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Sleep disruption and activation of cellular inflammation mediate heightened pain sensitivity: a randomized clinical trial.
Irwin, MR, Olmstead, R, Bjurstrom, MF, Finan, PH, Smith, MT
Pain. 2023;164(5):1128-1137
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Sleep disturbance is associated with elevated levels of inflammation. Experimental studies have found that even a modest amount of sleep loss activates inflammatory processes. Experimental sleep disruption also induces alterations in sleep architecture including loss of slow wave or N3 sleep and loss of rapid eye movement sleep. The aim of this study was to clarify whether changes in the amount of N3 sleep and cellular inflammation mediate thermal pain sensitivity (i.e., heat pain threshold) in response to experimental sleep disruption. This study was a secondary analysis (assessor-blind) of a randomised controlled trial. The enrolled participants were randomised to 1 of 2 groups: 2 nights of undisturbed sleep (US) and 2 nights of sleep disruption or forced awakening (FA). Participants underwent 2 consecutive nights of US (or FA), followed by a 2-week washout interval in their home environment, and then completed 2 consecutive nights of the opposing sleep condition FA (or US). Results showed that in healthy adults, experimental disruption of sleep due to the administration of FA induced a significant decrease in heat pain threshold, as compared with responses after US. Experimental manipulation of sleep with FA also led to disturbance in sleep continuity and changes in sleep architecture, including loss of N3 sleep. Moreover, in the morning after FA, there was a robust activation of cellular inflammation Authors conclude that the differential loss of N3 sleep and increases in cellular inflammation may be important drivers of pain sensitivity in response to sleep disruption.
Abstract
Sleep loss heightens pain sensitivity, but the pathways underlying this association are not known. Given that experimental sleep disruption induces increases in cellular inflammation as well as selective loss of slow wave, N3 sleep, this study examined whether these mechanisms contribute to pain sensitivity following sleep loss in healthy adults. This assessor-blinded, cross-over sleep condition, single-site, randomized clinical trial enrolled 95 healthy adults (mean [SD] age, 27.8 [6.4]; female, 44 [53.7%]). The 2 sleep conditions were 2 nights of undisturbed sleep (US) and 2 nights of sleep disruption or forced awakening (FA, 8 pseudorandomly distributed awakenings and 200 minutes wake time during the 8-hour sleep opportunity), administered in a cross-over design after 2 weeks of washout and in a random order (FA-US; US-FA). Primary outcome was heat pain threshold (hPTH). Sleep architecture was assessed by polysomnography, and morning levels of cellular inflammation were evaluated by Toll-like receptor-4 stimulated monocyte intracellular proinflammatory cytokine production. As compared with US, FA was associated with decreases in the amount of slow wave or N3 sleep ( P < 0.001), increases in Toll-like receptor-4 stimulated production of interleukin-6 and tumor necrosis factor-α ( P = 0.03), and decreases in hPTH ( P = 0.02). A comprehensive causal mediation analysis found that FA had an indirect effect on hPTH by decreases in N3 sleep and subsequent increases in inflammation (estimate=-0.15; 95% confidence interval, -0.30 to -0.03; P < 0.05) with the proportion mediated 34.9%. Differential loss of slow wave, N3 sleep, and increases in cellular inflammation are important drivers of pain sensitivity after sleep disruption.Clinical Trials Registration: NCT01794689.
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Sleep-Opt-In: A Randomized Controlled Pilot Study to Improve Sleep and Glycemic Variability in Adults With Type 1 Diabetes.
Martyn-Nemeth, P, Duffecy, J, Quinn, L, Steffen, A, Baron, K, Chapagai, S, Burke, L, Reutrakul, S
The science of diabetes self-management and care. 2023;49(1):11-22
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Insufficient sleep (insufficient total sleep time) and irregular sleep timing (variability in the occurrence of sleep within a 24-hour period) are increasingly recognized as important contributors to glycaemic control and variability in type 1 diabetes (T1D). The aims of this study were to evaluate the feasibility and acceptability of a sleep intervention (Sleep-Opt-In) targeted for adults with type 1 diabetes with short or irregular sleep and to examine the effects of Sleep-Opt-In on sleep duration and regularity, glucose indices, and patient-reported outcomes. This study was a randomised controlled parallel trial design. Participants (n=14) were randomly assigned to either the Sleep-Opt-In intervention or a Healthy Living attention control group. Results showed that: - Sleep-Opt-In was feasible and acceptable to the target population. - participants with objectively confirmed short or irregular sleep, sleep irregularity improved by 25 minutes on average, whereas sleep duration improved only negligibly (8 minutes). - the control group experienced an increase in sleep duration but no change in sleep regularity. Authors conclude that Sleep-Opt-In is feasible, acceptable, and promising for further evaluation to improve sleep duration or regularity, glucose parameters and important patient reported outcomes of diabetes distress, daytime sleepiness, fatigue and depressive mood in the T1D population.
Abstract
PURPOSE The purpose of this study was to evaluate the feasibility and acceptability of a technology-assisted behavioral sleep intervention (Sleep-Opt-In) and to examine the effects of Sleep-Opt-In on sleep duration and regularity, glucose indices, and patient-reported outcomes. Short sleep duration and irregular sleep schedules are associated with reduced glycemic control and greater glycemic variability. METHODS A randomized controlled parallel-arm pilot study was employed. Adults with type 1 diabetes (n = 14) were recruited from the Midwest and randomized 3:2 to the sleep-optimization (Sleep-Opt-In) or Healthy Living attention control group. Sleep-Opt-In was an 8-week, remotely delivered intervention consisting of digital lessons, sleep tracker, and weekly coaching phone calls by a trained sleep coach. Assessments of sleep (actigraphy), glucose (A1C, continuous glucose monitoring), and patient-reported outcomes (questionnaires for daytime sleepiness, fatigue, diabetes distress, and depressive mood) were completed at baseline and at completion of the intervention. RESULTS Sleep-Opt-In was feasible and acceptable. Those in Sleep-Opt-In with objectively confirmed short or irregular sleep demonstrated an improvement in sleep regularity (25 minutes), reduced glycemic variability (3.2%), and improved time in range (6.9%) compared to the Healthy Living attention control group. Patient-reported outcomes improved only for the Sleep-Opt-In group. Fatigue and depressive mood improved compared to the control. CONCLUSIONS Sleep-Opt-In is feasible, acceptable, and promising for further evaluation as a means to improve sleep duration or regularity in the population of people with type 1 diabetes.
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Late, but Not Early, Night Sleep Loss Compromises Neuroendocrine Appetite Regulation and the Desire for Food.
Meyhöfer, S, Chamorro, R, Hallschmid, M, Spyra, D, Klinsmann, N, Schultes, B, Lehnert, H, Meyhöfer, SM, Wilms, B
Nutrients. 2023;15(9)
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Sleep loss has become common in modern societies. In parallel, the prevalence of obesity and metabolic comorbidities, such as type 2 diabetes, are rising worldwide. The aim of this study was to investigate the impact of the specific timing of sleep loss compared to regular sleep on appetite regulation and desire for foods. This study was a randomised, balanced, crossover design on three conditions spaced at least three and at maximum five weeks apart. Fifteen healthy young male participants were included. All participants had a regular sleep–wake cycle during the last four weeks before the experiments, with a minimum of 7 hours sleep per night. Results showed that ‘late-night sleep loss’, but not ‘early-night sleep loss’, elevated ghrelin concentrations, as well as feelings of hunger and appetite, and desire for food during the subsequent morning. Leptin concentrations were not affected by acute sleep loss per se, nor timing of sleep loss. Authors conclude that their findings could be of clinical interest to healthcare practitioners working with sleep deprived individuals, regarding sleep hygiene and appropriate sleep recommendations.
Abstract
OBJECTIVE There is evidence that reduced sleep duration increases hunger, appetite, and food intake, leading to metabolic diseases, such as type 2 diabetes and obesity. However, the impact of sleep timing, irrespective of its duration and on the regulation of hunger and appetite, is less clear. We aimed to evaluate the impact of sleep loss during the late vs. early part of the night on the regulation of hunger, appetite, and desire for food. METHODS Fifteen normal-weight ([mean ± SEM] body-mass index: 23.3 ± 0.4 kg/m2) healthy men were studied in a randomized, balanced, crossover design, including two conditions of sleep loss, i.e., 4 h sleep during the first night-half ('late-night sleep loss'), 4 h sleep during the second night-half ('early-night sleep loss'), and a control condition with 8h sleep ('regular sleep'), respectively. Feelings of hunger and appetite were assessed through visual analogue scales, and plasma ghrelin and leptin were measured from blood samples taken before, during, and after night-time sleep. RESULTS Ghrelin and feelings of hunger and appetite, as well as the desire for food, were increased after 'late-night sleep loss', but not 'early-night sleep loss', whereas leptin remained unaffected by the timing of sleep loss. CONCLUSIONS Our data indicate that timing of sleep restriction modulates the effects of acute sleep loss on ghrelin and appetite regulation in healthy men. 'Late-night sleep loss' might be a risk factor for metabolic diseases, such as obesity and type 2 diabetes. Thereby, our findings highlight the metabolic relevance of chronobiological sleep timing.
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Intake of Lactiplantibacillus plantarum HEAL9 Improves Cognition in Moderately Stressed Subjects: A Randomized Controlled Study.
Önning, G, Montelius, C, Hillman, M, Larsson, N
Nutrients. 2023;15(15)
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It is thought that there is a bidirectional communication pathway between the gut microbiota and the brain, known as the gut-brain axis. Stress, anxiety and low mood and the hormones produced when experiencing these have been shown to be improved by the introduction of healthy gut microbiota through probiotic use. As such, the use of probiotics may be of benefit to mental health problems. This randomised control trial of 129 individuals with moderate stress aimed to determine the effect of one probiotic strain Lactoplantibacillus plantarum HEAL9 (LPHEAL9) on the gut-brain axis. The results showed that following supplementation for 12 weeks, cognitive function was significantly improved compared to placebo and there was an improvement in the feelings of confusion, anger, and depression. There was a trend for improved sleep for individuals given LPHEAL9, however this was not significantly better than individuals given placebo. There were no benefits to perceived stress following LPHEAL9 supplementation. It was concluded that LPHEAL9 improved cognitive function compared to placebo and this may be due to improved mood and sleep. This study could be used by healthcare professionals to specifically recommend LPHEAL9 to individuals with stress, anxiety, and low mood.
Abstract
BACKGROUND The usage of probiotics has expanded beyond the areas of gut and immune health improvement. Several studies have shown the positive impact associated between probiotics and stress, cognition, and mood; a relationship referred to as the gut-brain axis. METHOD The aim of this exploratory study was to evaluate the effect of the probiotic strain Lactiplantibacillus plantarum HEAL9 (LPHEAL9) on the gut-brain axis in subjects with moderate stress. One hundred and twenty-nine subjects aged 21-52 years completed the study, randomized to consume either LPHEAL9 (n = 65) or placebo (n = 64) for 12 weeks. RESULTS Perceived stress and awakening cortisol were significantly reduced over time in both groups. A significant improvement in four cognition tests after consumption of LPHEAL9 compared to placebo was observed (rapid information processing test, numeric working memory test, paired associated learning, and word recall, p < 0.05). There was a tendency for a significantly better improvement in the LPHEAL9 group for three mood subscales (Confusion-Bewilderment, Anger-Hostility, and Depression-Dejection) and for fewer subjects with poor sleep in the LPHEAL9 group compared to placebo (p < 0.10). CONCLUSIONS Intake of LPHEAL9 significantly improved cognitive functions compared to the placebo, potentially by ameliorating aspects of mood and sleep.
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Probiotic intervention benefits multiple neural behaviors in older adults with mild cognitive impairment.
Fei, Y, Wang, R, Lu, J, Peng, S, Yang, S, Wang, Y, Zheng, K, Li, R, Lin, L, Li, M
Geriatric nursing (New York, N.Y.). 2023;51:167-175
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Mild cognitive impairment (MCI) is an intermediate stage between the normal cognitive changes associated with aging and dementia. Recent research shows that probiotic supplementation can regulate the balance of the intestinal flora and improve self-care ability and cognition in older adults. The aim of this study was to explore the effects and the underlying mechanisms of probiotic supplementation on MCI older adults. This study was a pilot randomised controlled trial (RCT) to investigate the effects of 12 weeks of probiotic supplementation in patients with MCI. Participants were randomly assigned to the probiotic group or control group. Results demonstrated the beneficial effects of probiotic supplementation intervention on multiple neural behaviours by regulating the homeostasis of the gut microbiota in older MCI patients. Authors conclude that this study provided new insights into nutrition interventions in older MCI patients. However, further trials with larger cohorts should be conducted to confirm the effects of probiotic intervention in MCI patients and provide more clinical evidence for its preventive and therapeutic effects.
Abstract
Probiotic supplements were shown to improve cognitive function in Alzheimer's disease (AD) patients. However, it is still unclear whether this applies to older individuals with mild cognitive impairment (MCI). We aimed to explore the effects of probiotic supplementation on multiple neural behaviors in older adults with MCI. Forty-two MCI patients (age > 60 years) were randomly divided into two groups and consumed either probiotics (n=21) or placebo (n=21) for 12 weeks. Various scale scores, gut microbiota measures and serological indicators were recorded pre- and posttreatment. After 12 weeks of intervention, cognitive function and sleep quality were improved in the probiotic group compared with those in the control group, and the underlying mechanisms were associated with changes in the intestinal microbiota. In conclusion, our study demonstrated that probiotic treatment enhanced cognitive function and sleep quality in older MCI patients, thus providing important insights into the clinical prevention and treatment of MCI.
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Effect of Docosahexaenoic Acid and Eicosapentaenoic Acid Supplementation on Sleep Quality in Healthy Subjects: A Randomized, Double-Blinded, Placebo-Controlled Trial.
Yokoi-Shimizu, K, Yanagimoto, K, Hayamizu, K
Nutrients. 2022;14(19)
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Docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA) are unsaturated Omega-3 fatty acids, primarily found in fish and seafood. The fatty acids fulfil many vital roles in the body, such as creating cell membranes, supporting brain functions and being associated with many disease-protective benefits. These fatty acids also influence sleep in children and young adults, but less is known about their effect in older people. Hence, this Japanese study investigated the impact of EPA and DHA on sleep quality in people above the age of ≥ 45. 66 males and females with poor sleep participated in this randomized, placebo-controlled, double-blinded, parallel-grouped study. They either received 860 mg of combined DHA/EPA per day (576 mg DHA/284 mg EPA) or a placebo of corn oil for 12 weeks. The outcome was assessed subjectively via sleep quality and mood questionnaires, as well as objectively with a sleep scanner and blood samples. Blood samples and blood pressure where also monitored as a safety measure. Upon completion of the study there was a subjective improvement, which was backed-up by the results of the sleep scanner. This study confirmed that DHA/EPA improves sleep quality in the middle aged and older population and does so at doses lower than those administered in previous studies. The authors had set the daily minimum intake of DHA/EPA at 860 mg/day for this trial, as previous research showed no effects at lower doses. They also noted that poor responders tended to be people with pre-existing conditions or those who were pregnant. This population may require higher dosages of DHA/EPA than healthy patients. Overall, the intervention was well tolerated. Ensuring adequate DHA and EPA levels and intake could be part of nutritional strategies for sleep support.
Abstract
Docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA)-omega-3 fatty acids with various functions-influence sleep in children and young adults. However, only limited studies on their effects on sleep in middle- and old-aged adults have been reported. Therefore, we investigated the effects of DHA and EPA on sleep quality in subjects aged ≥ 45 years. We performed a randomized, placebo-controlled, double-blinded, parallel-grouped study, in which we randomly assigned 66 healthy Japanese males and females. Each individual received six 480 mg capsules containing 576 mg DHA and 284 mg EPA per day (DHA/EPA group, n = 33), or corn oil (placebo group, n = 33), for 12 weeks. Before and after the intervention, the Oguri-Shirakawa-Azumi sleep inventory MA version (OSA-MA) and the sleep state test were conducted. In the DHA/EPA group, factor III (frequent dreaming) scores among the OSA-MA scores were significantly improved compared to the placebo group. Additionally, sleep state tests revealed that sleep efficiency improved in the DHA/EPA group. To our knowledge, this study is the first to report that DHA/EPA improves sleep quality in middle- and old-aged individuals, even at doses lower than those administered in previous studies.
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Partial sleep restriction-induced changes in stress, quality of life, and lipid metabolism in relation to cold hypersensitivity: A before-and-after intervention study.
Baek, Y, Jung, K, Kim, H, Lee, S
Medicine. 2022;101(46):e31933
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Inadequate sleep has been associated with an increased risk of cardiovascular disease and has an adverse impact on quality of life (QOL), metabolism and the immune system. Furthermore, sleep is associated with the body’s thermoregulation ability, which is closely associated with distal and proximal skin temperature, as well as core body temperature. The hypothesis of this study was that the physiological and psychological changes caused by insufficient sleep will differ according to cold hypersensitivity (CH). This study was an uncontrolled, before-and-after study with 3 days of 4-hour sleep restriction (SR) as intervention. A total of 130 participants completed the study. Results showed that less-than-optimal sleep duration leads to worsened stress and QOL and reduced low-density lipoprotein cholesterol levels. These changes were significant in the CH group compared to the non-CH group. Authors conclude that their findings provide additional information for evaluating the clinical risks posed by sleep disturbances and assessing the usual sleep patterns according to CH.
Abstract
Sleep disturbances are associated with cold hypersensitivity (CH) and characterized by excessive cold sensation in specific body parts and cold thermal discomfort. This study investigated the effects of short-term sleep restriction followed by a recovery phase on subjective health status, inflammation, and lipid metabolism in different types of CH. A total of 118 healthy adults aged 35 to 44 years without sleep disturbances were enrolled. Participants underwent 4-hour sleep restrictions per day for 3 days at a hospital and then returned to their daily lives for 4 days of rest. CH was assessed using a structured questionnaire with eight characteristic symptoms. A questionnaire and blood tests were administered baseline, after sleep restriction, and follow-up to assess cortisol, lipid profiles, and self-reported stress and quality of life (QOL). Participants were divided into CH (44.1%) and non-CH (55.9%) groups. The CH group showed increased stress, impaired QOL, and decreased low-density lipoprotein-cholesterol (LDL-C) levels compared to the non-CH group after sleep restriction. The variance for QOL (effect size = 0.07), subjective stress (effect size = 0.053), and LDL-C (effect size = 0.029) among time points depended on the group. Short-term sleep restriction was associated with deterioration of subjective health and reduced lipid metabolism; such changes were more evident in the CH group. Our findings suggest the need to consider an individual's CH status to assess the clinical risk associated with insufficient sleep.
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Simultaneous comparison of helium and nitrogen expiratory "closing volumes".
Travis, DM, Green, M, Don, H
Journal of applied physiology. 1973;34(3):304-8
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Restricted sleep has been linked to obesity but the underlying mechanisms are not clear. This study aimed to assess whether restricted sleep (4.5hrs for 4 consecutive nights) alters the appetite-regulating hormones ghrelin, leptin and pancreatic polypeptide in the following 24hrs in 19 healthy, lean men (BMI 19-24.9). This randomised crossover study assessed whether those hormonal changes predicted the food intake during ad libitum feeding. The study found that Ghrelin levels were increased after sleep restriction but did not alter leptin or pancreatic polypeptide profiles. Sleep restriction was associated with an increase in calorie consumption from snacks, primarily from carbohydrates. They concluded that restricted sleep significantly increases ghrelin levels. Elevated ghrelin is associated with an increased calorie consumption which may lead to the development of obesity.