Effects of circadian rhythm phase alteration on physiological and psychological variables: Implications to pilot performance (including a partially annotated bibliography)

The effects of environmental synchronizers upon circadian rhythmic stability in man and the deleterious alterations in performance and which result from changes in this stability are points of interest in a review of selected literature published between 1972 and 1980. A total of 2,084 references relevant to pilot performance and circadian phase alteration are cited and arranged in the following categories: (1) human performance, with focus on the effects of sleep loss or disturbance and fatigue; (2) phase shift in which ground based light/dark alteration and transmeridian flight studies are discussed; (3) shiftwork; (4)internal desynchronization which includes the effect of evironmental factors on rhythmic stability, and of rhythm disturbances on sleep and psychopathology; (5) chronotherapy, the application of methods to ameliorate desynchronization symptomatology; and (6) biorythm theory, in which the birthdate based biorythm method for predicting aircraft accident susceptability is critically analyzed. Annotations are provided for most citations

Disorders of Endocrine Function After Major Head Injury

This study was instigated after the diagnosis of post-traumatic hypopituitarism in a young female under our care, who had sustained a closed head injury in a motor cycle accident (Case 1, see below). A review of the world literature revealed only 47 reported cases of post-traumatic hypopituitarism, with the majority occurring in the last 20 years (Edwards and Clark, 1986). Surprisingly, we were able to collect a further 5 cases over a relatively short period of time, suggesting that it might be a more frequent complication than is currently recognised. It is of interest that the low prevalence of clinical hypopituitarism is in contrast to the frequent finding of damage to the hypothalamus and pituitary by pathologists after fatal head injury (Daniel, Prichard 6 Treip, 1959; Ceballos, 1966; Kornblum and Fisher, 1969; Treip, 1970; Crompton, 1971; Harper et al, 1986). As little endocrine information was available a large prospective study was undertaken to investigate abnormalities in endocrine function after head injury

Corticosteroid Therapy for Brain Tumor Patients with Adrenal Insufficiency

The use of corticosteroids in cases of brain tumors has become common to reduce brain edema. However, the use can cause adrenal insufficiency (AI) if used long-term and in large doses and with rapid withdrawal. In cases of pituitary macroadenoma that has undergone surgery, AI may also occur. AI also affects the treatment of brain tumor patients. Hence, AI is an important problem in brain tumors because almost all patients with brain tumors receive corticosteroids at some point in the course of their disease. The management is similar to another AI with focus of hydrocortisone treatment. The adjustment of hydrocortisone dosage in patients whom undergo brain surgery is similar with another major surgery, whether the adjustment for pituitary adenoma patients whom undergo excision is more complicated and careful due to the high risk and incidence of AI in these patients

Optimizing Circadian Rhythm and Characterizing Brain Function in Disorders of Consciousness

Sleep is a physiological state where memory processing, learning and brain plasticity occur. Patients with prolonged disorders of consciousness (PDOC) show no or minimal signs of awareness of themselves or their environment but appear to have sleep-wake cycles. The main aim of this thesis was to investigate effect of circadian rhythm and sleep optimization on brain functions of patients with PDOC. In the first instance, sleep and circadian rhythms of patients with PDOC were investigated using polysomnography and saliva melatonin measurements. The investigations that were performed at the baseline suggested that both circadian rhythmicity and sleep were severely deranged in PDOC patients. This was followed by the interventional stage of the research where an attempt was made to optimize circadian rhythm and sleep by giving blue light, caffeine and melatonin in a small cohort of patients. To measure the effects of the intervention, we used a variety of assessments: Coma Recovery Scale-Revised (CRS-R) to measure changes in awareness; PSG for assessment of sleep, melatonin for assessment of circadian rhythm; and, event-related potential measures including mismatch negativity (MMN) and subject’s own name (SON) paradigms. Our results showed that it is possible to improve sleep and circadian rhythms of patients with PDOC, and most importantly, this improvement leads to increase in Coma Recovery Scale-Revised scores. Individually, those patients who responded well to the intervention also showed improvements in their functional brain imaging assessments

Adrenal suppression: A practical guide to the screening and management of this under-recognized complication of inhaled corticosteroid therapy

Inhaled corticosteroids (ICSs) are the most effective anti-inflammatory agents available for the treatment of asthma and represent the mainstay of therapy for most patients with the disease. Although these medications are considered safe at low-to-moderate doses, safety concerns with prolonged use of high ICS doses remain; among these concerns is the risk of adrenal suppression (AS). AS is a condition characterized by the inability to produce adequate amounts of the glucocorticoid, cortisol, which is critical during periods of physiological stress. It is a proven, yet under-recognized, complication of most forms of glucocorticoid therapy that can persist for up to 1 year after cessation of corticosteroid treatment. If left unnoticed, AS can lead to significant morbidity and even mortality. More than 60 recent cases of AS have been described in the literature and almost all cases have involved children being treated with ≥500 μg/day of fluticasone

Control mechanisms of circadian rhythms in body composition: Implications for manned spaceflight

The mechanisms underlying the internal synchronization of the circadian variations in electrolyte content in body compartments were investigated, and the significance of these oscillations for manned spaceflight were examined. The experiments were performed with a chair-acclimatized squirrel monkey system, in which the animal sits in a chair, restrained only around the waist. The following information was given: (1) experimental methodology description, (2) summary of results obtained during the first contract year, and (3) discussion of the research performed during the second contract year. This included the following topics: physiological mechanisms promoting normal circadian internal synchronization, factors precipitating internal desynchronization, pathophysiological consequences of internal desynchronization of particular relevance to spaceflight, and validation of a chair-acclimatized system

Critical roles of endogenous glucocorticoids for disease tolerance in malaria

During malaria, the hypothalamic-pituitary-adrenal (HPA) axis is activated and glucocorticoid (GC) levels are increased, but their essential roles have been largely overlooked. GCs are decisive for systemic regulation of vital processes such as immune responses, vascular function, and metabolism, which are crucial in malaria. Here, we introduce GCs in general, followed by their versatile roles for disease tolerance in malaria. A complementary comparison is provided with their role in sepsis. Finally, potential translational implications are considered. The failed clinical trials of dexamethasone against cerebral malaria in the past have diminished the interest in GCs in malaria. However, the issue of relative corticosteroid insufficiency has barely been explored in malaria patients, but may hold promise for a better understanding and treatment of specific malaria complications

Adaptation to prolonged bedrest in man: A compendium of research

A compilation of major studies that describe the clinical observations and elucidate the physiological mechanisms of the adaptive process of man undergoing prolonged bed rest is presented. Additional studies are included that provide background information in the form of reviews or summaries of the process. Wherever possible a detailed annotation is provided under the subheadings: (1) purpose, (2) procedure and methods, (3) results, and (4) conclusions. Additional references are provided in a selected bibliography

Sleep and circadian rhythms in the acute phase of moderate to severe traumatic brain injury

Les traumatismes craniocérébraux (TCC) sont la principale cause d’invalidité chez les jeunes adultes, engendrant d’importantes séquelles cognitives, physiologiques et comportementales. Les perturbations du cycle veille-sommeil sont parmi les symptômes les plus persistants à la suite d’un TCC et pourraient nuire à la récupération. En effet, le sommeil est nécessaire à l’apprentissage, la plasticité cérébrale et la génération de nouveaux neurones dans le cerveau adulte. Les observations cliniques suggèrent que ces perturbations apparaissent dès les premières semaines suivant le TCC et pourraient suggérer une altération de l’horloge circadienne. Cependant, aucune étude n’a encore documenté comment les perturbations du cycle veille-sommeil émergent et évoluent dans la phase aiguë du TCC, ni leur association à la récupération fonctionnelle et cognitive à court-terme. Conséquemment, cette thèse vise à caractériser le sommeil et les rythmes circadiens des patients hospitalisés avec un TCC modéré ou sévère et déterminer si les perturbations du cycle veille-sommeil sont causées par un dérèglement de l’horloge circadienne. Pour ce faire, nous avons utilisé des mesures objectives et quantitatives de sommeil et des rythmes circadiens, incluant l’actigraphie, la polysomnographie (PSG) et la mélatonine, dès la phase d’éveil aux soins intensif. Afin de comprendre le rôle du TCC dans ces perturbations, nous avons comparé les patients TCC à des patients hospitalisés avec blessures orthopédiques graves, sans TCC. Ce protocole a mené à cinq articles de recherche. En premier lieu, nous démontrons que le cycle veille-sommeil des patients TCC est sévèrement perturbé, mais s’améliore chez 50% d’entre eux au cours de leur séjour hospitalier. Les patients avec une amélioration de la consolidation du cycle veille-sommeil ont un meilleur fonctionnement cognitif et fonctionnel au congé de l’hôpital. Ensuite, dans une étude de cas, nous démontrons qu’un patient TCC peut avoir un cycle veille-sommeil complètement différent dans un même environnement, selon son stade de récupération. Notre troisième article confirme que la consolidation du cycle veille-sommeil évolue en synchronie avec la récupération de la conscience et des fonctions cognitives dans la phase aiguë du TCC. Notre quatrième article compare le sommeil des patients TCC à celui des blessés orthopédiques graves, sans TCC, en utilisant un système de PSG ambulatoire au chevet. Nous démontrons que, contrairement à notre hypothèse, le sommeil des patients TCC comprend tous les éléments et stades d’un sommeil normal. Cependant, ces patients s’endorment plus tôt et ont un sommeil de plus longue durée, mais plus fragmenté, que les patients sans TCC. Dans les deux groupes, le sommeil est de mauvaise qualité, reflétant probablement l’effet de facteurs non-spécifiques associés avec les blessures physiques et l’environnement hospitalier. Conséquemment, la PSG en phase aiguë permet difficilement de distinguer les patients TCC des patients sans TCC. Notre dernier article confirme que les patients avec TCC ont une consolidation du cycle veille-sommeil et une qualité de sommeil nocturne inférieures à celles des patients sans TCC, ce qui confirme le rôle du TCC dans les perturbations du cycle veille-sommeil. Cependant, malgré ces perturbations plus sévères, les patients TCC ont un rythme normal de la mélatonine et celui-ci n’est pas associé aux perturbations observées. Cet article suggère que des mécanismes neuronaux autres que l’horloge circadienne seraient responsables des perturbations du cycle veille-sommeil à la suite d’un TCC. Cette thèse est la première à évaluer le sommeil et le fonctionnement de l’horloge circadienne de patients hospitalisés avec un TCC modéré ou sévère ayant atteint la stabilité médicale. En isolant le rôle du TCC de celui du traumatisme physique et du milieu hospitalier, ces études contribuent à comprendre les caractéristiques, les conséquences et la pathophysiologie des perturbations du cycle veille-sommeil à la suite d’un TCC, ouvrant la voie à de possibles interventions visant à améliorer le sommeil et optimiser la récupération.Traumatic brain injuries (TBI) are the leading cause of disability among young adults, causing debilitating cognitive, psychological and behavioural impairments. Sleep-wake disturbances (SWD) are among the most persistent sequelae following TBI, and could impede recovery. Indeed, sleep is essential to learning, plasticity and neurogenesis. Clinical observations suggest that these disturbances arise in the first weeks following injury, and could suggest a circadian disturbance. However, no study has yet documented how SWD arise and evolve in the acute phase of TBI, or how they are associated to short-term cognitive and functional recovery. Consequently, this thesis aims to characterize the sleep and circadian rhythms of patients hospitalized with moderate or severe TBI, and determine whether SWD are caused by a deregulation of the circadian clock. To achieve this goal, we used objective and quantitative measures of sleep and circadian rhythms including actigraphy, polysomnography (PSG), and melatonin, beginning in the awakening stage in the Intensive Care Unit. In order to understand the specific role of TBI on SWD, we compared TBI patients to other hospitalized trauma patients, without TBI. Our comprehensive study protocol led to five research articles. First, we show that the sleep-wake cycle of TBI patients is severely disturbed, but improves for 50% of patients during their hospital stay. Patients whose sleep-wake cycle consolidation improves have better cognitive and functional outcome at hospital discharge. Then, in a single case study, we demonstrate how a patient can have drastically different sleep-wake patterns in the same environment, according to recovery stage. In our third research article, we show that the consolidation of sleep and wake states evolves synchronously with the recovery of consciousness and cognition in the acute phase of TBI. Our fourth article compares the sleep of TBI patients to that of non-TBI trauma patients using ambulatory PSG at bedside. Contrary to our hypothesis, TBI patients have normal sleep elements and normal proportions of each sleep stages. However, they have earlier sleep onset and longer nighttime sleep duration, but with greater fragmentation, than non-TBI patients. In both groups, sleep quality is poor, which most likely reflects non-specific factors associated with the physical trauma and hospital environment. Therefore, PSG reveals little information able to distinguish TBI patients from other non-TBI trauma patients at this stage post-injury. Our final article shows that TBI patients have poorer sleep-wake cycle consolidation and nighttime sleep quality than non-TBI patients, confirming the role of the TBI in altering sleep and wake states. However, despite having more severe SWD, TBI patients have a normal melatonin rhythm, and this rhythm is not associated with the observed SWD. This article suggests that neural mechanisms other than the circadian clock may be responsible for post-TBI SWD. This thesis is the first to investigate the sleep and circadian clock of hospitalized moderate to severe TBI patients who are medically stable. By isolating the role of the injured brain from that of overall trauma and the hospital setting, these studies contribute to understanding the characteristics, consequences and pathophysiology of post-TBI SWD, unlocking the possibility to design interventions aiming to improve sleep and optimize recovery