313 resultados para Rail Edge Stress
Resumo:
Summary: Friedreich's ataxia (FRDA), the most common autosomal recessive ataxia, is characterised by progressive ataxia with dysarthria of speech, loss of deep-tendon reflexes, impaired vibratory and proprioceptive sensations and corticospinal weakness with a Babinski's sign. Patients eventually also develop kyphoscoliosis, cardiomyopathy and diabetes mellitus. The disease is a GAA repeat disorder resulting in severely reduced levels of frataxin, with secondary increased sensitivity to oxidative stress. The anti-oxidative drug, idebenone, is effective against FRDA-associated cardiomyopathy. We provide detailed clinical, electrophysiological and biochemical data from 20 genetically confirmed FRDA patients and have analysed the relation-ship between phenotype, genotype and malondialdehyde (MDA), which is a marker of superoxide formation. We assessed the effects of idebenone biochemically by measuring blood M DA and clinically by serial measurements of the International Cooperative Ataxia Rating Scale (ICARS). The GAA repeat length influenced the age at onset (p <0.001), the severity of ataxia (p= 0.02), the presence of cardiomyopathy (p =0.04) and of low-frequency hearing loss (p = 0.009). Multilinear regression analysis showed (p = 0.006) that ICARS was dependent on the two variables of disease duration (p = 0.01) and size of the GAA expansion (p = 0.02). We found no correlation to bilateral palpebral ptosis visual impairment, diabetes mellitus or skeletal deformities, all of which appear to be signs of disease progression rather than severity. We discuss more thoroughly two underrecognised clinical findings: palpebral ptosis and GAA length-dependent low-frequency hearing loss. The average ICARS remained unchanged in 10 patients for whom follow-up on treatment was available (mean 2.9 years), whereas most patients treated with idebenone reported an improvement in dysarthria (63%), hand dexterity (.58%) and fatigue (47%) after taking the drug for several weeks or months. Oxidative stress analysis showed an unexpected increase in blood MDA levels in patients on idebenone (p = 0.04), and we discuss the putative underlying mechanism for this result, which could then explain the unique efficacy of idebenone in treating the FRDA-associated cardiomyopathy, as opposed to other antioxidative drugs. Indeed, idebenone is not only a powerful stimulator of complexes II and III of the respiratory chain, but also an inhibitor of complex I activity, then promoting superoxide formation. Our preliminary clinical observations are the first to date supporting an effect of idebenone in delaying neurological worsening. Our MDA results point to the dual effect of idebenone on oxidative stress and to the need for controlled studies to assess its potential toxicity at high doses on the one hand, and to revisit the exact mechanisms underlying the .physiopathology of Friedreich's ataxia on the other hand, while recent reports suggest non-oxidative pathophysiology of the disease.
L'influence de l'activité physique sur la réactivité au stress chez les enfants obèses et non-obèses
Les effets d'une activité physique intense sur les mesures objectives et subjectives liées au stress
Resumo:
Lorsqu'un individu est confronté à une situation stressante, une des réponses les plus saillantes est l'activation de l'axe HPA, caractérisée par le déclenchement d'un taux élevé de glucocorticoïdes dans le sang. De manière générale, cette réponse hormonale est adaptative et elle a pour but la mobilisation des ressources physiques et cognitives de l'individu pour une action spécifique (Axelrod & Reisine, 1984; Chrousos & Gold, 1992; N. M. Kaplan, 1988; McEwen, 2004). Cependant, lorsque une personne est confrontée très tôt dans son développement, et de manière répétée, à des situations de stress, cette réponse physiologique peut s'altérer, devenir inadaptée (Anand, 1993; Bremner et al., 1995; Meaney et al., 1996; Mirescu, Peters, & Gould, 2004; Plotsky & Meaney, 1993; Sapolsky, 2000) et être associée à des troubles cognitifs (McEwen & Sapolsky, 1995) et émotionnels (McEwen, 2000). A l'âge adulte, le résultat de ces altérations psychoneuroendocriniennes se traduit au cours de l'activation de l'axe HPA et elles sont visibles lors de situations de stress moins intenses (Graham, Heim, Goodman, Miller, & Nemeroff, 1999; Mirescu et al., 2004; Stam, Bruijnzeel, & Wiegant, 2000; A. Taylor, Fisk, & Glover, 2000). La dysregulation de l'axe HPA semble représenter un facteur de vulnérabilité lié à des dysfonctionnements psychiques et physiologiques chez les adultes (Heim, Ehlert, & Hellhammer, 2000; Heim & Nemeroff, 1999; Heim, Newport, Mletzko, Miller, & Hemeroff, 2008). Cependant, des facteurs de protection peuvent influencer à leur tour ces vulnérabilités. La littérature, basée sur des études translationnelles (animaux, humains), converge vers le postulat selon lequel la dimension relationnelle apportée par l'environnement est fondamentale dans le développement des vulnérabilités physiologiques et psychiques du sujet. Dans ce sens, les relations d'attachement ont été particulièrement étudiées. A l'âge adulte, par exemple, la qualité des représentations d'attachement semble influencer directement l'expression de gènes impliqués dans les réponses hormonales de stress (Biagini, Pich, Carani, Marrama, & Agnati, 1998; Caldji, Diorio, & Meaney, 2000; Dallman, 2000; De Kloet, Rosenfeld, Van Eekelen, Sutanto, & Levine, 1988; Rincon-Cortes & Sullivan, 2014; Romeo, Tang, & Sullivan, 2009; van Oers, de Kloet, Whelan, & Levine, 1998), illustrant ainsi une perspective épigénétique. Traumatismes précoces et réponses de stress, leur association avec la santé mentale, l'attachement et l'ocytocine Deux objectifs principaux définissent ce travail de doctorat. Le premier est de comprendre comment un événement à portée traumatique, qui a eu lieu pendant la période périnatale, l'enfance ou l'adolescence, peut s'inscrire au niveau physiologique (axe hypotalamico- hypophysaire-surrénalien - axe HPA), au niveau psychopathologique ou encore au niveau de la régulation émotionnelle au cours de l'âge adulte. A ce propos, nous avons évalué les réponses physiologiques (telles que le Cortisol, l'ACTH et l'ocytocine), la présence de psychopathologies (relatives à l'axe I du DSM-IV) et les réponses émotionnelles (telles que la perception au stress) au cours d'une situation de stress de nature psychosociale, induite en laboratoire. Le deuxième objectif de ce travail est de savoir si les représentations d'attachement peuvent médiatiser ces effets, chez des individus exposés à différents événements à portée traumatique. Dans ce but, trois populations ont été considérées. La première est relative à des jeunes adultes nés grands prématurés ; la deuxième, concerne des femmes adultes ayant vécu un ou plusieurs abus sexuels au cours de leur enfance ou de leur adolescence et enfin la troisième est constituée de personnes adultes qui ont survécu à une maladie grave (cancer) pendant leur enfance ou leur adolescence. Enfin, ces trois populations sont comparées à des groupes contrôle. La prise en considération de différents types de traumatismes a permis de relever : premièrement, qu'un événement à portée traumatique de nature différente, peut influencer de manière semblable les structures neuronales, par exemple l'hypocortisolémie ; deuxièmement, qu'un dysfonctionnement de l'axe HPA n'aboutit pas nécessairement à la présence de signes de souffrance mentale ; enfin, des effets protecteurs ont été mis en évidence. Ces facteurs sont sous-tendus, d'un point de vue psychologique, par les représentations d'attachement et, d'un point de vue physiologique, par la sécrétion d'ocytocjne périphérique. Traumatismes précoces et réponses de stress, leur association avec la santé mentale, l'attachement et l'ocytocine -- When an individual is faced by a stressful situation, one of the most notable responses is the activation of the HPA axis, which is characterized by a heightened level of glucocortisoids in the blood. In general, this is an adaptive hormonal response which prepares the individual both physically and cognitively for a specific action (Axelrod & Reisine, 1984; Chrousos & Gold, 1992; N. M. Kaplan, 1988; McEwen, 2004). However, should a person be confronted to stressful situations very early and repeatedly in their development, this physiologic response may be altered and become maladapted (Anand, 1993; Bremner et al., 1995; Meaney et al., 1996; Mirescu et al., 2004; Plotsky & Meaney, 1993; Sapolsky, 2000) which can be associated to emotional (McEwen, 2000) and cognitive disorders(McEwen & Sapolsky, 1995). Throughout adulthood, the result of these psychoneuroendocrine alterations affects the activation of the HPA axis and are noticeable during less intense stressful situations (Graham et al., 1999; Mirescu et al., 2004; Stam et al., 2000; A. Taylor et al., 2000). HPA axis dysregulation appears to represent a factor of vulnerability linked to psychological and physical disorders in adults (Heim, Ehlert, et al., 2000; Heim & Nemeroff, 1999; Heim, Newport, et al., 2008). Nonetheless, these vulnerabilities may be influenced by further protection factors. The literature, based on translational studies (animals and humans), suggests that relationships formed in the context of the individual's environment are fundamental in the development of their physiological and psychological vulnerabilities. Thus, attachment relationships have been particularly studied. In adulthood, for example, the quality of attachment representations appear to influence directly the expression of genes involved in the hormonal responses to stress (Biagini et al., 1998; Caldji et al., 2000; Dallman, 2000; De Kloet et al., 1988; Rincon-Cortes & Sullivan, 2014; Romeo et al., 2009; van Oers et al., 1998). With the goal to study these dimensions, two principal objectives define these doctoral study. The first is to understand how an event considered to be traumatic, which took place during early infancy, infancy, or adolescence, could influence physiology (HPA axis), psychopathology or emotional regulation during adulthood. Therefore we have evaluated the presence of psychopathologies (relative to axis I of the DSM), physiological responses (such as Cortisol, ACTH and oxytocin) and emotional responses (such as perception of stress) throughout a psychosocial stress situation, conducted in a laboratory setting. The second objective of this study is to understand if attachment representations can mediate these effects, in individuals exposed to three different types of traumatic events. Therefore, three populations have been considered. The first is young adults who were born prematurely; the second concerns adult women who have suffered sexual abuse, on one or more occasions, during their childhood or adolescence; finally the third group is constituted of people who have survived a grave childhood illness. These populations were all compared to control groups. The consideration of different types of traumatic events has demonstrated, firstly, that different events which are considered to be traumatic can similarly influence neuronal structures, for example hypocortisolism. Secondly, that an HPA axis disorder does not necessarily lead to the presence of mental signs of distress, as is the case for those born very prematurely. Finally, protective effects were demonstrated, distinctively from a psychological point of view, by attachment representations and furthermore by peripheral oxytocin secretion from a physiological perspective.
Resumo:
Training and competition in major track-and-field events, and for many team or racquet sports, often require the completion of maximal sprints in hot (>30 °C) ambient conditions. Enhanced short-term (<30 s) power output or single-sprint performance, resulting from transient heat exposure (muscle temperature rise), can be attributed to improved muscle contractility. Under heat stress, elevations in skin/core temperatures are associated with increased cardiovascular and metabolic loads in addition to decreasing voluntary muscle activation; there is also compelling evidence to suggest that large performance decrements occur when repeated-sprint exercise (consisting of brief recovery periods between sprints, usually <60 s) is performed in hot compared with cool conditions. Conversely, poorer intermittent-sprint performance (recovery periods long enough to allow near complete recovery, usually 60-300 s) in hotter conditions is solely observed when exercise induces marked hyperthermia (core temperature >39 °C). Here we also discuss strategies (heat acclimatization, precooling, hydration strategies) employed by "sprint" athletes to mitigate the negative influence of higher environmental temperatures.
