RU2428957C1 - Method of diagnosing state of human visual system and correction of patient's psychophysiological state basing on detected changes - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: patient is shown successive demonstration of test-objects of three colours with sinusoidal distribution of brightness. Colour space-frequency characteristics of human visual system are measured. Curves of preservation of measured characteristics are determined with preliminary specification of values of brightness and colouration coordinates of test-object and background, measurement of colour space-frequency characteristics of human visual system and determination of curves of preservation of measured characteristics for specified coordinates of colouration, which are performed with specified time intervals of person's presence in light environment, with further regulation of spectral composition of irradiation, thus changing colouration coordinates of regulated light source, creating comfortable light environment. Simultaneously with secondary measurement of colour space-frequency characteristics of human visual system, changes of colour space-frequency characteristics of human visual system are determined, regulation of spectral composition of irradiation being carried out taking into account said person's physiological characteristics for creation of comfortable light environment and correction of psychophysiological state of person.

EFFECT: method makes it possible to increase accuracy of measurement of space-frequency characteristics of human visual system with simultaneous carrying out and taking into account person's physiological characteristics due to measurement of colour space-frequency characteristics of visual system, determination of curves of preservation of measured characteristics and regulation of spectral composition of irradiation, with creation of comfortable light environment.

7 dwg, 3 tbl, 2 ex

Description

The invention relates to medicine and can be used in psychophysiology to study and monitor the functional state of a person, in the space industry to increase the efficiency of astronauts during a long stay of astronauts at a space station. And also the invention can be used to restore human health in conjunction with traditional therapy.

A known method for diagnosing the state of the human visual system by visocontrastometry, including visual representation of test objects of three colors with a sinusoidal distribution of brightness to a person, measuring the color spatial and frequency characteristics of the human visual system, determining the safety curves of the measured characteristics (A.M. Shamshinova, A.E. Belozerov, V.M. Shapiro, E.N. Eskina, Yu.A. Arefiev, G.L. Barseghyan // Bulletin of Ophthalmology, 1997, No. 1, pp. 22-25).

In this case, the determination of the conservation curve of the color spatial-frequency characteristics consists in determining the deviation of the contrast sensitivity in the patient at the investigated spatial frequency from the value of the contrast sensitivity of a healthy person at the same spatial frequency.

The disadvantage of this method is the low accuracy of determining the contrast sensitivity, the physiological characteristics of the observer are not taken into account and, as a consequence, the decrease in the accuracy of diagnosis.

The closest in technical essence is a method for diagnosing the state of the human visual system and correcting the psychophysiological state of a person on the basis of the identified changes, in which the state of the human visual system is diagnosed by visocontrastometry, which includes visual representation of three-color test objects with a sinusoidal brightness distribution, color spatial measurement -frequency characteristics of the human visual system, determination of safety curves by measurement these characteristics and further regulation of the color of the light medium depending on them (RU 2366389 C1, A61F 9/00, 2008).

The disadvantage of this method is that it does not take into account the individual characteristics of the physiology of the observer, and, as a result, the accuracy of correction of the psychophysiological state of a person decreases. Also a very significant drawback is the bulkiness and complexity of controlling the experimental setup.

The objective of the invention is to simplify and improve the accuracy of the method for diagnosing the human visual system and correcting the psychophysiological state of a person based on the identified changes.

The technical result of the invention is to improve the accuracy of measuring the spatial-frequency characteristics of the visual system while measuring (determining) the selected physiological characteristics of a person.

To achieve a technical result in a method for diagnosing a person’s state and correcting a person’s psychophysiological state on the basis of the identified changes, including a sequential visual presentation to a person of test objects of three colors with a sinusoidal distribution of brightness, measurement of color spatial and frequency characteristics of the human visual system, determination of the safety curves of the measured characteristics, with preliminary setting of brightness values and color coordinates of the test object and background, change the color spatial-frequency characteristics of the human visual system and the determination of the safety curves of the measured characteristics for given chromaticity coordinates carried out at given intervals of a person’s stay in the light medium, followed by regulation of the spectral composition of the radiation, thereby changing the color coordinates of an adjustable light source, creating a comfortable light environment , according to the invention, at the same time as changing the color spatial-frequency characteristics of the viewer Flax human system is performed the measurement of physiological characteristics of the person, the control spectral composition of radiation is carried out based on the data of human physiological characteristics of light to create a comfortable environment and adjustments human physiological condition.

The physiological characteristics are used as an electromyogram, electric skin resistance, body temperature taken from the little finger of the right hand, pulse wave propagation time, systolic blood pressure, diastolic blood pressure, cardiac cycle duration, respiratory sinus arrhythmia, respiratory cycle duration, inspiration duration.

The essence of the invention lies in the fact that the patient, using successively presented to him test objects with a sinusoidal distribution of brightness, measure the spatial-frequency characteristics of the visual system, while measuring physiological characteristics of a person. Then, the safety curves of the measured characteristics and the type of patient response are determined, depending on which the color control of the regulated light source is carried out. Before starting measurements, brightness values and color coordinates of the test object and background are set.

The invention is illustrated by drawings, where

Figure 1 is a block diagram of an installation for implementing a method for diagnosing a human condition.

Figure 2 - color spatial-frequency characteristics of the visual system for the red test object and background at different adaptation brightnesses.

Figure 3 - color spatial-frequency characteristics of the visual system of three people for the red color of the test object and background.

Figure 4 - physiological characteristics of three people for the red color of the test object and background, and three spatial frequencies.

The flowchart of the installation for implementing the method for diagnosing a human condition comprises a chair 1 with a head lock, a monitor 2 with an image of a test object, a system unit of a personal computer 3, an adjustable light source 4, consisting of 3 types of color radiation sources and generating background radiation, an adjustment unit 5 parameters of the light source, sensors, fixing the individual physiological parameters of the patient, 6-12, analog-to-digital Converter 13.

A method for diagnosing a human condition is as follows.

To implement the method for diagnosing a person’s condition, they first calibrate the brightness and color parameters of the monitor 2 and an adjustable light source 4, on which the diagnostics will be carried out. As a result of calibration, we obtain the dependences of the brightness and color coordinates of the image displayed on the computer monitor on the relative brightness units specified by the program, since monitors of different types have different brightness and color parameters, and the difference in color and brightness coordinates depending on the voltage supplied to the adjustable lamp and the corresponding relative units of the control automatic program. By calibration set relative units of brightness and color of the background radiation and monitor the test object, produced by adjustable luminaire installation are provided: First, the brightness of 30 cd / m ^2, since it is the brightness of day adaptation of the visual system, and secondly, the chromaticity coordinates of the background radiation in the range: for green x = 0.15 ± 0.03, y = 0.67 ± 0.08, for red x = 0.60 ± 0.04, y = 0.28 ± 0.02 , for blue x = 0.18 ± 0.02, y = 0.4 ± 0.02. The adjustable lamp creates uniform illumination on the monitor 2 and the working surface.

After setting the necessary brightness parameters and chromaticity coordinates of the test object and background radiation, the color spatial-frequency characteristics of the human visual system are measured. For this, the patient is offered to sit in chair 1 in a position convenient for a long stay, fixing his head so that his eyes are perpendicular to monitor 2. Computer 3 allows diagnostic tests to simultaneously change the color of the test object and background radiation during the transition to the measurement of color spatial-frequency characteristics of the next color, as well as constantly record the individual physiological parameters of the observer. The patient observes a test object with a sinusoidal distribution of brightness against a background of a given brightness and color coordinates. After adaptation for 5 minutes to the shape and color of the test object by the method of limits, the threshold brightness of detection of the test object is determined as the arithmetic mean brightness of the appearance and disappearance of objects. To do this, the brightness of the test object is changed on the computer: the amplitude of the sinusoidal distribution of the brightness of the test object is increased (decreased) until the patient sees (sees) the test object. The brightness calculation for each given color is carried out in absolute units, translating the relative brightness units into absolute units according to the calibration results. The spatial frequency is defined as the inverse angular size of one period of the test object with a sinusoidal distribution of brightness. The received data is stored in the computer memory. During this study, the individual physiological parameters are constantly recorded in the patient using the sensors 6-12 worn on him, the signals from which are then processed in computer 3 input through an analog-to-digital converter 13.

To diagnose a person’s condition, the contrast sensitivity is measured successively in three colors — red, green, and blue — with the given chromaticity coordinates at three spatial frequencies. The spatial frequencies of the test objects are selected from the range of low (0.1-1.5 cycle / degree), medium (1.5-8 cycle / degree) and high frequencies (8-22 cycle / degree).

After carrying out measurements and calculations according to the established program, the computer calculates the color contrast sensitivity as the ratio of the brightness of the background radiation to the calculated threshold brightness of the detection of the test object, after which it builds the color spatial-frequency characteristics. Then, the safety curves of the measured visual characteristics for each color are determined, i.e. determine the deviation of the measured contrast sensitivity of the patient from the "norm" at the investigated spatial frequency. As the “norm”, color spatial-frequency characteristics are chosen, measured in healthy people with 100% vision, without revealed mental and physiological diseases. At the same time, according to the individual physiological characteristics of the observer, their type of response is determined (for example, a vegetatively stable reaction, a cardiovascular reaction, a hypertensive type of reaction, etc.), i.e. determine the direction of physiological reactions. Depending on the type obtained, weights are selected to control the chromaticity coordinates of the lighting.

Then a signal is supplied to the adjustment unit 5 of the parameters of the light source of the light medium. The magnitude of the deviation and the weight coefficient regulate the spectral composition of the radiation, changing the color coordinates of the adjustable light source 4 in order to create a comfortable light environment for a person, which leads to the alignment of his psychophysiological state, increase efficiency.

To control the light environment, pulse-width modulation of the power supply of the light source 4 is used, for example, a source using LEDs with three types of radiation sources with different color spectral characteristics (blue, green, red). For this, the duty cycle of the supply of current pulses to the radiation sources is changed, which leads to a change in the average brightness of each of the three types of color radiation sources of the light source. As a result, the chromaticity coordinates of the light source and the spectral composition of the radiation will change. This leads to a change in the color contrast sensitivity of the patient’s visual system, which depends on the color of the surrounding light environment. In the process of a person's stay in the light environment, due to a change in the color of the space surrounding the person, the psychophysiological state of the person is regulated. Since the entire light environment in which a person is located is regulated, the working conditions of the organ of vision are improved, and the working capacity is improved by creating a comfortable light environment.

Thus, changing the radiation flux of the source of each color that makes up the regulated light source, they achieve the spectral composition of radiation necessary to improve the psychophysiological state while maintaining the necessary lighting standards and the brightness of the medium.

Diagnostic testing is carried out every 23-24 hours a person is in a closed light environment.

Spatial-frequency characteristics necessary for diagnostics to increase the accuracy and volume of statistics are in the process of refinement. The primary characteristics for red are shown in FIG. 2. The chromaticity coordinates of the background radiation and the test were selected: red - for a brightness of 100 cd / m ² x = 0.61, y = 0.30; for brightness 25 cd / m ² x = 0.57, y = 0.30; for a brightness of 5 cd / m ² x = 0.57, y = 0.30, blue for a brightness of 100 cd / m ² x = 0.16, y = 0.38; for brightness 25 cd / m ² x = 0.17, y = 0.40; for a brightness of 5 cd / m ² x = 0.17, y = 0.40, and green for a brightness of 100 cd / m ² x = 0.12, y = 0.75; for brightness 25 cd / m ² x = 0.12, y = 0.73; for brightness 5 cd / m ² x = 0.18, y-0.59.

Example 1 illustrates the determination of the type of response of the observer and the color spatial-frequency characteristics for the adaptation brightness of 25 cd / m ² . Studies were conducted for 10 observers. Measurements were carried out for three colors of test objects. To construct the characteristics, 3 spatial frequencies were taken from the region of low (0.2 cycle / degree), medium (2 cycle / degree) and high (17 cycle / degree) spatial frequencies. Of all the observers, three were selected with the closest spatial-frequency characteristics. Two of them (operator 1 and 2) belonged to one type of response, and the third (operator 3) to the other. Figure 3 shows the spatial frequency response of the operators for red, and figure 4 shows one of the physiological parameters of the observers (heart rate) for red and three spatial frequencies. An example shows that even with close spatial-frequency characteristics, the physiological response of a person may vary depending on the type of response.

Example 2 shows the results of the study on the possibility of adjusting the color contrast sensitivity of the patient by changing the color coordinates of the light source, taking into account the individual physiological characteristics of the operator.

In a patient located in a room illuminated by an adjustable light source, the proposed spatial method measured the color spatial-frequency characteristic and determined the type of response. At sources of radiation color temperature is usually set. In this case, the chromaticity coordinates of the radiation are determined graphically, in accordance with the passport data of the radiation source. (The reference book on lighting engineering, under the editorship of Yu.B. Aizenberg, M., 1995, pp. 42, 45). The color temperature of the radiation sources was set at 6000K, 4800K, 4000K. At a given color temperature of the source 6000K, the chromaticity coordinates are x = 0.3, y = 0.33. At a source color temperature of 4800K, the source color coordinates are x = 0.35, y = 0.35. At a source color temperature of 4000K, the source color coordinates are x = 0.38, y = 0.37. For the given color coordinates of the sources, the function of preserving the color spatial-frequency characteristics of the organ of vision of three observers was determined, which were tested in the first example for a high spatial frequency of 17 cycles / deg. The data obtained as a result of the experiment are shown in Table 1. The results of the study showed that, depending on the type of response of the observer, a change in the chromaticity coordinates of the radiation source leads to various changes in the deviation of the color contrast sensitivity from the “norm”. Thus, various changes in the psychophysiological state of a person occur due to the regulation of the chromaticity coordinates of the light source, which leads to a change in the spectral composition of the radiation.

Thus, the claimed method provides an increase in the accuracy of measuring the spatial-frequency characteristics of the visual system while conducting and taking into account the physiological characteristics of a person.

A method for diagnosing a human condition may find application:

- in psychophysiology for the study and control of the functional state of a person;

- in space to increase the efficiency of astronauts during a long stay of astronauts at a space station;

- to restore human health in conjunction with traditional therapy.

По реакции на световое воздействие можно разделить зрительные и не зрительные характеристики. Зрительное воздействие вызывает возбуждение в ретикулярную формацию, которое оказывает влияние на дыхательный и сосудодвигательный центры. В обзоре Р. K. Kaiser (1984) было показано наличие физиологических человеческих реакций на цвет, таких как изменения в электроэнцефалограмме, в гальваническом ответе кожи, кровяном давлением, частоте дыхания, частоте дыхания сердечных сокращений, частоте мигания глаза и насыщения крови кислородом. Р. K. Kaiser Physiological response to color: A critical review // Color Research & Application Volume 9, Issue 1, pages 29-36, Spring 1984.

According to the reaction to light exposure, visual and non-visual characteristics can be divided. Visual impact causes excitation in the reticular formation, which affects the respiratory and vasomotor centers. A review by R. K. Kaiser (1984) showed the presence of physiological human responses to color, such as changes in the electroencephalogram, in the galvanic response of the skin, blood pressure, respiration rate, respiration rate, heart rate, eye blink rate and oxygen saturation in the blood. R. K. Kaiser Physiological response to color: A critical review // Color Research & Application Volume 9, Issue 1, pages 29-36, Spring 1984.

He visual effects of light appear at the level of tissue respiration. It is known that the nitrosyl complex of cytochrome c oxidase (cyt a32 + -NO), unlike other complexes, has photosensitivity and decomposes under the influence of visible light. Boelens, R., Rademaker, H., Pel, R „and Wever, R. (1982) EPR studies of the photodissociation reactions of cytochrome with oxidase-nitric oxide complexes, Biochim. Biophys. Acta 679, 84-94.

So, if the formation of cyt a3 2 + -NO plays a decisive role in the inhibition mechanism, then the enzyme activity and respiration should be sensitive to the presence of NO, and irradiation should remove the inhibitory effect of NO. Indeed, it turned out that visible light almost completely restores the activity of the enzyme. But this only happens in the presence of an excess of reducing agent. If the concentration of the reducing agent is low, then the oxygen consumption of cytochrome with oxidase in the light turned out to be as low as in the dark. In other words, when the reducing ability of the medium is high, the formation of cyt a3 2 + -NO is the key stage of inhibition; if the reducing ability of the medium is low, the main mechanism of inhibition is either the reduction of cytochrome components by nitric oxide or the formation of light-insensitive cyt a3 3+ complexes -NO2. Sarti, P., Giuffre, A., Forte, E., Mastronicola, D., Barone, M.C., and Brunori, M. (2000) Nitric oxide and cytochrome with oxidase: mechanisms of inhibition and NO degradation. Biochem. Biophys. Res. Commun. 274, 183-187.

Light with a wavelength of 458 nm exerts its non-visual effects on human cognitive function, body temperature and sense of time. Cajochen C, Münch M, Kobialka S, Kräuchi K, Steiner R, Oelhafen P, Orgül S, Wirz-Justice A. High sensitivity of human melatonin, alertness, thermoregulation, and heart rate to short wavelength light. J Clin Endocrinol Metab. 2005 Mar; 90 (3): 1311-6. Epub 2004 Dec 7.

Green and blue phototherapy reduced bilirubin in newborns. Myara A, Sender A, Valette V, Rostoker C, Paumier D, Capoulade C, Loridon F, Bouillie J, Milliez J, Brossard Y, Trivin F 1997 Early changes in cutaneous bilirubin and serum bilirubin isomers during intensive phototherapy of jaundiced neonates with blue and green light. Biol Neonate 71: 75-82.

Phototherapy was considered safe and effective for treating jaundice in newborns and protecting against bilirubin-related impairment of nervous system development (Maisels MJ, Watchko JF 2003 Treatment of jaundice in low birthweight infants. Arch Dis Child Fetal Neonatal Ed 88: F459-F463). However, phototherapy in infants with extremely low birth weight (weight ≤1500 g) was effective for the treatment of jaundice, but in infants a question weighing 501-750 g raised the question of the safety of phototherapy. So, since premature babies have imperfect antioxidant protection and are easily visible in their body, this can contribute to the development of harmful photochemical reactions in them. Morris BH, Oh W, Tyson JE, Stevenson DK, Phelps DL, O'Shea TM, McDavid GE, Perritt RL, Van Meurs KP, Vohr BR, Grisby C, Yao Q, Pedroza C, Das A, Poole WK, Carlo WA , Duara S, Laptook AR, Salhab WA, Shankaran S, Poindexter BB, Fanaroff AA, Walsh MC, Rasmussen MR, Stoll BJ, Gotten CM, Donovan EF, Ehrenkranz RA, Guillet R, Higgins RD 2008, Aggressive vs. conservative phototherapy for infants with extremely low birth weight. N Engl J Med 359: 1885-1896).

Oddly enough, light, reducing bilirubin levels, reduces the possibility of endogenous protection against lipid peroxidation. (Vreman HJ, Wong RJ, Stevenson DK 2004, Phototherapy: current methods and future directions. Semin Perinatol 28: 326-333), (Gopinathan V, Miller NJ, Milner AD, Rice-Evans CA 1994, Bilirubin and ascorbate antioxidant activity in neonatal plasma. FEBS Lett 349: 197-200).

Light can cause acute physiological responses and a state of anxiety in people, the magnitude of these reactions depends on the choice of time, intensity, and duration of light exposure. The two-hour exposure to monochromatic light with a wavelength of 460 nm in the late evening caused a significantly greater suppression of melatonin than light with a wavelength of 550 nm. The suppression of melatonin was accompanied by a concomitant large response to the level of anxiety, increased basic body temperature and heart rate. Non-classical ophthalmic photoreceptors with a peak sensitivity of approximately 460 nm affected circadian rhythms by suppression of melatonin and phase shift of the circadian rhythm (Cajochen, C., Munch, M., Kobialka, S., Krauchi, K., Steiner, R., Oelhafen, P. , Orgul, S., Wirz-Justice, A. (2005). High sensitivity of human melatonin, alertness, thermoregulation, and heart rate to short wavelength light, J Clin Endocrinol Metab, vol. 90, p. 1311-1316).

Vreman HJ In al. (2009) showed an increase in CO secretion from the skin of Wistar rats subjected to phototherapy. They showed the release of CO as an index of peroxidation. Light from a blue LED source, even at an intensity of 100 W / cm ² / nm, was effective for photoisomerization of bilirubin and in lowering circulating levels of bilirubin. In addition, exposure to blue LEDs in the therapeutic ranges (50 W / cm ² / nm or less) was not associated with an increase in CO production. While the light from the source, giving a fluorescent blue / white light with an intensity of 70 W / cm ² / nm, caused large increases in the emission of CO. This suggests that other parts of the light spectrum, in addition to the blue part, could more penetrate the body of rat pups, including the yellow-red range, possibly causing even more oxidation. Vreman HJ; Knauer Yuri; Wong RJ; Chan Miu-Lan; Stevenson DK Dermal carbon monoxide excretion in neonatal rats during light exposure Pediatric Research: July 2009 - Volume 66 - Issue 1 - p. 66-69.

All of the above has a qualitative analysis of the reactions and requires an increase in the accuracy of phototherapy techniques both in increasing the brightness of the light exposure and in choosing the color coordinates that determine the spectral composition of the radiation, which makes it possible to regulate the light-color medium.

Claims (1)

A method for diagnosing a person’s state and correcting a person’s psychophysiological state based on the detected changes, including the sequential presentation to a person of test objects of three colors with a sinusoidal distribution of brightness, measurement of color spatial and frequency characteristics of the human visual system, determination of the safety curves of the measured characteristics, with preliminary setting of brightness values and color coordinates of the test object and background, by measuring color spatial-frequency characteristics IR of the human visual system and the determination of the safety curves of the measured characteristics for the given chromaticity coordinates, carried out at given intervals of the person’s stay in the light medium, followed by regulation of the spectral composition of the radiation, thereby changing the color coordinates of the regulated light source, creating a comfortable light environment, characterized in that simultaneously with the secondary measurement of color spatial-frequency characteristics of the human visual system, such as electro Iogram, electric skin resistance, body temperature taken from the little finger of the right hand, pulse wave transit time, systolic blood pressure, diastolic blood pressure, duration of the heart cycle, respiratory sinus arrhythmia, respiratory cycle duration, inspiration duration, and then changes in color spatially frequency characteristics of the human visual system, and the regulation of the spectral composition of radiation is carried out taking into account physiological data teristics of man to create a comfortable light environment and adjust the psychophysiological state.

Images