1.
Habitual daily intake of a sweet and fatty snack modulates reward processing in humans.
Edwin Thanarajah, S, DiFeliceantonio, AG, Albus, K, Kuzmanovic, B, Rigoux, L, Iglesias, S, Hanßen, R, Schlamann, M, Cornely, OA, Brüning, JC, et al
Cell metabolism. 2023;35(4):571-584.e6
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The prolific amount of sugar and fat in modern Western diets is regarded as a significant contributor to overeating and consequential weight gain. Dopamine, a neurotransmitter involved in learning and reward signalling, is also important in regulating food intake. Energy-dense foods, often high in both sugar and fat, stimulate pleasure-signalling dopamine to encourage eating, even if no more energy is needed. It is acknowledged that in many cases of obesity, the function of dopamine appears to be altered. Yet it is uncertain whether this was pre-existing to obesity, a result of obesity or whether it was re-shaped though exposure to high sugar and high-fat diets. To gain more insights, this study evaluated whether adding a high-fat/high-sugar (HF/HS) snack or a low-fat/low-sugar (LF/LS) snack to a regular diet could change the candidates liking for fat, their brain responses to likeable foods like fat and sugar and if it impacted on sensory associative learning. The randomised controlled study was conducted for 8-weeks and included 49 people of normal-weight. The candidates were also monitored for any changes in weight and body fat, insulin resistance, leptin levels, and blood fats, and all completed self-reported dietary intake forms. The findings demonstrated that repeated exposure to HF/HS food reduced the preference for low-fat foods and up-regulated the brain responses when anticipating and consuming such highly palatable, energy-dense foods. Beyond increased brain response to HF/HS food, HF/HS exposure also induced a general rewiring of the brain by enhancing new sensory associations and behavioural adaptations that were unrelated to food. Notably, these changes all occurred independent of weight gain or alterations in metabolic function, thus suggesting that repeated exposure to HF/HS foods can change the physiology in healthy weight individuals to reduce their liking of healthier foods whilst at the same time increasing the reward responses to more palatable HF/ HS foods. The authors highlighted this as a risk for overeating and weight gain, arguing that reducing the exposure to energy-dense HF/HS food items therefore is critical in the prevention and management of obesity.
Abstract
Western diets rich in fat and sugar promote excess calorie intake and weight gain; however, the underlying mechanisms are unclear. Despite a well-documented association between obesity and altered brain dopamine function, it remains elusive whether these alterations are (1) pre-existing, increasing the individual susceptibility to weight gain, (2) secondary to obesity, or (3) directly attributable to repeated exposure to western diet. To close this gap, we performed a randomized, controlled study (NCT05574660) with normal-weight participants exposed to a high-fat/high-sugar snack or a low-fat/low-sugar snack for 8 weeks in addition to their regular diet. The high-fat/high-sugar intervention decreased the preference for low-fat food while increasing brain response to food and associative learning independent of food cues or reward. These alterations were independent of changes in body weight and metabolic parameters, indicating a direct effect of high-fat, high-sugar foods on neurobehavioral adaptations that may increase the risk for overeating and weight gain.
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Men’s Health for Physical Performance and Longevity
The Functional Health Podcast is hosted by Ben Atkinson, a nutritionist with the core belief that a holistic and functional approach to health is fundamental to optimal well-being. The podcast promotes the integration and collaboration of conventional, complementary and allied health professionals in order to prosper in the changing landscape of healthcare.
2023
Abstract
Rick Miller is a clinical and sports dietician who is trained in functional medicine. In this podcast he eloquently explores optimal nutrition and exercise for men to support physical performance and longevity. He discusses the nuances around men and masculinity and how men are less likely to seek support for whole host of common issues such as insulin resistance, mental health, gastric concerns and sexual dysfunction. Interestingly, dopamine excess has been shown to impact libido and he manages this via a dopamine fast and cold exposure. Rick reviews the evidence around macronutrients on testosterone levels and explains his rationale for using an animal based eating approach within his clinic.
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The influence of macronutrient intake, stress and prostaglandin levels (pgf2α) of urine with the incidence of dysmenorrhea in adolescents.
Tahir, A, Sinrang, AW, Jusuf, EC, Syamsuddin, S, Stang, Arsyad, A
Gaceta sanitaria. 2021;35 Suppl 2:S298-S301
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Dysmenorrhea is a health problem that has a negative impact on the physical and emotional aspects of health. It also causes absenteeism in school that affects academic performance. The aim of this study was to analyse the influence of macronutrient intake, stress, and prostaglandin levels (pgf2α) on adolescent dysmenorrhea incidence. This study is an observational cohort study of 16 years old adolescents with a menstrual cycle every 21–35 days and a menstrual period of about 5–7 days. Results show that: - levels of pgf2α affect the incidence of dysmenorrhea i.e., prostaglandins can reduce or temporarily inhibit blood supply to the uterus, causing the uterus to lack oxygen and cause myometrium contraction which in turn causes pain. - stress is very influential with dysmenorrhea as it can interfere with the work of the endocrine system. - an insufficient intake of nutrients may increase the risk of dysmenorrhoea. Thus, adolescents should ensure adequate intake of macronutrients especially during menstruation. Authors conclude that stress and prostaglandin levels significantly affect the occurrence of dysmenorrhea in adolescents.
Abstract
OBJECTIVES This study aimed to analyze the influence of macronutrient intake, stress, and prostaglandin levels (pgf2α) on adolescent dysmenorrhea incidence. METHOD This type of study is observational analytic with a cohort study draft done in January-March 2020 at High junior school 21 Makassar. Respondents in this study were grade X and XI students divided into 64 teenagers who had dysmenorrhea and 64 adolescents who did not experience Dysmenrhea. The criteria of the respondent in this study were the reproductive age, already experiencing menstruation, knowing the time and date of menstruation, menstrual cycles were regular, and willing to be respondents. The study used Menstrual Symptoms Questionnaire (MSQ) and used an ultrasonography (ultrasound) examination to perform the sample cervical. Food recall 24 hours to assess the intake of macronutrients, Depression Anxiety Stress Scales (DASS 42) to measure stress levels, and an examination of urine prostaglandin levels using the method Enzyme-Linked Immunosorbent Assay (ELISA). Urine intake is carried out on the second day as much as 2-5cc. Data were analyzed by the Chi-square test and logistics regression backward. RESULT A multivariate analysis showed a variable that strongly affects dysmenorrhea is stress with the value p=0.000 and the level of prostaglandins with p-value=0.003 compared to other variables. CONCLUSION Stress and prostaglandin levels significantly affect the occurrence of dysmenorrhea in adolescents.
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Differential Health Effects on Inflammatory, Immunological and Stress Parameters in Professional Soccer Players and Sedentary Individuals after Consuming a Synbiotic. A Triple-Blinded, Randomized, Placebo-Controlled Pilot Study.
Quero, CD, Manonelles, P, Fernández, M, Abellán-Aynés, O, López-Plaza, D, Andreu-Caravaca, L, Hinchado, MD, Gálvez, I, Ortega, E
Nutrients. 2021;13(4)
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Synbiotic, a mixture of prebiotics and probiotics, is known to improve neurotransmitter interactions, immune, inflammatory, and stress responses by modulating the gut microbial composition. It is also believed that physical activity plays an important role in the modulation of immune function and stress response. The purpose of this triple-blinded, randomized, placebo-controlled pilot study was to evaluate the health benefits of symbiotic intervention in fourteen sedentary students and thirteen soccer players, especially in terms of improving immunophysiological and metabolic parameters. The 300mg of symbiotic intervention contained Bifidobacterium lactis CBP-001010, Lactobacillus rhamnosus CNCM I-4036, Bifidobacterium longum ES1(109 colony-forming unit), and fructooligosaccharides (200 mg) plus 1.5 mg of zinc, 8.25 µg of selenium, 0.75 µg of vitamin, and maltodextrin. Following a one-month intervention with synbiotic formulation, soccer players showed improvements in anxiety, sleep quality and stress, a slight reduction in proinflammatory cytokine IL-1β, an exercise-induced significant increase in dopamine and a slight elevation of corticotropin-releasing hormone. For confirmation of results of this pilot study and to assess more significant effects of symbiotic intervention in athletes as well as in the general population, longer-term robust studies are required. The findings of this study can help healthcare professionals understand the extensive health benefits of synbiotic intervention and its relationship to physical activity.
Abstract
The main objective of this research was to carry out an experimental study, triple-blind, on the possible immunophysiological effects of a nutritional supplement (synbiotic, Gasteel Plus®, Heel España S.A.U.), containing a mixture of probiotic strains, such as Bifidobacterium lactis CBP-001010, Lactobacillus rhamnosus CNCM I-4036, and Bifidobacterium longum ES1, as well as the prebiotic fructooligosaccharides, on both professional athletes and sedentary people. The effects on some inflammatory/immune (IL-1β, IL-10, and immunoglobulin A) and stress (epinephrine, norepinephrine, dopamine, serotonin, corticotropin-releasing hormone (CRH), Adrenocorticotropic hormone (ACTH), and cortisol) biomarkers were evaluated, determined by flow cytometer and ELISA. The effects on metabolic profile and physical activity, as well as on various parameters that could affect physical and mental health, were also evaluated via the use of accelerometry and validated questionnaires. The participants were professional soccer players in the Second Division B of the Spanish League and sedentary students of the same sex and age range. Both study groups were randomly divided into two groups: a control group-administered with placebo, and an experimental group-administered with the synbiotic. Each participant was evaluated at baseline, as well as after the intervention, which lasted one month. Only in the athlete group did the synbiotic intervention clearly improve objective physical activity and sleep quality, as well as perceived general health, stress, and anxiety levels. Furthermore, the synbiotic induced an immunophysiological bioregulatory effect, depending on the basal situation of each experimental group, particularly in the systemic levels of IL-1β (increased significantly only in the sedentary group), CRH (decreased significantly only in the sedentary group), and dopamine (increased significantly only in the athlete group). There were no significant differences between groups in the levels of immunoglobulin A or in the metabolic profile as a result of the intervention. It is concluded that synbiotic nutritional supplements can improve anxiety, stress, and sleep quality, particularly in sportspeople, which appears to be linked to an improved immuno-neuroendocrine response in which IL-1β, CRH, and dopamine are clearly involved.
5.
Small talk: microbial metabolites involved in the signaling from microbiota to brain.
Caspani, G, Swann, J
Current opinion in pharmacology. 2019;48:99-106
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The gut-brain axis (GBA) is the communication network between the gastrointestinal tract and the central nervous system. An array of gut bacteria-derived metabolites mediates this interaction between the gastrointestinal system and the brain, influencing physiological and pathological processes in direct and indirect ways. Thus a variation in the gut microbiome can alter the functional capacity and output of the gut-brain-communication. In this review, the authors summarise key bacterial metabolites from the gut and their effect on the brain. Addressed are short-chain fatty acids, their impact on gut and brain barrier integrity, their role in appetite regulation, and their association with anxiety and depressive disorders amongst other aspects. Secondly, bile acids, which are processed by the microbiome, can activate several receptors. And thus divergence gut bacteria can alter the composition of bile acids and change their signalling capacity. Bile acids can also directly modify gut and blood-brain barrier function and may carry a signalling role in the brain. A few neurotransmitters are covered in this article, as several types of gut bacteria synthesize neurotransmitters, such as serotonin and dopamine. Though, it is uncertain whether all gut-derived neurotransmitters can reach the brain. However, certain GABA-producing bacteria have been shown to elicit higher GABA levels in the brain. The microbiota can also be involved with the conversion of neurotransmitters such as dopamine. The final section briefly capture the evidence of other brain health-relevant molecules derived from the intestinal microbiota, including Lipopolysaccharides, choline, lactate and B-Vitamins. This review yields a short and comprehensive summary highlighting the many ways the gut can influence brain function and health and could be of interest to those providing mental health support in light of gut function.
Abstract
The wealth of biotransformational capabilities encoded in the microbiome expose the host to an array of bioactive xenobiotic products. Several of these metabolites participate in the communication between the gastrointestinal tract and the central nervous system and have potential to modulate central physiological and pathological processes. This biochemical interplay can occur through various direct and indirect mechanisms. These include binding to host receptors in the brain, stimulation of the vagus nerve in the gut, alteration of central neurotransmission, and modulation of neuroinflammation. Here, the potential for short chain fatty acids, bile acids, neurotransmitters and other bioactive products of the microbiome to participate in the gut-brain axis will be reviewed.