Global ETD Search

1	Studies on melatonin receptors in guinea pig platelets and melatonin actions on human leukemic megakaryoblast MEG-01 cells 游燕珍, Yau, Yin-chun, Mabel. January 2001 (has links) published_or_final_version / Physiology / Doctoral / Doctor of Philosophy Melatonin - Physiological effect. Megakaryocytes. Blood platelets. Guinea pigs - Physiology.
2	Indole rhythms, locomotor activity and the environment Allen, Andrée Elizabeth. January 1988 (has links) published_or_final_version / Chemistry / Doctoral / Doctor of Philosophy Biological rhythms. Animal locomotion. Melatonin - Physiological effect. Pineal gland - Secretions.
3	The role of melatonin in human thermoregulation and sleep / by Cameron J. van den Heuvel. Heuvel, Cameron J. van den January 1998 (has links) Bibliography: leaves 162-197. / vii, 216 leaves : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / To determine the effects of melatonin on sleepiness and body temperature under conditions that better approximated the endogenous melatonin profile. / Thesis (Ph.D.)--University of Adelaide, Dept. of Obstetrics and Gynaecology, 1998? Melatonin Physiological effect Circadian rhythms Sleep Body temperature Regulation
4	The regulation of seasonal reproductive cycles in "Antechinus" : photoperiodic and pineal correlates McAllan, B. M. (Bronwyn Marie) January 1987 (has links) (PDF) Bibliography: leaves 131-150. Antechinus flavipes Reproduction Brown antechinus Reproduction Dasyuridae Reproduction Photoperiodism Pineal gland Melatonin Physiological effect
5	The occurence and metabolism of melatonin / by A.J. Fellenberg Fellenberg, A. J. (Alan J.) January 1983 (has links) Bibliography: leaves 89-118 / viii, 118 leaves : ill ; 31 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Obstetrics and Gynaecology, 1987 612.022 19 Melatonin Physiological effect. Melatonin Synthesis. Melatonin Metabolism. Pineal gland. Circadian rhythms.
6	Metal interactions with neural substrates and their role in neurodegeneration Lack, Barbara Anne January 2003 (has links) "Life" may be characterized as a controlled stationary flow equilibrium, maintained by energy consuming chemical reactions. The physiological functioning of these life systems include at least 28 of the elements isolated on the periodic table thus far, most of which are metals. However, as with Paracelsus Principle: "The dose makes the poison", there exists a definite link between metal levels, essential and toxic, and the onset of neurodegenerative diseases. The economic costs of brain dysfunction are enormous, but this pales in comparison to the staggering emotional toll on the victims themselves and their families. In an attempt to improve the understanding of the causes of neurodegeneration, this study focuses on one potential aspect: the possible link between metals and neurotransmitter homeostasis utilising a variety of electronanalytical techniques. Adsorptive cathodic stripping voltammetry was employed to investigate the binding affinities and complex formation of melatonin and its precursor serotonin with calcium, potassium, sodium, lithium and aluminium. The results showed that all the metals studied formed complexes with both pineal indoleamines. However, the stability and affmity of the ligands toward the various metals varied greatly. The study suggests a further role for melatonin, that of metalloregulator and possible metal detoxifier in the brain, the in vivo studies which followed will further substantiate this notion. This research additionally focused on the cholinergic system, in particular acetylcholine complex formation studies with mercury, lead, cadmium, copper and zinc using the adsorptive cathodic stripping voltammetry method. The formation and characterisation of a solid mercury-acetylcholine complex lent further strength to the in situ electrochemical complex formation observed. The results showed the preference of acetylcholine for environmentally toxic heavy metals (such as Cd²⁺) over those divalent cations that occur naturally in the body. The possible metalloregulatory role melatonin played in the three brain regIOns: cerebellum, cortex and corpus striatum of male Wistar rats was studied as an in vivo extension of the earlier in vitro studies. Anodic stripping voltammetry was employed to detect metal levels present. The results showed that daily injections of melatonin was responsible for significantly decreasing copper(I), cadmium(II) and lead(II) levels in various regions of the rat brain of those animals that had undergone a pinealectomy in comparison to the saline injected group having undergone the same treatment. Histological and electrochemical stripping techniques were applied to investigate the implications of high A1³⁺ levels in the brain regions, particularly the hippocampus. Melatonin showed signs of promise in indirect symptom alleviation and by significantly decreasing A1³⁺ levels in rats that had been dosed with melatonin prior to A1³⁺ treatments in comparison with the control groups. Finally a preliminary study outlining a method for the production of a calcium selective microelectrode was undertaken. Further work is still needed to optimise the microelectrode production as well as its possible applications. However, whilst the overall conclusions of this entire multidisciplinary study may indeed only be in effect one piece of a very large puzzle on neurodegenerative diseases, this piece will no doubt serve as a building block for further ideas and work in this field. Nervous system -- Degeneration Neurotoxicology Chemical reactions Metals -- Physiological effect Melatonin -- Physiological effect
7	Seasonal and Sex Differences in the Effects of Melatonin on Brain Arginine Vasotocin in Green Treefrogs (Hyla cinerea): Relationship to Melatonin Receptor 1a Howard, Christina Marie 30 May 2014 (has links) Critical life history events such as breeding, migration and hibernation must take place in the correct environmental context to minimize deleterious consequences on survival and reproductive fitness. Neuroendocrine mechanisms synchronizing internal physiological states with extrinsic environmental cues are vital to timing life history events appropriately. Secretion of the pineal hormone melatonin is sensitive to light and temperature cues, which provides a physiological indicator of time of day and time of year for organisms. Melatonin influences seasonal reproduction in a variety of vertebrates, likely by altering the synthesis and/or release of reproductive neuropeptides in the brain. The neuropeptides arginine vasotocin and its mammalian homologue, arginine vasopressin, are well-known modulators of reproductive and sociosexual behavior across vertebrate taxa, and are likely targets of melatonin in the context of seasonal reproduction. There is extensive evidence that vasotocin/vasopressin innervation in the brain is subject to seasonal variation, and that this variation is frequently sexually dimorphic. However, evidence that melatonin directly modulates this important neuropeptide system is lacking. Melatonin receptor 1a (MT1 in mammals) may be responsible for mediating melatonin's influence on brain vasotocin, as it is known to regulate seasonal reproduction in a variety of vertebrates. In the present study, I asked whether melatonin influences brain vasotocin in male green treefrogs (Hyla cinerea), and compared the distribution of melatonin receptor 1a in the brain of green treefrogs between sexes and seasons. Adult male and female green treefrogs were collected from field sites in Louisiana during the summer breeding season. Summer animals were acclimated to lab conditions for 3 weeks, then euthanized and their brains collected. Winter animals were maintained in the lab for four months under incrementally changing photo-, thermo-, and hygroperiod regimes that mimicked the transition to winter in their natural habitat, followed by euthanasia and brain collection. A subset of winter males (Experiment 1) were implanted with melatonin-filled or blank silastic capsules for a period of one month prior to euthanasia and brain collection. Brains of these males were processed for vasotocin immunohistochemistry. I quantified AVT-ir cell number in Experiment 1 males in the nucleus accumbens (NAcc), amygdala and caudal striatum (AMG), preoptic area (POA), suprachaismatic nucleus (SCN), and ventral hypothalamus (VH). Melatonin did not influence brain vasotocin-ir cell number in any brain region. Brains from untreated summer and winter males and females were collected and processed for MT1 immunohistochemistry. MT1-ir cells were quantified in the NAcc, striatum (STR), AMG, POA, SCN, and VH. In all regions quantified, reproductively active males had significantly more MT1-ir cells than nonreproductive males. Within the summer breeding season, males had significantly more MT1-ir cells in the NAcc than did reproductively active females. In all other regions there was no significant difference in MT1-ir cell number between reproductively active males and females. Collectively, these data suggest that melatonin modulates vasotocin via MT1. These findings assist in elucidating the neuroendocrine mechanisms by which vertebrates integrate seasonal cues with physiology to correctly time critical life history events. Melatonin -- Physiological effect Biological rhythms Green treefrog -- Seasonal variations Green treefrog -- Sex differences Neuroscience and Neurobiology
8	Effect of melatonin on myocardial susceptibility to ischaemia and reperfusion damage in a rat model of high-fat diet-induced obesity Kaskar, Rafee'ah 12 1900 (has links) Thesis (MScMedSc)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: Obesity has reached epidemic proportions worldwide and is currently a serious health problem. It is associated with metabolic abnormalities, oxidative stress, hypertension, insulin resistance and an increased disposition for the development of cardiovascular disease. Elucidation of the pathophysiological mechanisms underlying obesity and its relationship with metabolic and cardiovascular diseases is essential for prevention and management of these disorders. Melatonin, the pineal gland hormone, is a powerful antioxidant and has been shown to protect the myocardium against ischaemia/reperfusion (I/R) injury. Long- as well as shortterm melatonin treatment also reversed several of the harmful effects of obesity in an animal model of hyperphagia-induced obesity (DIO). However, its effects on myocardial I/R injury and intracellular signalling in obesity induced by a high fat diet (HFD) are still unknown. Aims of study: (i) To evaluate the ability of a high fat diet (HFD) to induce obesity in rats. Apart from evaluating its effects on the biometric parameters and resistance to ischaemia/reperfusion injury (as indicated by infarct size in regional ischaemia and functional recovery after global ischaemia), special attention will be given on the interplay between adiponectin, AMPK, leptin, and FFA in this model. (ii) To evaluate the effect of daily oral administration of melatonin to rats on the HFD as well as their littermate controls, on the parameters listed above as well as on the development of obesity. In this study melatonin will be administered from the onset of the feeding of the high fat diet. Methods: Male Wistar rats were divided into 4 groups: (i) control rats (receiving normal rat chow) (C); (ii) control rats receiving melatonin (CM); (iii) obese rats (receiving HFD) (HFD); (iv) obese rats receiving melatonin (HM). Animals were kept on the diet for 16 weeks and melatonin treatment (10mg/kg/day, added to the drinking water) started at the onset of the feeding. Following feeding and treatment, the animals were grouped into fasted/ non-fasted of which biometric parameters were recorded and blood collected at the time of sacrifice for metabolic and biochemical assays. Hearts were perfused in the working mode for evaluation of myocardial function and infarct size determination after exposure to 35min regional ischaemia/60min reperfusion. For study of intracellular signaling, hearts were perfused in the working mode, subjected to 20min global ischaemia/10min reperfusion and freeze-clamped for Western blotting. Plasma leptin, adiponectin, free fatty acid, triglycerides, total cholesterol, phospholipids, conjugated dienes and thiobarbituric reactive substances (TBARS) levels were determined. Several kinases were investigated including, the RISK (reperfusion injury salvage kinase) (PKB/Akt and ERK p44/42) and SAFE (survivor activating factor enhancement) (STAT-3) pathways, AMPK and JNK under baseline conditions or following 10 min reperfusion. In addition, expression of UCP-3 and PGC1-α was determined. Results: Significant increases in body weight, visceral fat, blood glucose, insulin, HOMA index and leptin and a reduction in adiponectin levels were observed in the fasted high fat diet (HFD) group when compared with controls (C). Significant increases in free fatty acid and triglyceride levels were also noted the HFD group while other serum lipid parameters, including TBARS, remained unchanged. No differences in functional recovery during reperfusion or infarct size after exposure to 35 min regional ischaemia, as well as functional recovery during reperfusion after 20 min global ischaemia were observed between the control and HFD groups. Baseline and 10 min reperfusion data were similar for the RISK and SAFE pathway kinases for the control vs HFD groups. The HFD also had no effect on the expression and phosphorylation of myocardial AMPK and JNK, as well as on the expression of UCP-3 and PGC1-α, when compared to the controls. Treatment with melatonin significantly reduced body weight, visceral fat, blood glucose, HOMA index and serum leptin levels in HFD treated groups, while having no effect on the lipid profile. Although melatonin significantly reduced infarct size in both control [% of area at risk: 20.59 ± 2.29 (CM) vs 38.08 ± 2.77 (C)] and high-fat diet groups [% of area at risk: 11.43 ± 2.94 (HM) vs 38.06 ± 3.59 (H)], it was without effect on myocardial functional recovery during reperfusion. Melatonin had no effect on the intracellular signaling pathways studied. Conclusions: The HFD proved to be a useful model of diet-induced obesity with a more pronounced impact on biometric and metabolic changes compared to the DIO model. Long-term melatonin treatment successfully prevented the development of metabolic abnormalities associated with the high fat diet and obesity as well as significantly reduced myocardial infarct size. The mechanisms involved in melatonin-induced cardioprotection in obesity have not been fully elucidated in this study and require further investigation. However, the anti-obesogenic and cardioprotective properties of melatonin were very significant indeed and support the suggestion of this hormone as a potential tool in the treatment of obesity and associated cardiovascular complications. / AFRIKAANSE OPSOMMING: Inleiding: Vetsug (obesiteit) het wêreldwyd epidemiese afmetings aangeneem en word tans as ‘n ‘n ernstige gesondheidsprobleem beskou. Vetsug word geassosieer met metaboliese afwykings, oksidatiewe stres, hipertensie, insulienweerstandigheid en is‘n belangrike risikofaktor vir die ontwikkeling van kardiovaskulêre siekte. Ten spyte hiervan, het onlangse studies ‘n gunstige effek van vetsug op die uitkomste van miokardiale infarksie in pasiënte gerapporteer, die sg obesiteitsparadoks. Kennis van die patofisiologiese meganismes onderliggend aan vetsug en die ontstaan van metaboliese afwykinge en hartsiekte is noodsaaklik vir die voorkoming en behandeling van hierdie toestande. Melatonien, die hormoon afgeskei deur die pineaalklier, is ‘n kragtige antioksidant en vry radikaal opruimer. Dit is voorheen aangetoon dat dit die hart teen iskemie/herperfusie (I/H) besering kan beskerm en sommige van die skadelike gevolge van vetsug in diermodelle kan omkeer. Die effek van melatonien op miokardiale I/H besering en intrasellulêre seintransduksie prosesse in vetsug geïduseer deur ‘n hoë vet dieet is egter nog onbekend. Doelstellings: (i) Die ontwikkeling en karakterisering van ‘n nuwe model van vetsug en insulienweerstandigheid geïnduseer deur 'n hoë vet dieet (HVD) en die evaluering van die effek daarvan op miokardiale I/H besering en die gepaardgaande intrasellulêre seintransduksieprosesse; (ii) Bepaling van die effek van daaglikse toediening van melatonien aan rotte op die HVD sowel as aan kontroles op ‘n standard dieet, op die ontwikkeling van dieet-geïnduseerde metaboliese veranderinge, miokardiale infarktgrootte en funksionele herstel na koronêre arterie afbinding, sowel as intrasellulêre seintransduksie. Metodiek: Vier groepe van manlike Wistar rotte is bestudeer: (i) kontrole rotte (op‘n standaard dieet) (K); (ii) kontrole rotte op ‘n standard dieet plus melatonien (KM); (iii) dieetrotte (op‘n HVD); (iv) HVD rotte wat melatonien ontvang (HM). Die HVD en melatonien (10mg/kg/dag in die drinkwater) is vir 16 weke toegedien. Na die periode van behandeling, is die diere in vastende en nie-vastende groepe verdeel, die biometriese parameters genoteer en bloedmonsters vir metaboliese en biochemiese bepalings versamel, tydens verwydering van die harte. Harte is geperfuseer volgens die werkhartmodel vir bepaling van miokardiale funksie en infarktgrootte na blootstelling aan 35min streeksiskemie. Vir evaluering van intrasellulêre seintransduksie, is geperfuseerde werkende rotharte blootgestel aan 15min globale iskemie/10 min herperfusie en gevriesklamp vir latere analises volgens die Western kladtegniek.hart. Serum leptien, adiponektien, vryvetsure, trigliseried, totale cholesterol, fosfolipiede, gekonjugeerde diene en tiobarbituursuur reaktiewe stowwe (TBARS) is bepaal. Met gebruik van Western kladtegniek, is die aktivering en/of uitdrukking van die RISK (PKB/ Akt en ERK p44/42) en SAFE (STAT-3) seintransduksiepaaie, AMPK, JNK, UCP-3 en PGC1-α, onder basislyn toestande of na 10 min herperfusie bestudeer. Resultate:‘n Beduidende toename in liggaamsgewig, visserale vet, die HOMA indeks, insulien en leptien vlakke is in die HVD groep waargeneem vergeleke met die kontrole (K) rotte. Adiponektien vlakke was laer in die HVD groep. Die HVD groep is ook gekenmerk deur ‘n beduidende styging in serum vryvetsuur en trigliseried vlakke, terwyl die ander lipied parameters, insluitende die TBARS vlakke, onveranderd was. Infarktgrootte en funksionele herstel tydens herperfusie na blootstelling aan 35 min streeksiskemie, asook funksionele herstel tydens herperfusie na 20 min globale iskemie het nie verskil tussen harte van die kontrole en HVD rotte nie. Aktivering van PKB/Akt, ERK p44/p42, STAT3, AMPK en JNK by basislyn en na 10 min herperfusie was soortgelyk in die kontrole en HFD groepe. Die HVD het ook geen effek op die uitdrukking van UCP-3 en PGC1-α in vergelyking met die kontrole gehad nie. Behandeling met melatonien het die liggaamsgewig, visserale vet, bloedglukose, HOMA indeks en serum leptien vlakke in die HVD groepe statisties beduidend verlaag, terwyl dit geen invloed op die lipiedprofiel gehad het nie. Melatonien behandeling het die miokardiale infarktgrootte beduidend en tot dieselfde mate verminder in beide kontrole [20.59 ± 2.29 (KM) vs 38.08 ± 2.77% (K)] en HVD groepe [11.43 ± 2.94 (HM) vs 38.06 ± 3.59% (HVD)]. Geen verskille is egter tussen die funksionele herstel gedurende herperfusie van die behandelde en onbehandelde kontrole en HVD groepe waargeneem nie. Melatonien het ook geen uitwerking op die intrasellulêre seintransduksiepaaie gehad nie. Gevolgtrekkings: Die resultate het getoon dat die HFD 'n goeie model van dieetgeïnduseerde vetsug en insulien weerstandigheid ontlok, met 'n meer uitgesproke impak op biometriese en metaboliese veranderinge as die voorheen gebruikte hoë-sukrose dieet. Langtermyn melatonien- behandeling het die ontwikkeling van metaboliese abnormaliteite geassosieer met die HVD, voorkom, asook miokardiale infarktgrootte na koronêre afbinding beduidend verminder. Die meganismes betrokke in melatonien-geïnduseerde miokardiale beskerming moet egter in meer detail ondersoek word. Die resultate verkry steun die voorstel dat melatonientoediening voordelig sal wees in die behandeling van vetsug en sy kardiovaskulêre komplikasies. Myocardium Ischaemia/reperfusion injury Melatonin -- Physiological effect Intracellular signalling Rats as laboratory animals Obesity -- Animal models UCTD
9	The regulation of the timing of melatonin secretion in the sheep Earl, Colin R. January 1989 (has links) (PDF) Includes bibliographical references (leaves 166-195) Addresses the nature of the central mechanisms involved in the regulation of the circadian pattern of secretion of the pineal hormone melatonin in the highly seasonal Suffolk breed of sheep. Provides new information on the behaviour of the onset and offset of melatonin secretion under different photoperiodic conditions. Ewes Australia Reproduction Suffolk sheep Effect of light on Photoperiodism Biological rhythms Molecular aspects Pineal gland Physiology Melatonin Physiological effect Hormones Secretion
10	Chronobiology of garter snakes : environmental and hormonal mechanisms mediating hibernation and reproduction Lutterschmidt, Deborah I. 12 June 2006 (has links) Graduation date: 2006 / Most vertebrates exhibit seasonality in many life history traits. Such seasonal rhythms are temporally organized via the transduction of environmental cues (e.g., photoperiod, temperature) into appropriate endocrine signals. However, among ectothermic vertebrates that undergo continuous winter dormancy, temperature is the only environmental cue available for synchronizing seasonal rhythms. Most intriguing is that in species where reproduction occurs immediately following spring emergence, the associated changes in neurophysiology and behavior that accompany reproduction likely occur during winter dormancy. The purpose of this dissertation research was to explore the mechanisms by which temperature cues affect the chronobiology and seasonal reproduction of red-sided garter snakes (Thamnophis sirtalis parietalis). Because of their roles in circadian organization and energy balance, melatonin and corticosterone are likely hormonal components of these time-keeping systems. I first characterized the interactions between melatonin and corticosterone to better understand the hormonal mechanisms facilitating temperature-induced reproduction. Melatonin and corticosterone additively inhibit reproductive behavior during the spring mating season. Experimental manipulations with a serotonin receptor antagonist suggest the mechanism underlying these effects involves a serotonin-regulated system. Although melatonin does not influence corticosterone responses to capture stress, capture stress significantly increases melatonin concentrations. To investigate the functional significance of these interactions in regulating temperature-induced reproduction, I measured body temperatures of snakes as well as circadian melatonin and corticosterone cycles during winter dormancy and spring emergence using a combination of field and laboratory experiments. Surprisingly, an increase in body temperature is not necessary for emergence from winter dormancy. Rather, critically low temperatures may serve as a zeitgeber entraining an endogenous circannual cycle that regulates emergence. Decreased environmental temperatures, in the absence of changing photoperiod cues, modulate circadian melatonin and corticosterone rhythms during hibernation. Such temperature-induced changes in hormone rhythms may facilitate seasonal reproductive behavior following spring emergence. Furthermore, a phase-shift in corticosterone rhythms during the mating season may regulate the seasonal transition between reproductive and non-reproductive states in red-sided garter snakes. Such studies investigating the environmental and hormonal mechanisms underlying time-keeping systems may provide valuable insight into the potential impact of environmental perturbations (e.g., climate change) on seasonal rhythms in physiology and behavior. Melatonin Corticosterone Circadian Stress Courtship behavior Temperature Hibernation Garter snakes Red-sided garter snake -- Reproduction Melatonin -- Physiological effect Corticosterone -- Physiological effect

Search results