performed. 132. A device for measuring the intensity of tissue metabolism, characterized in that the measurement is carried out locally, and the device is equipped with a sensor for measuring the density of the flow of water vapor evaporating from the surface of a limited area of the skin during imperceptible perspiration, and a heat flux sensor. 133. The device according to p, characterized in that the heat flow sensor is made in the form of an air temperature sensor. 134. The device according to p, characterized in that the sensor of the density of water flow is made in the form of a sensor of differential concentration of water vapor. 135. The device according to p, characterized in that the water flow density sensor is based on the methods of spectroscopy of the stratum corneum. 136. The device according to p, characterized in that it contains a sensor of the density of the flow of water based on the measurement of the electrical characteristics of the stratum corneum. 137. The device according to p, characterized in that it is equipped with a measuring capsule with a sensor for measuring the total amount of water evaporating from the surface of the skin during imperceptible perspiration and a temperature sensor. 138. The device according to p, characterized in that it contains a device for creating a metered pressure on the skin surface, and the measuring capsule contains a sealed cavity, the working surface of which is in contact with the skin, made in the form of a rigid membrane, semi-permeable to water. 139. The device according to p, characterized in that the measuring capsule contains a cavity having diffusion contact with the skin surface and not having mechanical contact with the skin surface. 140. The device according to any one of paragraphs.113-139, characterized in that the cavity of the measuring capsule contains a material that absorbs water, and serves as a sensitive element of the sensor for the amount of water. 141. The device according to p, characterized in that the water quantity sensor is made in the form of a conductivity sensor. 142. The device according to p. 140, characterized in that the water quantity sensor is made in the form of a sensor that measures mechanical characteristics. 143. The device according to p. 139 or 139, characterized in that the water quantity sensor is made in the form of a water vapor pressure sensor. 144. The device according to p. 139 or 139, characterized in that the water quantity sensor is made in the form of a sensor for the concentration of water vapor. 145. The device according to p, characterized in that the water quantity sensor is made in the form of a dielectric constant sensor. 146. The device according to p, characterized in that the water quantity sensor is made in the form of a sensor of thermophysical characteristics of water vapor. 147. The device according to p, characterized in that the water quantity sensor is made in the form of a heat capacity sensor for water vapor. 148. The device according to p, characterized in that the water quantity sensor is made in the form of a sensor of thermal conductivity of water vapor. 149. The device according to p, characterized in that the water vapor concentration sensor is made in the form of a sensor based on spectroscopy methods. 150. The device according to p, characterized in that the water vapor concentration sensor is made in the form of a sensor based on the method of optical acoustic spectroscopy. 151. The device according to p, characterized in that it is equipped with a waterproof applicator applied to the surface of the stratum corneum with a device for creating a metered pressure, and a sensor for measuring the amount of water in the volume of tissue located under the applicator. 152. The device according to p, characterized in that the water quantity sensor is made in the form of a sensor for measuring the amount of water in the stratum corneum of the epidermis of the skin (RSE). 153. The device according to p, characterized in that it contains a sensor of the amount of water in the stratum corneum, based on measuring the spectral characteristics of the stratum corneum. 154. The device according to p. 153, characterized in that it contains a sensor of the amount of water in the stratum corneum, based on measuring the reflection coefficient of the stratum corneum on spectral lines of water absorption. 155. The device according to p, characterized in that it comprises a sensor for the amount of water in the stratum corneum based on measuring the absorption coefficient of the stratum corneum on water absorption lines. 156. The device according to p, characterized in that the sensor of the amount of water in the stratum corneum is based on measuring the thermophysical characteristics of the stratum corneum. 157. The device according to p, characterized in that the sensor of the amount of water in the stratum corneum is based on measuring the temperature of the stratum corneum under the applicator. 158. The device according to p, characterized in that the sensor of the amount of water in the stratum corneum is made in the form of an electrometric sensor that measures the electrical characteristics of the stratum corneum. 159. The device according to p. 158, characterized in that it contains a base and measuring electrodes, a device for creating a metered pressure of the electrodes on the skin surface, a power source and a measuring unit, and at least one of the electrodes is made in the form of a dry waterproof electrode. 160. The device according to p, characterized in that the area of the base electrode exceeds the area of the measuring electrode. 161. The device according to p, characterized in that the area of one of the electrodes, measuring, satisfies the condition: S (mm ² )> 2P (mm) · 0.4 (mm), where S represents the area of the electrode and P represents the perimeter of the surface in contact with the skin. 162. The device according to p. 159, characterized in that the working surface of the base electrode is equipped with a means for increasing the conductivity of the skin at the point of contact. 163. The device according to p, characterized in that the means for increasing the conductivity of the skin at the point of contact is an electrically conductive paste. 164. The device according to p. 159, characterized in that the electrodes are made in the form of combined disks with a total area determined by a large diameter. 165. The device according to p, characterized in that the electrodes are made in the form of combined coaxial (coaxial) disks. 166. The device according to any one of paragraphs.157-165, characterized in that the measuring unit is made in the form of a device for measuring the transverse conductivity of the stratum corneum of the epidermis in direct current. 167. The device according to any one of paragraphs.157-165, characterized in that the measuring unit is made in the form of a device for measuring the dielectric constant of the stratum corneum of the epidermis at low frequencies. 168. The device according to p, characterized in that the sensor of the amount of water in the volume of tissue under the applicator is based on the measurement of tissue pressure. 169. The device according to p, characterized in that the sensor of the amount of water in the volume of tissue under the applicator is based on the measurement of hydraulic pressure in the microcirculation system. 170. The device according to p, characterized in that the sensor of the amount of water in the volume of tissue under the applicator is based on measuring elastic pressure. 171. The device according to p, characterized in that the sensor of the amount of water in the volume of tissue under the applicator is based on measuring the temperature of the tissue. 172. The device according to p. 151, characterized in that the sensor of the amount of water in the volume of tissue under the applicator is based on measuring the spectral characteristics of the tissue. 173. The device according to p, characterized in that it comprises a measuring unit made in the form of a microprocessor. 174. The device according to p, characterized in that it contains an atmospheric pressure sensor. 175. The device according to p, characterized in that it contains an indicator. 176. The device according to any one of paragraphs.138, 149 or 159, characterized in that the device for creating a metered pressure is made using pneumatic, mechanical, piezoelectric, electromagnetic, vacuum or hydraulic principles. 177. The device according to p, characterized in that it contains a calibrated heat source. 178. The device according to p, characterized in that the calibrated heat source is made in the form of electrical resistance. 179. The device according to p, characterized in that the calibrated heat source is made in the form of an element acting on the Peltier effect. 180. The device according to p, characterized in that it contains two or more sensors of the amount of water. 181. The device according to p, characterized in that it contains a matrix of sensors for mapping a parameter. 182. The device according to p, characterized in that it contains a scanning device for mapping a parameter. 183. The device according to p, characterized in that it contains a humidity meter. 184. The device according to p, characterized in that it contains a temperature sensor on the surface of the skin. 185. The device according to p, characterized in that it is designed to measure the level of glucose in the blood. 186. The device according to p, characterized in that it is designed to measure the elastic pressure of the intercellular substance. 187. The device according to p, characterized in that it is designed to measure the amount of water in the intercellular substance. 188. The device according to p, characterized in that it contains a device for dosed exposure to a tissue site using physical factors. 189. The device according to p, characterized in that the dosed effect is selected from the group including external pressure, local decompression, heating, cooling, electric current and magnetic field. 190. The device according to p, characterized in that the device for dosed exposure is a device for creating a dosed pressure. 191. The device according to p, characterized in that the average amount of capillary pressure, as well as the minimum and maximum pressure in the microcirculation system, osmotic pressure of the intercellular tissue, filtration coefficients for water and biochemical blood components are determined by the amount of water in the intercellular substance. 192. The device according to any one of paragraphs.188-191, characterized in that it contains sensors for measuring additional parameters. 193. The device according to p. 192, characterized in that the additional parameters are selected from the group including glucose in the blood, air temperature and atmospheric pressure. 194. The device according to p, characterized in that it is designed to determine the amount of water that provides swelling of the intercellular substance. 195. The device according to p. 194, characterized in that it is intended for the diagnosis of pathological conditions of intercellular tissue. 196. The device according to p, characterized in that it is designed to measure capillary pressure. 197. The device according to p, characterized in that it is designed to measure tissue (osmotic) pressure of the intercellular substance. 198. The device according to p, characterized in that it is designed to measure the resulting transcapillary flow. 199. The device according to p, characterized in that it is designed to measure blood pressure. 200. The device according to p, characterized in that it contains a sensor for measuring glucose concentration in the stratum corneum of the epidermis. 201. The device according to claim 200, characterized in that the sensor for measuring the concentration of glucose in the stratum corneum is based on the electrochemical principle. 202. The device according to claim 200, characterized in that the sensor for measuring the concentration of glucose in the stratum corneum is based on spectroscopy methods. 203. The device according to claim 200, characterized in that the sensor for measuring glucose concentration in the stratum corneum is based on optical acoustic spectroscopy methods. 204. The device according to claim 200, characterized in that the sensor for measuring glucose concentration in the stratum corneum is based on the electrometric method. 205. The device according to p. 200, characterized in that it is designed to measure glucose in the blood. 206. The device according to p. 152, characterized in that the measurement is carried out locally, and the device is equipped with a waterproof applicator applied to the surface of the stratum corneum of the skin using a device for creating a metered pressure, a temperature sensor and a sensor for measuring the concentration of the biochemical component of blood plasma in the stratum corneum epidermis. 207. The device according to p. 206, characterized in that the sensor for measuring the biochemical component of blood plasma in the stratum corneum is based on the electrochemical principle. 208. The device according to p. 206, characterized in that the sensor for measuring the concentration of the biochemical component in the stratum corneum is based on the methods of optical-acoustic spectroscopy. 209. The device according to p. 206, characterized in that the sensor for measuring the concentration of the biochemical component of blood in the stratum corneum is based on the electrometric method. 210. The device according to p. 206, characterized in that the biochemical component of the blood is glucose. 211. The device according to p. 206, characterized in that the biochemical component of the blood is water. 212. The device according to p. 211, characterized in that the sensor for measuring the amount of water is based on measuring the physicomechanical characteristics of the tissue. 213. The device according to p. 212, characterized in that the sensor for measuring the amount of water is based on measuring the coefficient of elasticity of the tissue. 214. The device according to p. 212, characterized in that the sensor for measuring the amount of water is based on measuring the electrical characteristics of the tissue. 215. The device according to p. 206, characterized in that the waterproof applicator is made of a material that is transparent in the frequency range of the spectrum of electromagnetic radiation used for measurements. 216. The device according to p. 215, characterized in that the water quantity sensor is based on the method of optical acoustic spectroscopy. 217. The device according to p. 206, characterized in that it is designed to determine the sensitivity of tissue to insulin. 218. The device according to p. 217, characterized in that it further comprises a sensor for measuring insulin content in the stratum corneum of the epidermis. 219. The device according to p. 218, characterized in that it further measures the insulin content in the intercellular substance and determines the sensitivity of the tissue to insulin. 220. The device according to p. 219, characterized in that the insulin content in the intercellular substance is determined by its content in the stratum corneum. 221. The device according to p. 220, characterized in that it contains a device for creating a calibrated dosed external pressure on the surface of the controlled area. 222. The device according to any one of paragraphs.188-189, characterized in that it contains a device for creating a local dosed physical effect on the tissue site and a parameter sensor characterizing the state of the tissue site. 223. The device according to p. 222, characterized in that it is intended for the treatment of diseases of internal organs. 224. The device according to p. 222, characterized in that it is designed to measure the amount of water, which determines the swelling of the intercellular substance, and diagnose disorders of the tissue site. 225. The device according to p. 222, characterized in that said parameter is the amount of water in the intercellular substance. 226. The device according to p. 222, characterized in that the said parameters are air temperature and glucose content. 227. The device according to p. 222, characterized in that the specified physical effect is selected from the group including mechanical and electromagnetic effects. 228. The device according to p. 227, characterized in that said physical effect is selected from the group comprising local decompression, external pressure, heating, cooling, electric current and magnetic field. 229. The device according to p. 222, characterized in that it is intended to stimulate cell growth and activate local tissue metabolism. 230. The device according to p. 227, characterized in that it is intended to stimulate the growth of breast cells. 231. The device according to p. 222, characterized in that it is intended to eliminate the effect of "orange peel" on the skin. 232. The device according to p. 222, characterized in that it is intended for the treatment of obesity. 233. The device according to p. 222, characterized in that it is intended for the prevention of type 2 diabetes. 234. The device according to p. 222, characterized in that it is intended for the treatment of erectile dysfunction. 235. The device according to p. 222, characterized in that it is intended for the treatment of osteochondrosis. 236. The device according to p. 222, characterized in that it contains a device for creating two or more different physical factors of influence. 237. The device according to p. 222, characterized in that it contains a feedback sensor for monitoring the condition of the exposed tissue site. 238. The device according to p. 237, characterized in that the condition of the exposed tissue site is controlled by measuring the rate of local metabolism. 239. The device according to p. 237, characterized in that the condition of the exposed tissue site is controlled by measuring microcirculation parameters. 240. The device according to p. 237, characterized in that the condition of the exposed tissue site is controlled by measuring the amount of water in the intercellular substance. 241. The device according to p. 222, characterized in that the dosed effect is pulsating. 242. The device according to p. 222, characterized in that it contains a device for creating local decompression (compression). 243. The device according to p. 224, characterized in that it contains a device for smooth adjustment of parameters that determine the mode of exposure (the value of decompression (compression) and the frequency and duty cycle of the air pulses). 244. The device according to p. 243, characterized in that it contains a blood pressure sensor. 245. The device according to p. 233, characterized in that it contains a sensor for determining the insulin resistance of the exposed tissue. 246. The device according to p. 245, characterized in that it is used for the prevention of type 2 diabetes. 247. The device according to p. 246, characterized in that it is used for the prevention of type 2 diabetes in overweight patients. 248. The device according to p, characterized in that it contains an air temperature sensor, as a heat flow sensor, and a parameter parameter characterizing the cardiovascular system. 249. The device according to p. pressure in the microcirculation system, capillary pressure, the resulting transcapillary flow, tissue (osmotic) pressure of the intercellular tissue, elastic pressure of the intercellular tissue (stress of elastic deformation), hydraulic resistance of capillary vessels or the amount of water in the intracellular tissue. 250. The device according to p. 249, characterized in that the transcapillary flow magnitude sensor is based on measuring the density of water flow through the RSE or the amount of water in the RSE. 251. The device according to p. 248, characterized in that it is intended for continuous monitoring of blood glucose. 252. The device according to p. 251, characterized in that it is intended for continuous monitoring of blood glucose during the glucose tolerance test (recording a continuous sugar curve). 253. The device according to p. 185 or 248, characterized in that it is intended for the diagnosis of prediabetic state. 254. The device according to p. 185 or 248, characterized in that it is intended for determining insulin resistance. 255. The device according to p. 185 or 248, characterized in that it contains a device for exerting a physical effect on a tissue site. 256. The device according to p. 255, characterized in that it contains a device for providing a dosed heat exposure, external pressure, local decompression, electric current or magnetic field. 257. The device according to p. 185 or 248, characterized in that it contains two or more sensors. 258. The device according to p. 185 or 248, characterized in that it contains two or more devices for providing a dosed physical effect. 259. The device according to p. 185 or 248, characterized in that it contains a device for creating a local physiological load. 260. The device according to p. 259, characterized in that it contains a device for creating local muscle load. 261. The device according to p. 259, characterized in that it contains a device for creating venous or arterial occlusion. 262. The device according to p. 248, characterized in that it contains an air temperature sensor, a sensor for blood glucose and a sensor for measuring at least one of the parameters characterizing the cardiovascular system. 263. The device according to p. 266, characterized in that it contains a sensor selected from the group including a sensor for measuring heart rate, cardiac output, blood pressure, pressure in the microcirculation system, the resulting transcapillary flow, the amount of water in the intercellular substance or osmotic pressure of the intercellular substance. 264. The device according to p. 263, characterized in that it contains a sensor for measuring pressure in the microcirculation system of the tissue site. 265. The device according to p. 264, characterized in that it contains a sensor of the amount of water in the intercellular substance. 266. The device according to p. 264, characterized in that the sensor for measuring the resulting transcapillary flow is based on measuring the density of the water flow through the RSE or the amount of water in the RSE. 267. The device according to any one of paragraphs.262-266, characterized in that it is applicable for the diagnosis of malignant tumors and, in particular, breast cancer. 268. The device according to any one of paragraphs.262-266, characterized in that the pressure sensor in the microcirculation system is made in the form of a multi-channel system or contains a device for mapping the parameter by scanning method. 269. The use of the device according to p. 132 for visualizing the effects of therapeutic effects. 270. The use according to p. 269, characterized in that it is applicable for visualizing the effects of medicinal therapeutic effects. 271. The use according to p. 269, characterized in that it is applicable for visualizing the effects of physiotherapeutic effects. 272. The use of the device according to p. 180 for the diagnosis of malignant tumors. 273. The use of claim 272, wherein the malignant tumor is breast cancer. 274. The method according to p, characterized in that the measurement of a parameter characterizing the state of the tissue is carried out using the device according to any one of claims 132-221. 275. The method according to p, characterized in that the mode of which is determined by measuring parameters characterizing the local state of the tissue using the device according to any one of paragraphs.132-205. 276. The method according to p. 275, characterized in that in the process of exposure in order to control the effectiveness of the impact, continuous monitoring of the parameters characterizing the state of the tissue site is carried out. 277. The method according to p. 276, characterized in that the mode and intensity of the exposure is adjusted during the exposure in order to optimize the effect of drainage.