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Lifestyle and vascular risk effects on MRI-based biomarkers of Alzheimer's disease: a cross-sectional study of middle-aged adults from the broader New York City area.
Mosconi, L, Walters, M, Sterling, J, Quinn, C, McHugh, P, Andrews, RE, Matthews, DC, Ganzer, C, Osorio, RS, Isaacson, RS, et al
BMJ open. 2018;8(3):e019362
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Alzheimer’s disease (AD) is the most common form of dementia, affecting nearly 34 million people worldwide. It has been estimated that one in every three cases of AD may be attributable to diet and lifestyle factors. The aim of this study was to investigate the effects of lifestyle and vascular-related risk factors for AD. Researchers studied the brain scans of 116 healthy adults aged 30-60 years. They collected information on factors related to lifestyle, such as diet, physical activity and intellectual enrichment. They also looked at markers for vascular risk such as body mass index (BMI), cholesterol and homocysteine, as well as cognitive function. The researchers found that a Mediterranean-style diet and good insulin sensitivity were both associated with a healthier brain structure. A better score for intellectual enrichment and lower BMI were both associated with better cognition. They concluded that adopting a Mediterranean-style diet and maintaining a healthy weight might reduce the risk of developing AD.
Abstract
OBJECTIVE To investigate the effects of lifestyle and vascular-related risk factors for Alzheimer's disease (AD) on in vivo MRI-based brain atrophy in asymptomatic young to middle-aged adults. DESIGN Cross-sectional, observational. SETTING Broader New York City area. Two research centres affiliated with the Alzheimer's disease Core Center at New York University School of Medicine. PARTICIPANTS We studied 116 cognitively normal healthy research participants aged 30-60 years, who completed a three-dimensional T1-weighted volumetric MRI and had lifestyle (diet, physical activity and intellectual enrichment), vascular risk (overweight, hypertension, insulin resistance, elevated cholesterol and homocysteine) and cognition (memory, executive function, language) data. Estimates of cortical thickness for entorhinal (EC), posterior cingulate, orbitofrontal, inferior and middle temporal cortex were obtained by use of automated segmentation tools. We applied confirmatory factor analysis and structural equation modelling to evaluate the associations between lifestyle, vascular risk, brain and cognition. RESULTS Adherence to a Mediterranean-style diet (MeDi) and insulin sensitivity were both positively associated with MRI-based cortical thickness (diet: βs≥0.26, insulin sensitivity βs≥0.58, P≤0.008). After accounting for vascular risk, EC in turn explained variance in memory (P≤0.001). None of the other lifestyle and vascular risk variables were associated with brain thickness. In addition, the path associations between intellectual enrichment and better cognition were significant (βs≥0.25 P≤0.001), as were those between overweight and lower cognition (βs≥-0.22, P≤0.01). CONCLUSIONS In cognitively normal middle-aged adults, MeDi and insulin sensitivity explained cortical thickness in key brain regions for AD, and EC thickness predicted memory performance in turn. Intellectual activity and overweight were associated with cognitive performance through different pathways. Our findings support further investigation of lifestyle and vascular risk factor modification against brain ageing and AD. More studies with larger samples are needed to replicate these research findings in more diverse, community-based settings.
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Circadian Rhythms, Metabolism, and Chrononutrition in Rodents and Humans.
Johnston, JD, Ordovás, JM, Scheer, FA, Turek, FW
Advances in nutrition (Bethesda, Md.). 2016;7(2):399-406
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Chrononutrition is an emerging field that links the body’s metabolism to its endogenous circadian rhythm. It is now recognised that numerous circadian clocks are found within all major tissues and most cells of the body. This complex network of clocks influences a wide range of biological processes including neuronal, endocrine, metabolic and behavioural function. When there is a disruption in a single circadian clock, whole-organism homeostasis can be impacted, potentially resulting in the development of disease. This review explains the potential mechanisms by which circadian clocks influence biological processes through transgenic animal studies, and how they are being translated to human genetics and metabolomics. The principles of chrononutrition are clinically significant factors that should be considered when managing and treating metabolic disease, as well as maintaining health in the general population.
Abstract
Chrononutrition is an emerging discipline that builds on the intimate relation between endogenous circadian (24-h) rhythms and metabolism. Circadian regulation of metabolic function can be observed from the level of intracellular biochemistry to whole-organism physiology and even postprandial responses. Recent work has elucidated the metabolic roles of circadian clocks in key metabolic tissues, including liver, pancreas, white adipose, and skeletal muscle. For example, tissue-specific clock disruption in a single peripheral organ can cause obesity or disruption of whole-organism glucose homeostasis. This review explains mechanistic insights gained from transgenic animal studies and how these data are being translated into the study of human genetics and physiology. The principles of chrononutrition have already been demonstrated to improve human weight loss and are likely to benefit the health of individuals with metabolic disease, as well as of the general population.
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Reversal of cognitive decline in Alzheimer's disease.
Bredesen, DE, Amos, EC, Canick, J, Ackerley, M, Raji, C, Fiala, M, Ahdidan, J
Aging. 2016;8(6):1250-8
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Alzheimer’s disease is the third leading cause of death and is one of the most significant global healthcare problems of modern times. It leads initially to cognitive decline – inability to recall words and faces, do mental calculations, navigate on familiar routes – and eventually to complete loss of memory and ability to perform routine daily tasks. Conventional therapy focuses on single drug therapies and success with these has been limited. This case study report details the results of 10 patients experiencing differing degrees of cognitive decline and early Alzheimer’s disease. Each patient followed a personalised, multiple therapy programme for 5 months to 2 years, based on their genetics, markers for blood glucose management, lipid profile, homocysteine, Vitamin D and inflammation, amongst others. Each case reports a quantified improvement in brain function, as well as subjective improvements reported by the carers and patients. The authors call for funding for a randomised controlled trial and for early detection and treatment using a multi-faceted protocol. Nutrition Practitioners working with cognitive decline can use the case study reports to inform their testing choices and personalised nutrition and lifestyle protocols.
Abstract
Alzheimer's disease is one of the most significant healthcare problems nationally and globally. Recently, the first description of the reversal of cognitive decline in patients with early Alzheimer's disease or its precursors, MCI (mild cognitive impairment) and SCI (subjective cognitive impairment), was published [1]. The therapeutic approach used was programmatic and personalized rather than monotherapeutic and invariant, and was dubbed metabolic enhancement for neurodegeneration (MEND). Patients who had had to discontinue work were able to return to work, and those struggling at work were able to improve their performance. The patients, their spouses, and their co-workers all reported clear improvements. Here we report the results from quantitative MRI and neuropsychological testing in ten patients with cognitive decline, nine ApoE4+ (five homozygous and four heterozygous) and one ApoE4-, who were treated with the MEND protocol for 5-24 months. The magnitude of the improvement is unprecedented, providing additional objective evidence that this programmatic approach to cognitive decline is highly effective. These results have far-reaching implications for the treatment of Alzheimer's disease, MCI, and SCI; for personalized programs that may enhance pharmaceutical efficacy; and for personal identification of ApoE genotype.
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Excessive Sugar Consumption May Be a Difficult Habit to Break: A View From the Brain and Body.
Tryon, MS, Stanhope, KL, Epel, ES, Mason, AE, Brown, R, Medici, V, Havel, PJ, Laugero, KD
The Journal of clinical endocrinology and metabolism. 2015;100(6):2239-47
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It is widely known that people eat to relieve stress. Rodent studies have shown that sugar consumption switches off activity in the networks that mediate the stress induced hypothalamic-pituitary-adrenal (HPA) autonomic nervous system. This study aimed to compare the effects of consuming drinks, sweetened with either sucrose or aspartame, on cortisol responses induced by stress. The researchers found that sucrose consumption was associated reduced stress induced cortisol, and a trend towards lower cortisol. Aspartame did not have the same effect. The Montreal Imaging Stress Task (MIST) was used to map areas of the brain associated with stress. It was found that sugar consumption caused a diminished response to MIST after two weeks of sucrose consumption, and cortisol was elevated after two weeks of aspartame. The study concluded that brain negative feedback pathways are affected by sugar, and consequently may make stressed individuals more reliant or addicted to sugar. In turn, this increases the likelihood of obesity and its associated chronic diseases.
Abstract
CONTEXT Sugar overconsumption and chronic stress are growing health concerns because they both may increase the risk for obesity and its related diseases. Rodent studies suggest that sugar consumption may activate a glucocorticoid-metabolic-brain-negative feedback pathway, which may turn off the stress response and thereby reinforce habitual sugar overconsumption. OBJECTIVE The objective of the study was to test our hypothesized glucocorticoid-metabolic-brain model in women consuming beverages sweetened with either aspartame of sucrose. DESIGN This was a parallel-arm, double-masked diet intervention study. SETTING The study was conducted at the University of California, Davis, Clinical and Translational Science Center's Clinical Research Center and the University of California, Davis, Medical Center Imaging Research Center. PARTICIPANTS Nineteen women (age range 18-40 y) with a body mass index (range 20-34 kg/m(2)) who were a subgroup from a National Institutes of Health-funded investigation of 188 participants assigned to eight experimental groups. INTERVENTION The intervention consisted of sucrose- or aspartame-sweetened beverage consumption three times per day for 2 weeks. MAIN OUTCOME MEASURES Salivary cortisol and regional brain responses to the Montreal Imaging Stress Task were measured. RESULTS Compared with aspartame, sucrose consumption was associated with significantly higher activity in the left hippocampus (P = .001). Sucrose, but not aspartame, consumption associated with reduced (P = .024) stress-induced cortisol. The sucrose group also had a lower reactivity to naltrexone, significantly (P = .041) lower nausea, and a trend (P = .080) toward lower cortisol. CONCLUSION These experimental findings support a metabolic-brain-negative feedback pathway that is affected by sugar and may make some people under stress more hooked on sugar and possibly more vulnerable to obesity and its related conditions.
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Metabolic profiling distinguishes three subtypes of Alzheimer's disease.
Bredesen, DE
Aging. 2015;7(8):595-600
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The causes of Alzheimer’s Disease (AD) remain incompletely defined and there are currently no truly effective drug therapies available. However, there is growing evidence that disordered blood glucose management and hormonal changes and deficiencies, amongst other things, are implicated in symptom onset. Optimising these various metabolic processes, therefore, may be used as a comprehensive way to avoid cognitive decline or achieve cognitive improvements in symptomatic individuals. This report provides the metabolic results of 3 case studies and suggests 3 different types of AD classification, depending on the individual metabolic profile. Further studies are required to elaborate on the metabolic profiles suggested in this report, however Nutrition Practitioners working with cognitive decline, can use this report as a basis for individualised nutrition protocols to optimise metabolic processes in clients with cognitive decline.
Abstract
The cause of Alzheimer's disease is incompletely defined, and no truly effective therapy exists. However, multiple studies have implicated metabolic abnormalities such as insulin resistance, hormonal deficiencies, and hyperhomocysteinemia. Optimizing metabolic parameters in a comprehensive way has yielded cognitive improvement, both in symptomatic and asymptomatic individuals. Therefore, expanding the standard laboratory evaluation in patients with dementia may be revealing. Here I report that metabolic profiling reveals three Alzheimer's disease subtypes. The first is inflammatory, in which markers such as hs-CRP and globulin:albumin ratio are increased. The second type is non-inflammatory, in which these markers are not increased, but other metabolic abnormalities are present. The third type is a very distinctive clinical entity that affects relatively young individuals, extends beyond the typical Alzheimer's disease initial distribution to affect the cortex widely, is characterized by early non-amnestic features such as dyscalculia and aphasia, is often misdiagnosed or labeled atypical Alzheimer's disease, typically affects ApoE4-negative individuals, and is associated with striking zinc deficiency. Given the involvement of zinc in multiple Alzheimer's-related metabolic processes, such as insulin resistance, chronic inflammation, ADAM10 proteolytic activity, and hormonal signaling, this syndrome of Alzheimer's-plus with low zinc (APLZ) warrants further metabolic, genetic, and epigenetic characterization.
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Sleep restriction increases the neuronal response to unhealthy food in normal-weight individuals.
St-Onge, MP, Wolfe, S, Sy, M, Shechter, A, Hirsch, J
International journal of obesity (2005). 2014;38(3):411-6
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Sleep patterns influence eating behaviour and the body’s response to food. Previous studies suggest that short sleep duration leads to increased caloric intake and a desire for high-fat foods, however the specific neural mechanisms explaining how sleep restriction modulates this response is unknown. The aim of this study was to determine whether a specific area of the brain is activated in response to unhealthy compared with healthy foods. 25 participants were included, all of which were normal weight and had normal sleeping patterns. Each participant was tested after five nights of either 4 or 9 hours in bed by functional magnetic resonance imaging (fMRI). The test was performed while the participant was shown healthy and unhealthy food photos in the fasted state. This study found that after a period of restricted sleep compared with habitual sleep, unhealthy foods led to greater activation in brain regions associated with reward compared with healthy foods. This finding provides a model of neuronal mechanisms relating short sleep duration to obesity and cardio-metabolic risk factors and warrants further investigation.
Abstract
CONTEXT Sleep restriction alters responses to food. However, the underlying neural mechanisms for this effect are not well understood. OBJECTIVE The purpose of this study was to determine whether there is a neural system that is preferentially activated in response to unhealthy compared with healthy foods. PARTICIPANTS Twenty-five normal-weight individuals, who normally slept 7-9 h per night, completed both phases of this randomized controlled study. INTERVENTION Each participant was tested after a period of five nights of either 4 or 9 h in bed. Functional magnetic resonance imaging (fMRI) was performed in the fasted state, presenting healthy and unhealthy food stimuli and objects in a block design. Neuronal responses to unhealthy, relative to healthy food stimuli after each sleep period were assessed and compared. RESULTS After a period of restricted sleep, viewing unhealthy foods led to greater activation in the superior and middle temporal gyri, middle and superior frontal gyri, left inferior parietal lobule, orbitofrontal cortex, and right insula compared with healthy foods. These same stimuli presented after a period of habitual sleep did not produce marked activity patterns specific to unhealthy foods. Further, food intake during restricted sleep increased in association with a relative decrease in brain oxygenation level-dependent (BOLD) activity observed in the right insula. CONCLUSION This inverse relationship between insula activity and food intake and enhanced activation in brain reward and food-sensitive centers in response to unhealthy foods provides a model of neuronal mechanisms relating short sleep duration to obesity.
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Reversal of cognitive decline: a novel therapeutic program.
Bredesen, DE
Aging. 2014;6(9):707-17
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Alzheimer’s Disease (AD) is estimated to affect 30 million individuals globally, with projections as high as 150 million by 2050 if no effective treatment is found. This report describes a personalised, multi-modal, therapeutic programme used with 10 individuals with various degrees of cognitive decline. The goal was to optimise metabolic parameters and lifestyle factors and was personalised based on laboratory test results. 9 out of 10 of the case study patients experienced improvement in cognitive abilities, beginning within 3-6 months of starting the programme. These effects were sustained at 2.5 year follow up. The 1 patient who did not benefit had advanced AD, in comparison to the other patients with subjective or mild cognitive decline. The authors call for a more extensive trial of the therapeutic programme.
Abstract
This report describes a novel, comprehensive, and personalized therapeutic program that is based on the underlying pathogenesis of Alzheimer's disease, and which involves multiple modalities designed to achieve metabolic enhancement for neurodegeneration (MEND). The first 10 patients who have utilized this program include patients with memory loss associated with Alzheimer's disease (AD), amnestic mild cognitive impairment (aMCI), or subjective cognitive impairment (SCI). Nine of the 10 displayed subjective or objective improvement in cognition beginning within 3-6 months, with the one failure being a patient with very late stage AD. Six of the patients had had to discontinue working or were struggling with their jobs at the time of presentation, and all were able to return to work or continue working with improved performance. Improvements have been sustained, and at this time the longest patient follow-up is two and one-half years from initial treatment, with sustained and marked improvement. These results suggest that a larger, more extensive trial of this therapeutic program is warranted. The results also suggest that, at least early in the course, cognitive decline may be driven in large part by metabolic processes. Furthermore, given the failure of monotherapeutics in AD to date, the results raise the possibility that such a therapeutic system may be useful as a platform on which drugs that would fail as monotherapeutics may succeed as key components of a therapeutic system.
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Dietary intake following experimentally restricted sleep in adolescents.
Beebe, DW, Simon, S, Summer, S, Hemmer, S, Strotman, D, Dolan, LM
Sleep. 2013;36(6):827-34
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Obesity in adolescents and adults has become a well recognised public health hazard. In this study the relationship of restricted sleep and consumption of high glycemic index foods, in particular sweets and desserts, was measured in adolescents. A 3-week experimental sleep manipulation protocol was designed. The order of experimental conditions was counterbalanced across participants in a randomised crossover design. All participants sleep time was in their home setting and was monitored via a daily sleep diary. No instructions were given regarding diet except to limit caffeine and energy drinks. Data was collected through sleep watches and the teens were instructed to wear the watch only during sleep time and throughout the night. A 24-hour diet recall was done at the end of each week. The results of the study showed that there was increased consumption of desserts and sweets during restricted sleep. The diets of adolescents after several nights of sleep restriction were characterised by higher glycemic index and glycemic load, as well as a trend toward high consumption of calories and carbohydrates. Sleep restriction may lead to to changes in dietary choices and dietary behaviour that may have long term negative impact on health.
Abstract
STUDY OBJECTIVE To examine the relationship between sleep and dietary intake in adolescents using an experimental sleep restriction protocol. DESIGN Randomized crossover sleep restriction-extension paradigm. SETTING Sleep obtained and monitored at home, diet measured during an office visit. PARTICIPANTS Forty-one typically developing adolescents age 14-16 years. INTERVENTIONS The 3-week protocol consisting of a baseline week designed to stabilize the circadian rhythm, followed randomly by 5 consecutive nights of sleep restriction (6.5 hours in bed Monday-Friday) versus healthy sleep duration (10 hours in bed), a 2-night washout period, and a 5-night crossover period. MEASUREMENTS Sleep was monitored via actigraphy and teens completed validated 24-hour diet recall interviews following each experimental condition. RESULTS Paired-sample t-tests examined differences between conditions for consumption of key macronutrients and choices from dietary categories. Compared with the healthy sleep condition, sleep-restricted adolescents' diets were characterized by higher glycemic index and glycemic load and a trend toward more calories and carbohydrates, with no differences in fat or protein consumption. Exploratory analyses revealed the consumption of significantly more desserts and sweets during sleep restriction than healthy sleep. CONCLUSIONS Chronic sleep restriction during adolescence appears to cause increased consumption of foods with a high glycemic index, particularly desserts/sweets. The chronic sleep restriction common in adolescence may cause changes in dietary behaviors that increase risk of obesity and associated morbidity.
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Effects of dietary glycemic index on brain regions related to reward and craving in men.
Lennerz, BS, Alsop, DC, Holsen, LM, Stern, E, Rojas, R, Ebbeling, CB, Goldstein, JM, Ludwig, DS
The American journal of clinical nutrition. 2013;98(3):641-7
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Clinical studies using functional brain imaging have found increased activity in the nucleus accumbens (thought to play a central role in reward and cravings) in obese subjects after viewing or eating highly palatable, calorific food. Additionally, studies have shown that striatal dopamine receptor activity was lower for obese subjects, suggesting that overeating may compensate for lower dopamine activity in these people. This study compared the brain activity following a high GI or a low GI meal, focusing on the areas of the brain that are responsible for eating behaviour, reward and addiction. Subjects were healthy overweight or obese men. The findings showed that compared to low GI meals, a high GI meal increased self-reported hunger, stimulated brain regions associated with reward and cravings, and decreased blood glucose (which could increase hunger and the hedonistic value of food).
Abstract
BACKGROUND Qualitative aspects of diet influence eating behavior, but the physiologic mechanisms for these calorie-independent effects remain speculative. OBJECTIVE We examined effects of the glycemic index (GI) on brain activity in the late postprandial period after a typical intermeal interval. DESIGN With the use of a randomized, blinded, crossover design, 12 overweight or obese men aged 18-35 y consumed high- and low-GI meals controlled for calories, macronutrients, and palatability on 2 occasions. The primary outcome was cerebral blood flow as a measure of resting brain activity, which was assessed by using arterial spin-labeling functional magnetic resonance imaging 4 h after test meals. We hypothesized that brain activity would be greater after the high-GI meal in prespecified regions involved in eating behavior, reward, and craving. RESULTS Incremental venous plasma glucose (2-h area under the curve) was 2.4-fold greater after the high- than the low-GI meal (P = 0.0001). Plasma glucose was lower (mean ± SE: 4.7 ± 0.14 compared with 5.3 ± 0.16 mmol/L; P = 0.005) and reported hunger was greater (P = 0.04) 4 h after the high- than the low-GI meal. At this time, the high-GI meal elicited greater brain activity centered in the right nucleus accumbens (a prespecified area; P = 0.0006 with adjustment for multiple comparisons) that spread to other areas of the right striatum and to the olfactory area. CONCLUSIONS Compared with an isocaloric low-GI meal, a high-GI meal decreased plasma glucose, increased hunger, and selectively stimulated brain regions associated with reward and craving in the late postprandial period, which is a time with special significance to eating behavior at the next meal. This trial was registered at clinicaltrials.gov as NCT01064778.