RU2319521C2 - Method for light impact upon physical and psycho-emotional state of a patient - Google Patents

Abstract

FIELD: medicine, ophthalmology.

SUBSTANCE: it is necessary to affect ocular retina with ultraviolet radiation due to applying uninterrupted ultraviolet radiation in spectral range of about 360-380 nm. Simultaneously, one should affect with impulse light radiation in spectral range of about 390-680 nm, at frequency being 0.1-1000 impulses/min. The innovation enables to decrease the intensity of optic radiation and avoid ocular lesions.

EFFECT: higher efficiency.

2 ex

Description

The invention relates to the field of physiotherapy and psychophysiology and is intended to influence the state of people, referred to in the literature as the term “desynchronosis”. Desynchronosis is called the "disorganization of the circadian system" of regulation of the rhythms of the physiological functions of the human body (2; 13, p. 40; 19, p. 12). Signs of desynchronosis: falling asleep, waking up at night, restless sleep, early waking, daytime drowsiness, appetite disorders, eating patterns, decreased performance, lethargy, irritability, mood decline, disturbance of the daily rhythm of body temperature, hormonal disturbances, as well as other phenomenological and laboratory manifestations (4; 9; 15). This condition may be associated with night work (1; 12; 17), rapid transmeridional movements (11), geographical conditions of residence and / or work (1; 6; 9; 12), as well as a number of other factors (4; 15; 19; 20). Of particular relevance is the problem of desynchronosis in medical practice (4; 12; 13; 20). The method can be used to increase the physical and mental performance of personnel in the workplace, to eliminate night drowsiness, regulate a person’s emotional state, create a subjective feeling of comfort, increase a person’s motivational stress, regulate alcohol consumption, and prevent premenstrual stress syndrome. The method makes it possible to influence the physical and psycho-emotional state of a person in other cases.

Known methods of exposure to light, based on a single-component exposure or in combination with other physiotherapeutic procedures for psychopathological symptoms (8).

The disadvantages of these methods include: the use of exposure in a limited part of the spectrum (p. No. 1766424), the effect on peripheral biological tissues (p. No. 2039580, p. No. 1697854), the indirect effect on the etiopathogenetic links of the disease process (p. No. 206357, p. No. 1827271).

A significant drawback of these methods is the therapeutic focus, which limits their use to the contingent of patients with nosologically verified diagnoses. Meanwhile, the imperfection of statistical diagnostic classifications assumes a difference in qualifying features. Thus, ICD-10 (International Classification of Diseases), unlike DSM-IV (a diagnostic system adopted in the USA), does not distinguish “seasonal affective disorder”, which is undoubtedly a clinical reality, in its independent diagnostic section (14). In addition, the disorders under consideration may not be of a painful nature at all, but rather be part of the body's adaptive reaction structure (2).

The closest biological and medical essence to the invention is a method of exposure to light in the UVA range of 360-370 nm, with an intensity of 0.04-0.3 W / m ² on the patient’s retina in order to stop psychopathological symptoms - patent RU 2134137, effective from March 11, 1998.

The implementation of the prototype method is based on the action of ultraviolet radiation in the range of 360-370 nm, on the retina, with the aim of resynchronizing the rhythm-organizing structures of the brain (10; 17, p. 65-66).

The disadvantages of the prototype method, reducing its effectiveness and limiting the scope of use are:

1. Exposure only in the spectral range of 360-370 nm.

2. Orientation to the contingent of patients with a diagnosis of seasonal affective disorder.

3. The absence of the pulsed nature of the effects of radiation, which provides the stimulation effect.

The first of these drawbacks is associated with the limited use of the spectral continuum with a very narrow zone of the long-wavelength “near” ultraviolet (UVA), which does not correspond to the theoretical recommendations “to use full-spectrum light” (8). In addition, the isolated use of long-wave ultraviolet radiation limits the radiation intensity to the declared range (0.04-0.3 W / m ² ), which does not correspond to the proportion of ultraviolet radiation in the composition of even diffused sunlight. The indicated intensity restriction was introduced taking into account the safety standards adopted by the World Health Organization (18, p. 51-95) for isolated ultraviolet radiation and undoubtedly reduces both the synchronizing and stimulating effects of exposure. At the same time, it is known that the damaging effect of isolated ultraviolet light is much higher than in the full-spectrum radiation stream (sunlight). The neutralizing effect of the optical parts of the spectrum on the ultraviolet component damaging the ocular media is also preserved in artificial light sources (16, p. 24), allowing their efficiency to be improved by approximating the ratio of intensities of individual parts of the spectrum in sunlight. The enrichment of optical radiation with long-wave ultraviolet, recreating the structure of natural sunlight, in part of the Fraunhofer lines (3, p. 21), makes it possible to reduce the intensity of optical radiation used in phototherapeutic installations, which is also capable of causing damage to ocular environments in recommended doses.

The purpose of the invention is to increase the effectiveness of light therapy, expanding the field of its functional application.

The specified goal is achieved:

- the simultaneous use of light sources emitting visible light (390-680 nm) and lamps emitting light in the range of 360-380 nm.

- the operation of the generator (s) of optical radiation (390-650 nm) in a pulsed mode, with a frequency of from 0.1 to 1000 per minute. Pulse-mode optical radiation generators can be synchronized relative to each other. Long-wave ultraviolet generators (360-380 nm) operate continuously throughout the entire session. For example, electroluminescent incandescent lamps, LDTSUF-80 and PHILLIPS-L / 73 and similar light sources, as well as sources with other principles of light emission, can be used.

The invention consists in light exposure simulating the structure of natural sunlight (spectral regions of the visible and long-wave ultraviolet) on the human retina under continuous illumination with long-wave ultraviolet radiation and pulsed illumination with optical radiation. The simultaneous use of ultraviolet and visible (optical) light allows the formation of an integral light flux that expands the functional use of the method, and various modes (pulsed and continuous) of the simultaneous exposure to these radiation make it possible to use the fundamental neurophysiological mechanism (5, p. 232-236; 7, p. 8-11; 21, pp. 232-239), providing a qualitatively new positive effect.

The method is as follows.

A person is located indoors at a distance of 1-30 meters from 4-30 evenly distributed working light sources. Various combinations of these light sources are permitted according to a specific purpose. With this arrangement, the intensity of ultraviolet radiation at the level of the external ocular environments of a person is from 0.01 to 0.1 W / m ² . Illumination - about 10-1000 lux. The pulse frequency of the optical generator is from 0.1 to 1000 per minute. The duration of the session is from 20 minutes to several hours. Accordingly, the exposure dose of ultraviolet radiation per session ranges from 50 to 10,000 J / m ² , remaining within the recommended safe level. The impact can be carried out once, in the course of 6-18 sessions, daily, or occasionally, as necessary. Examples of the method.

Example 1. Patient E-s, 32 years old, was treated on an outpatient basis. Work is associated with a constant stay in rooms with a lack of natural light. Somatically healthy. The last 3 months before treatment, he quickly got tired of his usual work, felt “overwhelmed”, constantly feeling unwell, earlier periods of daytime sleepiness and apathy appeared, there was no desire to do what he liked, or household chores. When I went on vacation, I didn’t feel rested, I assessed my condition as painful, painful, I independently turned to a psychotherapist for help. I visited 7 sessions of phototherapy in this way. Light sources: 2 "PHILLIPS" L / 73 lamps, 8 incandescent lamps of 100 W each, operating in a pulsed mode, with a frequency of 30 imp./min. The patient was located in the center of the room at a distance of 5-6 meters from light sources. The duration of the session is 30-45 minutes. At the end of the course, he noted a significant improvement in his well-being, expressed a desire to actively spend the remaining vacation.

Example 2. Patient St., 34 years old. I went to a psychotherapist complaining of regularly occurring premenstrual lability of emotions, irritability, temper, depressed mood, apathy, unwillingness to do household chores, motor inhibition, ideas of self-abasement and self-incrimination. Within 10 days I visited 5 sessions of phototherapy according to the specified method, lasting 60 minutes. Light sources: 2 "PHILLIPS" L / 73 lamps, 8 incandescent lamps of 100 W each, operating in a pulsed mode, with a frequency of 10-60 imp./min. She was surprised to note that the expected disorders were absent.

INFORMATION SOURCES

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4. Grishchenko V.I. The role of the pineal gland in the physiology of the pathology of the female reproductive system. Kharkov, 1989, 247 p.

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Psychiatry and psychopharmacotherapy. 2002, No. 4, pp. 158-160.

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20. Khananashvili M.M. Features of the course of endogenous diseases occurring with seasonal depression. In: Journal of Neurology and Psychiatry. 2000, No. 7, pp. 18-22.

21. Shapiro B.I., Karmanova I.G. The influence of rhythmic light on the neurosecretion of the supraoptic and paraventricular nuclei of the anterior hypothalamus. In the book: Neurosecretory elements and their importance in the body. M., 1964, pp. 232-239.

Claims (1)

The method of light exposure on the physical and psycho-emotional state of a person, including exposure to the retina with ultraviolet radiation, characterized in that they use continuous ultraviolet radiation in the spectral range of 360-380 nm and simultaneously act with pulsed light radiation in the spectral range of 390-680 nm, with a frequency of 0 , 1-1000 pulses per minute.