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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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Essential Hypertension and Oxidative Stress: Novel Future Perspectives.
Franco, C, Sciatti, E, Favero, G, Bonomini, F, Vizzardi, E, Rezzani, R
International journal of molecular sciences. 2022;23(22)
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High blood pressure is one of the main risk factors for cardiovascular disease and a significant contributor to the development of strokes, heart attacks, and heart and kidney failure leading to early disability and reduced life expectancy. Essential or primary hypotension makes up 95% of high blood pressure cases, which is abnormally elevated blood pressure that is not a result of any other medical condition. Essential hypertension arises from various factors such as diet, lifestyle, environmental and genetic influences. Despite many available medications, not all patients attain well-managed blood pressure levels. Unmanaged high blood pressure can, over time, lead to narrowing and stiffening of the blood vessels and ultimately to structural and functional changes in the blood tissues. In part, this is mediated by oxidative stress, changes in antioxidant capacity and chronic low-grade inflammation, which damage the blood vessels' endothelial tissue and result in vascular stiffness. Melatonin is one of the most potent antioxidants found in nature and has been studied in short-term trials for its blood pressure lowering, antioxidant and vascular protective effects. This small open-label randomised study sought to get a better understanding of the long-term use of melatonin. Initially, the study assessed endothelial tissue damage, oxidative status and vascular stiffness in patients with high blood pressure. Subsequently, some of the participants received a low-dose melatonin supplement (1 mg/day) for one year, whilst being monitored for clinical and structural vascular changes. The study included 23 patients and 14 in the final analysis. After one year, the results showed a significant improvement in arterial stiffness in the melatonin group (11) and an improvement in endothelial tissue function, though the latter was not at statistically significant levels. Improvement in arterial stiffness seemed to be linked to a reduction in total antioxidant capacity (TAC). These findings suggest that melatonin can contribute to restoring oxidative balance in blood plasma, which reflects improved arterial stiffness. The study also demonstrated that besides being a well-tolerated intervention, melatonin also has clinical benefits even when administered at lower doses than normal.
Abstract
Among cardiovascular diseases, hypertension is one of the main risk factors predisposing to fatal complications. Oxidative stress and chronic inflammation have been identified as potentially responsible for the development of endothelial damage and vascular stiffness, two of the primum movens of hypertension and cardiovascular diseases. Based on these data, we conducted an open-label randomized study, first, to evaluate the endothelial damage and vascular stiffness in hypertense patients; second, to test the effect of supplementation with a physiological antioxidant (melatonin 1 mg/day for 1 year) in patients with essential hypertension vs. hypertensive controls. Twenty-three patients of either gender were enrolled and randomized 1:1 in two groups (control and supplemented group). The plasmatic total antioxidant capacity (as a marker of oxidative stress), blood pressure, arterial stiffness, and peripheral endothelial function were evaluated at the beginning of the study and after 1 year in both groups. Our results showed that arterial stiffness improved significantly (p = 0.022) in supplemented patients. The endothelial function increased too, even if not significantly (p = 0.688), after 1 year of melatonin administration. Moreover, the supplemented group showed a significative reduction in TAC levels (p = 0.041) correlated with the improvement of arterial stiffness. These data suggest that melatonin may play an important role in reducing the serum levels of TAC and, consequently, in improving arterial stiffness.
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Resistance Training Improves Sleep and Anti-Inflammatory Parameters in Sarcopenic Older Adults: A Randomized Controlled Trial.
de Sá Souza, H, de Melo, CM, Piovezan, RD, Miranda, REEPC, Carneiro-Junior, MA, Silva, BM, Thomatieli-Santos, RV, Tufik, S, Poyares, D, D'Almeida, V
International journal of environmental research and public health. 2022;19(23)
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Sleep is a behavioural state that is characterised by relative immobility and reduced responsiveness and can be distinguished from coma or anaesthesia by its rapid reversibility. Sleep has a number of functions, which include metabolism modulation and the repair of organic tissue. The aim of this study was to investigate the effects of a 12-week resistance exercise training (RET) protocol on subjective and objective sleep parameters in older individuals with sarcopenia and the possible role of inflammation status in this process. This study was a randomised, placebo-controlled, parallel-group study. Participants were randomly assigned to one of the two groups; RET group or control group. Results showed that a 12-week RET protocol simultaneously improved muscle strength. In addition to the increase in overall subjective sleep quality, there was also a reduction in sleep latency, apnoea-hypopnea index, and insomnia severity, as well as an increase in deeper stage 3 sleep (slow-wave sleep) in the RET group in comparison with the CTL group. Authors conclude that future studies are necessary to elucidate how different age groups and genders, with and without sarcopenia, can present specific muscle and sleep responses to potentially anti-inflammatory interventions, such as physical exercise.
Abstract
Sleep and exercise have an important role in the development of several inflammation-related diseases, including sarcopenia. Objective: To investigate the effects of 12 weeks of resistance exercise training on sleep and inflammatory status in sarcopenic patients. Methods: A randomized controlled trial comparing resistance exercise training (RET) with a control (CTL) was conducted. Outcomes were obtained by physical tests, polysomnography, questionnaires, isokinetic/isometric dynamometry tests, and biochemical analysis. Results: Time to sleep onset (sleep latency) was reduced in the RET group compared to the CTL group (16.09 ± 15.21 vs. 29.98 ± 16.09 min; p = 0.04) after the intervention. The percentage of slow-wave sleep (N3 sleep) was increased in the RET group (0.70%, CI: 7.27−16.16 vs. −4.90%, CI: 7.06−16.70; p = 0.04) in an intention to treat analysis. Apnea/hour was reduced in the RET group (16.82 ± 14.11 vs. 7.37 ± 7.55; p = 0.001) and subjective sleep quality was improved compared to the CTL (−1.50; CI: 2.76−6.14 vs. 0.00; CI: 1.67−3.84 p = 0.02) in an intention-to-treat analysis. Levels of interleukin-10 (IL-10) (2.13 ± 0.80 vs. 2.51 ± 0.99; p < 0.03) and interleukin-1 receptor antagonist (IL-1ra) (0.99 ± 0.10 vs. 0.99 ± 0.10 ng/mL; p < 0.04; delta variation) were increased in the RET group. Conclusions: RET improves sleep parameters linked to muscle performance, possibly due to an increase in anti-inflammatory markers in older sarcopenic patients.
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Sleep Disturbance Affects Immune Factors in Clinical Liver Cancer Patients.
Wang, Z, Wang, Y, Huang, J, Xu, J, Chen, F, Zhu, Z, Gao, L, Qin, J, Liu, B, Liang, C
Current oncology (Toronto, Ont.). 2022;29(10):7943-7952
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Many studies have shown that sleep disorders promote tumor growth and can impair immunity at the cellular level. There is however a lack of research in patients with liver cancer. The aim of this study was the asses the quality of sleep and the prevalence of disturbed sleep in patients with liver cancer and to explore whether sleep quality influences immune factors. 210 patients with liver cancer were randomly divided into 2 groups: HBV (Hepatitis B virus) cirrhosis and non-HBV cirrhosis. Their sleep quality was evaluated using a questionnaire and then the patients were divided into 2 groups according to these scores. The association between sleep disturbances and immune factors was analysed by logistic regression models. Over half the patient experienced poor sleep quality. Sleep disturbances were higher in patients with liver cancer of non-HBV cirrhosis than with that coming from the HBV virus. A rise in CD3+ T cells and a reduction in NK cells are associated with sleep disturbances in patients with non-HBV cirrhosis liver cancer. Medicines that can promote sleep and therefore improve immune function might be beneficial. Non-pharmacological sleep interventions to improve sleep quality, should be a safer choice where there are complex drug side effects.
Abstract
BACKGROUND Sleep-wake disturbance is prevalent in patients with liver cancer, but there is no direct evidence of its association and related biological mechanisms. Our study was to assess quality of sleep and to describe prevalence of sleep disturbances in patients with different etiologies of liver cancer, especially to explore whether sleep quality influences immune factors. METHODS A total of 210 patients with liver cancer from August 2015 to December 2015 were randomly divided into two groups including HBV cirrhosis and non-HBV cirrhosis. The Pittsburgh Sleep Quality Index (PSQI) was used to evaluate their sleep quality, and then 202 patients enrolled in this study were divided into two groups according to their PSQI scores: PSQI ≤ 5 and PSQI > 5. The association between sleep disturbances and immune factors was analyzed by logistic regression models. RESULTS A total of 56.9% of liver cancer patients experienced poor sleep quality (PSQI > 5). The prevalence of sleep disturbances was significantly higher in patients with liver cancer of non-hepatitis B virus (HBV) cirrhosis than with that evolving from HBV cirrhosis (66.7% vs. 50%, p = 0.018). In non-HBV cirrhosis liver cancer patients, the PSQI > 5 group had a higher percentage of CD3+ T cells (71.06 ± 11.07 vs. 63.96 ± 14.18, p = 0.014) and lower natural killer (NK) cells (14.67 ± 9.65 vs. 20.5 ± 10.77, p = 0.014) compared with patients with PSQI ≤ 5. Logistic regression further confirmed that liver cancer patients without HBV cirrhosis are more prone to experience poor sleep with increased CD3+ T cells (OR = 1.07, 95% CI = 1.01-1.13, p = 0.030) and decreased NK cells (OR = 0.92, 95% CI = 0.85-0.98, p = 0.014). Our results indicate that increased CD3+ T cells and decreased NK cells are both associated with sleep disturbances in patients with liver cancer of non-HBV cirrhosis. CONCLUSIONS Most liver cancer patients suffer from sleep disturbances, especially evolving from non-HBV cirrhosis. A rise in CD3+ T cells and a reduction in NK cells are associated with sleep disturbances in patients with liver cancer of non-HBV cirrhosis.
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The impact of sleeping with reduced glycogen stores on immunity and sleep in triathletes.
Louis, J, Marquet, LA, Tiollier, E, Bermon, S, Hausswirth, C, Brisswalter, J
European journal of applied physiology. 2016;116(10):1941-54
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Endurance athletes are increasingly using training strategies focused on low glycogen availability in attempt to improve performance. It is well known, however, that increasing training stress could influence immune function and increase the risk of illness or injury. In endurance sports, training load, nutrient intake and sleep are key factors in modulating immune function. The aim of this study was to investigate the effects of a 3-week training strategy involving lowered glycogen availability overnight on immune function, upper respiratory tract infections and sleep patterns in 21 trained endurance athletes. This study found that reduced glycogen availability resulted in significantly faster 10km running times, and found no significant changes in the recorded immunity markers. Based on this study, the authors conclude that reduced glycogen availability has no deleterious impact on immune function.
Abstract
PURPOSE We investigated the effects of a 3-week dietary periodization on immunity and sleep in triathletes. METHODS 21 triathletes were divided into two groups with different nutritional guidelines during a 3-week endurance training program including nine twice a day sessions with lowered (SL group) or maintained (CON group) glycogen availability during the overnight recovery period. In addition to performance tests, sleep was monitored every night. Systemic and mucosal immune parameters as well as the incidence of URTI were monitored every week of the training/nutrition protocol. Two-ways ANOVA and effect sizes were used to examine differences in dependent variables between groups at each time point. RESULTS The SL group significantly improved 10 km running performance (-1 min 13 s, P < 0.01, d = 0.38), whereas no improvement was recorded in the CON group (-2 s, NS). No significant changes in white blood cells counts, plasma cortisol and IL-6 were recorded over the protocol in both groups. The vitamin D status decreased in similar proportions between groups, whereas salivary IgA decreased in the SL group only (P < 0.05, d = 0.23). The incidence of URTI was not altered in both groups. All participants in both groups went to bed earlier during the training program (SL -20 min, CON -27 min, P < 0.05, d = 0.28). In the SL group, only sleep efficiency slightly decreased by 1.1 % (P < 0.05, d = 0.25) and the fragmentation index tended to increase at the end of the protocol (P = 0.06). CONCLUSION Sleeping and training the next morning regularly with reduced glycogen availability has minimal effects on selected markers of immunity, the incidence of URTI and sleeping patterns in trained athletes.
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Sleep restriction for 1 week reduces insulin sensitivity in healthy men.
Buxton, OM, Pavlova, M, Reid, EW, Wang, W, Simonson, DC, Adler, GK
Diabetes. 2010;59(9):2126-33
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Short sleep duration is associated with an increased risk of many chronic diseases including diabetes, however the effects of sleep restriction on insulin sensitivity have not yet been established. The aim of study was to assess the effects of decreased sleep duration on insulin sensitivity in a controlled environment. This 12-day inpatient study included 20 healthy men who were randmoised to receive a wakefulness-promoting drug, modafinil, or placebo during the sleep restriction phase. This study showed that sleep restriction for one week significantly reduces insulin sensitivity. These findings raise concerns about chronic insufficient sleep on the development of metabolic diseases and promote further research into these effects.
Abstract
OBJECTIVE Short sleep duration is associated with impaired glucose tolerance and an increased risk of diabetes. The effects of sleep restriction on insulin sensitivity have not been established. This study tests the hypothesis that decreasing nighttime sleep duration reduces insulin sensitivity and assesses the effects of a drug, modafinil, that increases alertness during wakefulness. RESEARCH DESIGN AND METHODS This 12-day inpatient General Clinical Research Center study included 20 healthy men (age 20-35 years and BMI 20-30 kg/m(2)). Subjects spent 10 h/night in bed for >or=8 nights including three inpatient nights (sleep-replete condition), followed by 5 h/night in bed for 7 nights (sleep-restricted condition). Subjects received 300 mg/day modafinil or placebo during sleep restriction. Diet and activity were controlled. On the last 2 days of each condition, we assessed glucose metabolism by intravenous glucose tolerance test (IVGTT) and euglycemic-hyperinsulinemic clamp. Salivary cortisol, 24-h urinary catecholamines, and neurobehavioral performance were measured. RESULTS IVGTT-derived insulin sensitivity was reduced by (means +/- SD) 20 +/- 24% after sleep restriction (P = 0.001), without significant alterations in the insulin secretory response. Similarly, insulin sensitivity assessed by clamp was reduced by 11 +/- 5.5% (P < 0.04) after sleep restriction. Glucose tolerance and the disposition index were reduced by sleep restriction. These outcomes were not affected by modafinil treatment. Changes in insulin sensitivity did not correlate with changes in salivary cortisol (increase of 51 +/- 8% with sleep restriction, P < 0.02), urinary catecholamines, or slow wave sleep. CONCLUSIONS Sleep restriction (5 h/night) for 1 week significantly reduces insulin sensitivity, raising concerns about effects of chronic insufficient sleep on disease processes associated with insulin resistance.
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Exposure to recurrent sleep restriction in the setting of high caloric intake and physical inactivity results in increased insulin resistance and reduced glucose tolerance.
Nedeltcheva, AV, Kessler, L, Imperial, J, Penev, PD
The Journal of clinical endocrinology and metabolism. 2009;94(9):3242-50
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Type-2 diabetes (T2D) is a complex disease influenced by genetic, environmental, metabolic and behavioural factors and is a rising burden in Westernised societies. Whether reduced sleep duration, in the context of a Western lifestyle, is associated with an increased incidence of T2D is unclear and available evidence is limited. The aim of this crossover study was to determine whether sleep restriction may result in a decreased glucose tolerance and reduced insulin secretion in 11 healthy middle-aged adults. Participants were restricted to 5.5 hours of sleep per night and glucose challenges and circulating plasma concentrations were used to measure hormonal and metabolic parameters. This study showed that recurrent short sleep times may facilitate the development of insulin resistance and reduced glucose tolerance. These findings suggest that combining the adverse metabolic effects of a Western lifestyle with chronically reduced sleep duration may increase the long-term risk of developing T2D.
Abstract
CONTEXT Epidemiological data indicate that reduced sleep duration is associated with increased incidence of type-2 diabetes. OBJECTIVE The aim of the study was to test the hypothesis that, when part of a Western-like lifestyle, recurrent bedtime restriction may result in decreased glucose tolerance and reduced insulin secretion and action. DESIGN AND SETTING We conducted a randomized crossover study at a university clinical research center and sleep research laboratory. PARTICIPANTS Eleven healthy volunteers (five females and six males) with a mean (+/-sd) age of 39 +/- 5 yr and body mass index of 26.5 +/- 1.5 kg/m(2) participated in the study. INTERVENTION The study included two 14-d periods of controlled exposure to sedentary living with ad libitum food intake and 5.5- or 8.5-h bedtimes. MAIN OUTCOME MEASURES Oral and iv glucose challenges were used to obtain measures of glucose tolerance, glucose effectiveness, insulin secretion, and insulin sensitivity at the end of each intervention. Secondary measures included circulating concentrations of the glucose counter-regulatory hormones, cortisol, GH, epinephrine, and norepinephrine. RESULTS Bedtime restriction reduced daily sleep by 122 +/- 25 min. Both study periods were associated with comparable weight gain; however, recurrent sleep restriction resulted in reduced oral glucose tolerance (2-h glucose value, 144 +/- 25 vs. 132 +/- 36 mg/dl; P < 0.01) and insulin sensitivity [3.3 +/- 1.1 vs. 4.0 +/- 1.6 (mU/liter)(-1) x min(-1); P < 0.03], and increased glucose effectiveness (0.023 +/- 0.005 vs. 0.020 +/- 0.005 min(-1); P < 0.04). Although 24-h cortisol and GH concentrations did not change, there was a modest increase in 24-h epinephrine and nighttime norepinephrine levels during the 5.5-h bedtime condition. CONCLUSIONS Experimental bedtime restriction, designed to approximate the short sleep times experienced by many individuals in Westernized societies, may facilitate the development of insulin resistance and reduced glucose tolerance.