RU2748686C1 - Method for diagnosis of light desynchronosis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to functional diagnostics, public health and health care, and can be used to assess the severity of light desynchronosis. A total assessment is carried out on a five-point scale, which is characterized by the following actions on patients over 45 years old. Evaluate the ratio of the evening value of the level of total blood cholesterol to the morning value; if the value is greater than one, 1 point is awarded. It is necessary to find the ratio of evening values of low-density lipoproteins to high density lipoproteins, with a value greater than 1.75, 1 point is awarded. The level of the evening value of blood plasma malondialdehyde is estimated, with a value of more than 1.3 mcM/l, 1 point is awarded. On the Beck depression scale, the level of depression is determined, with a value of more than 20, 1 point is awarded, then the ratio of the phase of the circadian rhythm of the axillary temperature determined by cosinor analysis and the patient's age at the time of the study is determined, with a value of more than 0.25 hours/years 1 point is assigned. According to the total assessment of the number of points, the severity of light desynchronosis is determined: high - with a value of 4 to 5 points inclusive, medium - with a value of 3 points, low - with a value of 1 to 2 points inclusive.

EFFECT: invention allows determining the high, medium and low severity of light desynchronosis.

1 cl, 4 tbl, 3 ex

Description

The invention relates to medicine, namely to functional diagnostics, public health and health care, and can be used to assess the severity of light desynchronosis.

The sharp boundary between day and night that existed for most of our ancestral development has changed in industrial societies. In modern industrial civilization, a person actively manipulates the light factor. Typical consequences of such manipulations are a significant deficit of daylight and excess of night light (Roenneberg et al, 2003; Yetish et al, 2015; Dijk & Skeldon, 2015; Munch et al, 2020). The differences are especially pronounced when compared with the light regime of populations that do not use artificial light (Yetish et al, 2015; Dijk & Skeldon, 2015). An artificial decrease in the amplitude of light exposure between daytime and nighttime is expectedly unfavorable for health and may be key factors in the diseases of civilization (Gubin, 2019). Electric light provides a "modern" life in a 24-hour, 7-day (24/7) mode, where more than 90% of people use light at night, which is most pronounced when moving to arctic latitudes for work and life. Many of us spend more than 22 hours a day indoors with little or no exposure to natural daylight. As a result, many people experience a lack of daylight during the day and receive excess artificial light in the evening or at night. Therefore, it is not surprising that the relatively recent "modern" model of exposure to light has a complex effect on physiology, sleep, performance and health (Cajochen et al., 2019; Gubin et al., 2017). The conditions of the 24-hour polar night and polar day, together with improperly distributed artificial lighting throughout the day, negatively affect the work of the biological clock and health, especially in conditions of a lack of natural light in northern latitudes in winter (Borisenkov et al., 2017; Danilenko et al., 2019). Polar day is a suppressor of melatonin production and sleep deficit.

Based on the analysis of numerous studies, it was concluded that constant light conditions (both constant light and constant darkness are not optimal conditions for health. Factors that artificially reduce the amplitude of the circadian rhythm (in particular, a deficit of daylight and an excess of night light) are unfavorable for health ( review in Gubin and Kolomeichuk, 2019).

LEVEL OF TECHNOLOGY

The consequences of exposure to suboptimal lighting modes for the mental (Borisenkov et al., 2017; Danilenko et al., 2019; Walker et al., 2020) and physical (Fonken et al., 2013; Rea & Figueiro, 2014; Plano et al., 2017; Lunn et al., 2017; Okuliarova et al., 2020) health has been actively studied recently, however, the criteria for an objective assessment of the parameters of physiological manifestations of light desynchronization in humans have not been sufficiently developed. Most of the criteria are based on studies of laboratory animals, or are focused on assessing the phase parameters of the circadian rhythm (Gubin, 2019; Cederroth et al., 2019), which is laborious, since requires a round-the-clock stay of the subject in controlled laboratory conditions, or multi-day monitoring observations. However, in addition to changes in marker circadian rhythms, the physiological manifestations of desynchronosis can affect a number of other physiological parameters, in particular lipid metabolism (Fonken et al., 2013; Plano et al., 2017; Okuliarova et al., 2020; Rumanova et al., 2020; Benedito-Silva et al., 2020), the antioxidant system (Wilking et al., 2013; Milev & Reddy, 2015; Verma et al., 2019), and mood (Walker et al., 2020). The most pronounced changes occur, as a rule, not in the morning, but in the evening, or at night (Gubin, 2019). In practice, biochemical and physiological tests are not carried out at this time, or the obtained values are compared with the standards that do not take into account the time of day, and serve as a correct reference for the morning, but not evening hours.

Known methods for determining the chronotype: Ostberg test (Horne J.A. et al., 1976) and Munich test (T. Roenneberg et al., 2003), which are simple and affordable to use and do not require cost. The disadvantage of these methods is subjectivity and moderate accuracy.

A known method for analyzing the phase of melatonin production in the dark (DLMO) (Pandi-Perumal SR, 2007), which is characterized by high accuracy in the results. The disadvantage of this method is the need for special laboratory conditions and the high cost of research.

There is a known method for analyzing the phase of circadian rhythms of activity using actimetry (Vitale JA et al., 2019), which is characterized by high accuracy of the results. The disadvantages are the need for special equipment, the need for long-term (optimally 7-day) monitoring, as well as the difference between the internal phase of the circadian rhythms of activity and the circadian phenotype.

The closest analogue can be considered the analysis of the phase of the temperature rhythm (Weinert D., 2007; Gubin DG et al., 2006), which is characterized by availability, lack of significant financial costs, and high accuracy. The disadvantage of this method is the need for observations for several days; dependence on masking factors (activity level), lack of unity in the method - the point of determination, as well as the lack of information about the relationship with the parameters of the circadian phenotype (metabolism, etc.), i.e. data on the manifestations of internal desynchronosis, tk. the temperature rhythm is only a phase marker of the internal phase of the biological clock.

DISCLOSURE

The technical task is to assess from a chronobiological point of view the severity of light desynchronosis with deterioration of light signal transduction against the background of glaucoma progression.

The technical result is to determine the high, medium or low severity of light desynchronosis

To implement the method for diagnosing light desynchronosis, including a total assessment on a five-point scale, it is necessary to perform the following actions on patients over 45 years old: assess the ratio of the evening value of total blood cholesterol to the morning value, if the value is greater than one, 1 point is added, then the ratio of evening values of lipoproteins is low density to high-density lipoproteins, with a value of more than 1.75, 1 point is awarded, then the level of the evening value of malondialdehyde in blood plasma is assessed, with a value of more than 1.3 μmol / l, 1 point is awarded, then the depression level is determined on the Beck depression scale, with a value more than 20, 1 point is awarded, then the ratio of the phase of the circadian rhythm of temperature determined by cosinor analysis (Cornelissen G., 2014) and the patient's age at the time of the study is determined, with a value of more than 0.25 hours / years, 1 point is assigned.

One of the variants of the method is the morning blood sampling for research is carried out at 8 o'clock, and evening - at 20 o'clock according to table 1.

Indicator Sampling / measurement time, h Scale of the sum of points Total cholesterol evening / morning 20 and 08 1 Risk score for> 1 LDL / HDL twenty 1 Risk score at> 1.75 MDA * plasma twenty 1 Risk score at> 1.3 Circadian rhythm phase by method, hours / age According to the scheme** 1 Risk score at> 0.25 Beck Depression Scale, points 1 Risk score at> 20

* - malonic dialdehyde

** - self-measurements of axillary body temperature d 8,11,14,17,20,23 and 3 hours three days in a row. The rhythm phase is calculated by least squares approximation with a sinusoid with a period of 24 hours, expressed in hours. The value in hours is divided by the age at the time of the study.

As a result, according to the total assessment of the number of points, the degree of severity of light desynchronosis is determined:

• high - with a value from 4 to 5 points inclusive,

• average - with a value of 3 points,

• low - with a value from 1 to 2 points inclusive

This method evaluates from a chronobiological point of view the manifestations of light desynchronosis with a deterioration in light signal transduction against the background of glaucoma progression (Gubin et al., 2019; Malishevskaya, 2017). Glaucoma is a disease in which the phenotypic manifestations of light desynchronosis are modulated. The mechanism is damage to retinal ganglion cells, in particular, melanopsin cells at advanced stages of the disease (Graticelli et al, 2015; Obara et al., 2016), which impairs light synchronization and causes disturbance of circadian rhythms (Drouyer et al., 2008; Girardin et al., 2008; La Morgia et al., 2018; Lax et al., 2019). Evidence for this mechanism has been presented in a number of studies in recent years (Graticelli et al, 2015; Gubin et al., 2019; Oh et al., 2019).

CARRYING OUT THE INVENTION

Example 1. Patient P., male 64 years old. Measured evening (4.2) and morning (5.6) total blood cholesterol. Evening LDL index - 1.3; HDL - 1.2. Evening MDA indicator - 0.9. Depression assessment on the Beck scale - 13. The calculated phase of the circadian rhythm of temperature - 14 hours.

Indicator Value Score Total cholesterol evening / morning 0.75 0 LDL / HDL 1.08 0 Plasma MDA 0.9 0 Circadian rhythm phase by method, hours / age 0.22 0 Beck Depression Scale, points 21 one TOTAL: one

The severity of light desynchronosis is low (1 point). Specialist consultation and adjustment of the daily routine is not required.

Example 2 . Patient K., female, 68 years old. Measured evening (6.7) and morning (7.6) total blood cholesterol. Evening LDL index - 1.4; HDL - 1.0. Evening MDA indicator - 2.0. Assessment of depression on the Beck scale - 29. The calculated phase of the circadian rhythm of temperature - 22 hours.

Indicator Value Score Total cholesterol evening / morning 0.88 0 LDL / HDL 1.4 0 Plasma MDA 2.0 one Circadian rhythm phase by method, hours / age 0.32 one Beck Depression Scale, points 29 one TOTAL: 3

The severity of light desynchronosis is average (3 points). It is necessary to consult a specialist with the appointment of light therapy and adjustments to the daily regimen.

Example 3 . Patient G., woman, 60 years old. Measured evening (6.9) and morning (6.5) total blood cholesterol. Evening LDL index - 1.8; HDL - 0.5. Evening MDA indicator - 1.6. Assessment of depression on the Beck scale - 21. The calculated phase of the circadian rhythm of temperature - 22 hours.

Indicator Value Score Total cholesterol evening / morning 1.06 one LDL / HDL 3.6 one Plasma MDA 1.6 one Circadian rhythm phase by method, hours / age 0.37 one Beck Depression Scale, points 21 one TOTAL: five

The severity of light desynchronosis is high (5 points). It is necessary to consult a specialist with the appointment of light therapy, adjusting the daily regimen and drug therapy with melatonin.

Several parameters reflecting changes in lipid metabolism, peroxidation, as well as the relationship of the circadian rhythm with age-related chronotypic features and mood, showed the most significant association with the loss of retinal ganglion cells by GCS in the multiple regression model (in total, 112 physiological, biochemical, derivatives were tested in the model. parametric daily dynamics and questionnaire indicators). Negative changes in these parameters were previously found in relation to unfavorable light conditions (factors of light desynchronosis - deficit of daylight / excess of night light) (Fonken et al., 2010; Obayashi et al., 2013; Fernandez et al., 2018; Gubin et al., 2017; 2019).

The method is based on a comprehensive interpretation of biochemical, physiological and test data. Using multiple correlation analysis of 42 (correlation significant) out of 112 indicators of the database of 115 patients with a diagnosis of primary open-angle form with varying degrees of glaucoma, 5 criteria with the highest correlation index were established based on the results of inverse multiple linear regression, r> 0.65 with the average value of the global index. loss of retinal ganglion cells, GCS of two eyes according to the results of optical coherence tomography at the time of the study.

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Claims (2)

1. A method for the diagnosis of light desynchronosis, including a total assessment on a five-point scale, which is characterized by the following actions on patients over 45 years old: the ratio of the evening value of the total blood cholesterol level to the morning value is estimated, if the value is greater than one, 1 point is given, then the ratio of the evening values of low lipoproteins is found density to high-density lipoproteins, with a value of more than 1.75, 1 point is awarded, then the level of the evening value of malondialdehyde in blood plasma is assessed, with a value of more than 1.3 μmol / l, 1 point is awarded, then the depression level is determined on the Beck depression scale, with a value more than 20, 1 point is awarded, then the ratio of the phase of the circadian rhythm of the axillary temperature, determined by cosinor analysis, and the patient's age at the time of the study is determined, with a value of more than 0.25 hours / years, 1 point is assigned and then, according to the total assessment of the number of points, the degree of severity of light desynchronosis: high - with a value from 4 to 5 points inclusive, medium - with a value of 3 points, low - with a value from 1 to 2 points inclusive. 2. The method according to claim 1, characterized in that the morning blood sampling for research is carried out at 8 o'clock, and the evening one - at 20 o'clock.