Your search keyword '"Inesa Benediktovna Kozlovskaya"' showing total 9 results

1. EFFECT OF 5-DAY DRY IMMERSION ON EYE HYDRODYNAMICS

Author

O. M. Man’ko, Elena Tomilovskaya, Inesa Benediktovna Kozlovskaya, and A.E. Smoleevsky

Subjects

Animal science, Materials science, Immersion (virtual reality), General Medicine, General Biochemistry, Genetics and Molecular Biology

Published

2019

2. EFFECTS OF 21-DAYS DRY IMMERSION ON CHARACTERISTICS OF MOTOR UNIT’S ACTIVITY AND OF REFLEX EXCITABILITY OF CALF EXTENSOR MUSCLES

Author

Elena Tomilovskaya, Inesa Benediktovna Kozlovskaya, Oleg I. Orlov, V. V. Kitov, and Tatiana Shigueva

Subjects

Motor unit, business.industry, Anesthesia, Immersion (virtual reality), Reflex, Medicine, business

Published

2020

3. Effect of optokinetic stimulation on visual–manual tracking under the conditions of support-proprioceptive deprivation

Author

Inesa Benediktovna Kozlovskaya, A. S. Pavlova, D. O. Glukhikh, I. A. Naumov, G. A. Ekimovskiy, L. N. Kornilova, and E. V. Habarova

Subjects

030110 physiology, 0301 basic medicine, Vestibular system, Communication, medicine.medical_specialty, Proprioception, medicine.diagnostic_test, Physiology, business.industry, Eye movement, Electrooculography, Stimulus (physiology), Audiology, 03 medical and health sciences, 0302 clinical medicine, Physiology (medical), Immersion (virtual reality), Reflex, medicine, Sensory deprivation, business, Psychology, 030217 neurology & neurosurgery

Abstract

The effects of additional dynamic visual stimuli (retinal optokinetic stimulation (ROKS)) on the visual–manual tracking (VMT) indicators in the absence of support afferentation and with a reduced level of proprioceptive afferentation were determined using a model of horizontal “dry” immersion. The accuracy of the VMT of jerky and smooth (linear, pendular, and circular) movements represented by visual dot stimuli was evaluated in all 18 participants aged 19–31 before, during and after their exposure to a five- to seven-day immersion bath. The eye movements were recorded by electrooculography, while the hand movements were recorded by a joystick with a biological visual feedback (the current angle of the joystick handle was imaged on the screen). Computerized visual stimulation tests were presented, through virtual reality glasses, to subjects in the absence and against the background ROKS. We analyzed the temporal and the amplitude- and velocity-related visual and manual tracking (VT and MT) characteristics, including the efficiency (e) and gain (g) coefficients as the ratios between the amplitudes and velocities of eye/hand movements and the amplitude of stimulus movements. The efficiency and gain coefficients of both VT and MT without ROKS were significantly decreased against the baseline during the entire period including three days of immersion and 3 post-immersion days. The most pronounced worsening was observed in the VT parameters. Whereas the VT and MT parameters remained unchanged against the threshold ROKS before the immersion, they were improved during and after the immersion (the improvement was significant on the fifth to seventh day of immersion and on the thirdthird post-immersion day, compared to the test indicators on the clean screen). The most pronounced impact of ROKS was observed in the VT parameters. The vestibular function (VF) was evaluated by videooculography before and after immersion. We analyzed the static torsional otolith-cervicalocular reflex (OCOR), dynamic vestibular-cervical-ocular reactions (VCOR), vestibular reactivity (VR), and spontaneous eye movements (SpEM). A significant decrease in OCOR (gOCOR was 0.1, compared to the background gOCOR value of 0.25) was detected alongside a simultaneous significant increase in the VCOR/VR parameters in 28% of subjects on day R + 1 after immersion. Correlational has been found between the parameters of VT and MT, as well as between those of VF and VT, but no correlation has been found between the VF and MT characteristics. The results have shown that the removal of support afferentation and the minimization of proprioceptive afferentation more affected the accuracy of VT rather than that of MT. The correlational links between the studied parameters against the background of ROKS were not only preserved, but also intensified. The obtained results confirm the development of sensory deprivation (and afferent deficit) under the exposure to an immersion bath and indicate the approach to correcting the sensory deprivation through additional ROKS.

Published

2016

4. Resting State Brain Activity During Long-Term Dry Immersion

Author

Elena Tomilovskaya, Inesa Benediktovna Kozlovskaya, and I.E. Lazarev

Subjects

Adult, Male, Supine position, Brain activity and meditation, Rest, Electroencephalography, Spaceflight, 01 natural sciences, law.invention, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Animal science, law, 0103 physical sciences, Immersion (virtual reality), Hum, medicine, Humans, 010303 astronomy & astrophysics, Weightlessness Simulation, medicine.diagnostic_test, Resting state fMRI, business.industry, Brain, General Medicine, Brain Waves, Simulated microgravity, business, 030217 neurology & neurosurgery

Abstract

BACKGROUND The purpose of this work was to investigate the brain's rhythmic activity during a simulated microgravity condition (namely dry immersion). METHODS During dry immersion, which lasted for 5 d, nine subjects (healthy men, 20 to 29 yr of age) were individually placed in a tub (2.2 × 1.1 × 0.85 m) filled with water (temperature was kept constant at about 33°C). Subject floated in the tub without bodily support in the supine horizontal position, but isolated from the water by waterproof material. Resting state EEGs were registered at the fourth or fifth day of dry immersion. Under the control conditions, resting state EEGs were registered while subjects laid in a supine position on a couch. RESULTS Compared to the control condition, EEG power in the alpha range (8-13 Hz) was greater in dry immersion; this effect was distributed across the whole scalp. No effects of dry immersion were found for the beta, delta, or theta frequency bands. CONCLUSION The results of the study, similar to those obtained in a real spaceflight, indicate that support withdrawal is an important contributor to brain activity alterations in weightlessness.Lazarev IE, Tomilovskaya ES, Kozlovskaya IB. Resting state brain activity during long-term dry immersion. Aerosp Med Hum Perform. 2018; 89(7):642-647.

Published

2018

5. Effects of mechanical stimulation of sole support zones on the H-reflex characteristics under conditions of support unloading

Author

Inesa Benediktovna Kozlovskaya, A. Z. Zakirova, Tatiana Shigueva, and Elena Tomilovskaya

Subjects

medicine.medical_specialty, Physiology, Chemistry, Test group, Physiology (medical), Immersion (virtual reality), medicine, Stimulation, Human physiology, H-reflex, Biomedical engineering, Surgery

Abstract

The effects of mechanical stimulation of the sole support zones on the state of the m. soleus moto-neuron pool in humans have been studied under 7-day support unloading conditions, which were simulated using a dry immersion (DI) model. The excitability of the m. soleus motoneuron pool was estimated by the H-reflex amplitude normalized by the maximal M-wave amplitude before, during, and after immersion exposure. The results were compared for two groups of volunteers, i.e. a control group, which was subjected only to immersion exposure, and a test group, in which mechanical stimulation in locomotion regimens was applied daily during DI. The relative H-reflex amplitude increased during immersion in the control group, whereas such alterations were not detected in the test group.

Published

2015

6. Fundamental and applied objectives of investigation in dry immersion

Author

Inesa Benediktovna Kozlovskaya

Subjects

medicine.medical_specialty, Physiology, Chemistry, medicine.medical_treatment, High intensity, Muscular system, Bed rest, Physical medicine and rehabilitation, Hypokinesia, Deconditioning, Physiology (medical), Motor system, medicine, Immersion (virtual reality), Hypogravity, medicine.symptom

Abstract

The results of extended comparative research in the effect of hypogravity on the motor system in space flights and ground-based experiments have shown that “dry” immersion (DI) is the most adequate model of microgravity—the time of development, and the volume and depth of structural and functional motor disorders in DI are very close to what is observed in real microgravity. The high intensity and speed of development of hypogravity effects during immersion hypokinesia in comparison with bed rest hypokinesia, differing from DI only by the level of support deafferentation, promoted an insight into the leading (triggering) role of support lessness in the genesis of microgravity-induced syndromes of muscular deconditioning and hypogravitational ataxia. The involvement and pathways of support afferentation within the muscular system were experimentally studied and verified. The mechanisms of the development of changes in the activity of the system mechanisms remain much less investigated. These issues, as well as some new approaches for the elimination of the negative effects of hypogravity, were the subjects of investigation in the program of a complex dry immersion experiment, the results of which are presented in this issue of the journal.

Published

2010

7. Visual-manual tracking and vestibular function during a seven-day dry immersion

Author

A. Yu. Mazurenko, Inesa Benediktovna Kozlovskaya, I. A. Naumov, and L. N. Kornilova

Subjects

Vestibular system, Communication, medicine.medical_specialty, Visual perception, medicine.diagnostic_test, Proprioception, Physiology, business.industry, Computer science, Electrooculography, Motor coordination, Physical medicine and rehabilitation, Physiology (medical), medicine, Immersion (virtual reality), Reflex, Eye tracking, business

Abstract

A seven-day dry immersion experiment provided the opportunity to study the effects of decreased proprioceptive tactile and support afferentations on the vestibular function and visual-manual tracking. Before and after immersion, six subjects participated in a video oculographic evaluation of the static torsion otolith-cervicoocular reflex (OCOR) in response to head tilt by 30° in the frontal plane and dynamic vestibular-cervicoocular reactions to head longitudinal rotations at 0.125 Hz. In addition, the hand-eye motor coordination of tracking a jerky (sinusoidal) or smooth (linear) movement of point targets along the horizontal or vertical lines was evaluated on the basis of the data of electrooculography and records of manipulations with the joystick during immersion. A computerized test was performed in virtual glasses displaying images of visual stimuli and hand motor acts. The computed parameters included the reaction’s latent time, amplitude, speed and time of eye and hand movements, and gains of optooculomotor reactions and manual tracking as a ratio of eye/hand to visual stimulus speed. Testing was carried out before the experiment, after 3 h of immersion, on days 3 and 6 of staying in the bath, in the initial hours after immersion and on the third day of recovery. It was shown that removal of support and minimization of proprioceptive afferentation had a profound effect on the ocular tracking rather than pursuing the visual stimulus by hand. The accuracy of manual tracking was better in comparison with the eye tracking in all subjects. This was the first observation of changes in the peripheral vestibular system in two out of six subjects, i.e., inversion of the static torsion OCOP and positional nystagmus against a background of converted reflex, which did not change the parameters of the visual-manual tracking.

Published

2010

8. Long-term dry immersion: review and prospects

Author

Elena Tomilovskaya, Inesa Benediktovna Kozlovskaya, Nastassia Navasiolava, Marc-Antoine Custaud, Claude Gharib, Guillemette Gauquelin-Koch, Irina M. Larina, Tadaaki Mano, Biologie Neurovasculaire Intégrée (BNVI), Université d'Angers (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Biologie Neurovasculaire et Mitochondriale Intégrée (BNMI), and Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université d'Angers (UA)

Subjects

Head-Down Tilt/physiology, History, Physiology, medicine.medical_treatment, [SDV]Life Sciences [q-bio], Context (language use), Bed rest, History, 21st Century, Models, Biological, Head-Down Tilt, 03 medical and health sciences, 0302 clinical medicine, Models, Physiology (medical), Immersion, Immersion (virtual reality), medicine, Humans, Orthopedics and Sports Medicine, Weightlessness Simulation/history/methods/trends, Immersion/physiopathology, Short duration, Weightlessness Simulation, 030304 developmental biology, 0303 health sciences, Petroleum engineering, Weightlessness, Public Health, Environmental and Occupational Health, General Medicine, Human physiology, History, 20th Century, Space Flight, Biological, 21st Century, Medical support, 20th Century, Environmental science, Water-Electrolyte Balance, 030217 neurology & neurosurgery, Bed Rest

Abstract

International audience; Dry immersion, which is a ground-based model of prolonged conditions of microgravity, is widely used in Russia but is less well known elsewhere. Dry immersion involves immersing the subject in thermoneutral water covered with an elastic waterproof fabric. As a result, the immersed subject, who is freely suspended in the water mass, remains dry. For a relatively short duration, the model can faithfully reproduce most physiological effects of actual microgravity, including centralization of body fluids, support unloading, and hypokinesia. Unlike bed rest, dry immersion provides a unique opportunity to study the physiological effects of the lack of a supporting structure for the body (a phenomenon we call 'supportlessness'). In this review, we attempt to provide a detailed description of dry immersion. The main sections of the paper discuss the changes induced by long-term dry immersion in the neuromuscular and sensorimotor systems, fluid-electrolyte regulation, the cardiovascular system, metabolism, blood and immunity, respiration, and thermoregulation. The long-term effects of dry immersion are compared with those of bed rest and actual space flight. The actual and potential uses of dry immersion are discussed in the context of fundamental studies and applications for medical support during space flight and terrestrial health care.

Published

2011

9. [The effects of support-proprioceptive deprivation on visual-manual tracking and vestibular function]

Author

I. A. Naumov, E. V. Habarova, L. N. Kornilova, Inesa Benediktovna Kozlovskaya, and D. O. Glukhikh

Subjects

Vestibular system, Communication, medicine.medical_specialty, medicine.diagnostic_test, Proprioception, Physiology, business.industry, Eye movement, Electrooculography, Audiology, Stimulus (physiology), Hand movements, Physiology (medical), Immersion (virtual reality), Reflex, Medicine, business

Abstract

In order to determine the effects of support and proprioceptive afferentation on the characteristics of visual-manual tracking (VMT), we used a model of weightlessness—horizontal dry immersion. Altogether 30 subjects who stayed in the immersion bath from 5 to 7 days were examined to evaluate the accuracy of the VMT in tasks to pursue the jerky (saccadically) and smooth (linear, pendular and circular) movement of a point visual stimulus. Examinations were performed before, during and after immersion using electrooculography (to record eye movements) and a joystick (to record hand movements) with a biological visual feedback—one of the two visible stimuli on the screen matched the current angle of the joystick handle. Computerized visual stimulation programs were presented to subjects using virtual-reality glasses. We analyzed the time, amplitude and velocity characteristics of the visual and manual tracking (VT and MT respectively), including the efficiency ratio (eVT and eMT) and the gain (gVT and gMT) as the respective ratios of the amplitudes and velocities of the eyes/hand movements to the stimulus movement. eVT was significantly reduced in comparison to the baseline all the time, while the subject lay in the immersion bath and until R+4 day after immersion. eMT decreased significantly only on I-1 and I-3 days of immersion. gVT significantly differed from the baseline only on I-3 and I-6 days of immersion and R+1 day after immersion. We found no significant changes in gMT. Evaluations of the vestibular function (VF) were performed before and after immersion using videooculography. We analyzed the static torsional otolith-cervical-ocular reflex (OCOR), the dynamical vestibular-cervical-ocular reactions (VCOR), spontaneous eye movements (SpEM), and the accuracy of the perception of the subjective visual vertical (SVV). After immersion, 47% of all subjects had a significant reduction of OCOR with a simultaneous significant increase of VCOR on 37% of subjects, as well as significant changes in the accuracy of the perception of the SVV, which correlated with changes in OCOR. We found a correlation between characteristics of the VT and MT and between the characteristics of the VF and VT, but we found no correlation between VF and MT. We discovered that removal of the support and minimization of the proprioceptive afferentation has a greater impact upon the accuracy of the VT than the accuracy of the MT.