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Assessment of the influence of artificial lighting simulating a natural photoperiod and spectrum on the parameters of circadian rhythms of healthy volunteers
Gesztesová, Kristina ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
The alternation of light and darkness on planet Earth has led to the development of endogenous systems that operate with a period of roughly 24 hours. We refer to these systems as circadian. For optimal functioning of the human circadian system, regular synchronization by an external stimulus is required. Light is a strong stimulus for synchronization for humans, but it should be noted that the outcome of this light synchronization depends critically on a number of factors. These factors include the timing and duration of the light pulse, as well as light parameters like spectrum and intensity. Commonly used interior lighting is often not optimal for the human endogenous circadian system, which is why the alternative of so-called biodynamic lighting (lighting that adequately stimulates the human organism) is being used more lately. As part of the experiment, we verified the effect of the newly created biodynamic lighting on the parameters of the circadian rhythm of healthy volunteers. Using methods of melatonin profile analysis, analysis of temperature records and actigraphy, we confirmed the influence of our experimental lighting.
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Physical and mental performance of morning and evening chronotypes in different times of day
Červená, Kateřina ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee) ; Větrovský, Tomáš (referee)
Circadian rhythmicity, which evolved in accordance with the rhythmicity of the external environment tied to the earth's rotation, governs the regular rhythms of our physiology and behavior. The central circadian clock in the suprachiasmatic nuclei of the hypothalamus controls the roughly 24-hour rhythmicity of many peripheral clocks of most cells of the body, that can be observed from the molecular to the behavioral level. The intrinsic circadian period (τ) in humans is on average slightly longer than 24 h, but may also be slightly shorter. Individuals with a short τ are referred to as morning chronotypes, whereas individuals with a long τ are referred to as evening chronotypes. However, the majority of the population belongs to the so-called intermediate chronotype. The molecular mechanism of circadian oscillations controlled by the circadian clock has been shown to be closely linked to cellular metabolism. Many physiological processes important for physical and cognitive performance are also regulated by the circadian system. The main aim of both studies was to quantify the difference in performance during morning and evening testing in subjects of a pronounced evening and morning chronotype. While the motivation for conducting Study A was practical, with the aim of identifying potential biases...
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The effect of melatonin on rhythmic ATP release from organotypic cultures of the rat SCN
Dvořáková, Barbora ; Svobodová, Irena (advisor) ; Jelínková, Dana (referee)
The rhythm of ATP accumulation is an one of examples of circadian rhythmicity which is demonstrated across the animal kingdom. It is located in the suprachiasmatic nucleus of hypothalamus, which is a centre of circadian clock and imposes rhytmicity on a whole organism. The question concering the ATP rhythm in an organotypic culture and the impact of melatonin on it has been discussing in this thesis. The synthesis of melatonin is regulated by the activity of the SCN and the hormon itself is known for its feedback on the SCN and a capability of regulating it. It has been shown that ATP rhythm is significantly inhibited under the constant control of melatonin and this inhibition is dose-dependent on a scale of 0,1-10 nM. In case of one-time applied melatonin in 4 p.m. there is no reduction in the accumulation of extracellular ATP but there is a phase shift in ATP rhythm. It has also been shown that ATP rhythm is inhibited and desynchronized under the control of tetrodotoxin which blocks an electric activity of neurons. These results show that melatonin is capable of inducing phase delay of ATP rhythm in SCN and reducing an amount of extracellular ATP, that the effect of melatonin is probably mediated by specific receptors and lastly that ATP rhythm is a result of cell-cell interaction between neurons...
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Evaluation of Biological Efficiency of Pilot Installation of Biodynamic Lighting in a Retirement Home
Halászová, Andrea ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
Many actions we observe in nature show some kind of regularity, therefore we call them rhytms. Rhytms with a period of approximately 24 hours, so called circadian rhytms, can be distinguished in many physiological processes, with the sleep-wake cycle being one of the most prominent ones. Light is the main exogenous circadian synchronizator and thanks to the circadian rhytm influence on physiological function, it's also often spoken about an influence of light on the entire organism. Nowadays, when we spend most of the day indoors under artificial light, we often suffer from a lack of natural daylight and its synchronizing potential. This is even more prominent in elderly population living in nursing homes and in other social facilities. Lately, a new type of lighting, so called biodynamic, has been introduced. Biodynamic lighting can simulate changes in natural light conditions throughout the day and therefore partially compensate for the lack of natural daylight we suffer from, and also minimize risks of the night light. In this study we aimed to test changes in the circadian system of seniors living in the Retirement Home of TGM in Beroun using questionnaires and circadian markers. We have shown a positive effect of the installed biodynamic lighting on our participants' circadian markers and...
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The effect of constant light in early development on the circadian system in the adulthood
Kubištová, Aneta ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
Long-term exposure to constant light results in desynchronization of the circadian system in an adult and is associated with reduced efficiency of many physiological functions timed to the exact time of day, or with the development of some of the so-called civilization diseases. Constant light in adults also results in deterioration of the cognitive abilities or changes in the sleep structure. The effect of night light on the health of an adult organism is studied mainly in connection with shift work or with light pollution. The question of what effect the increased level of night light has on the development of the organism, especially on the development of the nervous system and the circadian system itself, is less studied. This diploma thesis focused on the identification of the extent of changes in the expression of Per2, Nr1d1, Stat3, BDNF genes, as well as genes encoding NMDA receptor subunits and some tissue-specific genes in the retina. Our experiments were performed on adult Long-Evans rats, that spent the first 20 days of their postnatal development in low-intensity constant light. Changes in expression were determined by quantification of mRNA by RT-qPCR in the structures of the frontal and parietal cortex, olfactory bulb, hippocampus, suprachiasmatic nucleus and retina. Behavioral tests...
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The effect of melatonin on rhythmic ATP release from organotypic cultures of the rat SCN
Dvořáková, Barbora ; Svobodová, Irena (advisor) ; Jelínková, Dana (referee)
The rhythm of ATP accumulation is an one of examples of circadian rhythmicity which is demonstrated across the animal kingdom. It is located in the suprachiasmatic nucleus of hypothalamus, which is a centre of circadian clock and imposes rhytmicity on a whole organism. The question concering the ATP rhythm in an organotypic culture and the impact of melatonin on it has been discussing in this thesis. The synthesis of melatonin is regulated by the activity of the SCN and the hormon itself is known for its feedback on the SCN and a capability of regulating it. It has been shown that ATP rhythm is significantly inhibited under the constant control of melatonin and this inhibition is dose-dependent on a scale of 0,1-10 nM. In case of one-time applied melatonin in 4 p.m. there is no reduction in the accumulation of extracellular ATP but there is a phase shift in ATP rhythm. It has also been shown that ATP rhythm is inhibited and desynchronized under the control of tetrodotoxin which blocks an electric activity of neurons. These results show that melatonin is capable of inducing phase delay of ATP rhythm in SCN and reducing an amount of extracellular ATP, that the effect of melatonin is probably mediated by specific receptors and lastly that ATP rhythm is a result of cell-cell interaction between neurons...
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The modulation of the circadian rhythm in melatonin production in human induced by experimental lighting conditions
Skálová, Kateřina ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
The circadian system controls the timing of most of the physiological functions and behaviour within approximately 24 hours period. The light/dark cycle aligns this circadian period with the exact length of the solar day. Light information is conveyed via ipRGC cells in the retina, with maximum sensitivity in the blue part light (460-480nm wavelength). The information proceeds to the main circadian clocks located in the suprachiasmatic nuclei. This clock regulates the synthesis of neurohormone melatonin in the pineal gland whose high night level can be rapidly downregulated by the light at night. The major aim of this study was to test the effectiveness of the blue or green light-emitting device, potentially utilized in clinical practice, to suppress the night melatonin level and provide thus the first evidence that this device may affect the circadian system. The results show that the light emitted by this device has the potential to lower melatonin levels in most subjects with the higher efficiency in the blue range. Key words: circadian rhythms, melatonin, light pulse, eyelids, blue and green light
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Circadian system and it's changes in Lurcher mutant mice
Boubín, Josef ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
The main topic of this thesis are changes in Circadian rhythms caused by cerebellar disorders. Mice with Lurcher mutation, which have specifically degenerated Purkinje cells layer, were choosen as animal model. Our results show that mutation of the glutamate receptor GluRδ2, which causes gradual degeneration of Purkinje cells, leads to damage of Circadian system. Mice with this mutation have reduced capability to adapt to external conditions in different light modes. They are also showing increased variability in endogenous cycle. The mice are also unable to show anticipatory behavior in time-restricted feeding. Compared to control group, affected mice do not show significant rhythm in levels of protein of Bmal1 gene in suprachiasmatic nuclei, paraventricular nuclei nor in habenula. Phosphorylated kinases ERK1/2 and GSK3ß also had distorted rhythms in suprachiasmatic nuclei. Because Circadian oscillations in locomotor activity are partly preserved, Circadian system is likely not damaged on molecular level. Cerebellar mutation hampers synchronization between suprachiasmatic nuclei of neurons and can also affect processes in the ventromedial hypothalamus regulating food intake. Our findings are the first to suggest functional interactions between cerebellum and Circadian pacemaker in suprachiasmatic...
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Changes motor functions in mouse model of cerebellar degeneration in the course of the ontogenesis
Šalomová, Martina ; Jelínková, Dana (advisor) ; Kubik-Zahorodna, Agnieszka (referee)
The cerebellum affects a number of important and complex processes in the organism. It ensures coordination, motor learning and plays an important role in cognitive and affective functions. In the case of cerebellar degeneration, we find not only the movement disorders but also behavioral abnormalities, collectively referred to as cognitive-affective syndrome. The aim of this work was to investigate motor functions during ontogenesis in animal models of hereditary cerebellar degeneration - mutant mice Lurcher and Purkinje cell degeneration using the device for quantitative gait analysis and rotarod. In addition, the effect of physical activity on the extent of ataxia and manifestations in classical behavioral tests was monitored. The results confirmed significant differences in motor skills between mutant and healthy mice; differences were also observed in some gait parameters, especially in walking speed and parameters that correlate with it. The motor functions of most groups of mice did not change during ontogenesis, pcd mice deteriorated their performance on the rotarod. The effect of physical activity was not found, with the exception of Forced swimming test. Physical activity of set intensity did not have any beneficial effect on the motoric manifestations of the mice.
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The expression and regulation of Dexras1 in the rat brain under development
Kyclerová, Hana ; Bendová, Zdeňka (advisor) ; Jelínková, Dana (referee)
The Dexras1 gene was identified after induction by glucocorticoid dexamethasone in pituitary tumor cells. Dexras1 has also been found in other brain regions and in the peripheral organs but its expression is rhythmic only in the suprachiasmatic nuclei of the hypothalamus (SCN), where the mammalian main circadian pacemaker is located. Dexras1 expression was also affected by stress, amphetamine or prenatal alcohol exposure. Its role in cells has not yet been explained. Dexras1 GTPase activity has been determined to be dependent on the NMDA receptor stimulation. Dexras1 acts as an activator of G protein signaling in cells. Its role has been detected in neuronal iron homeostasis or in the regulation of main circadian pacemaker sensitivity to photic and nonphotic synchronization cues during the day. The aim of our study was to describe the Dexras1 mRNA expression in the rat brain during ontogeny and during development after visual sensory deprivation by in situ hybridization. The earliest Dexras1 expression was detected on embryonic day 20, in the rat SCN and the ventral posteromedial thalamic nucleus. Postnatally, its expression also appeared in other sensory areas, motor thalamic areas, hypothalamic areas involved in the regulation of water homeostasis, or in limbic system. Our results further show...
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