1.
The connection between POPs and Metabolic Syndrome
As the pioneer and global leader of Functional Medicine, the Institute of Functional Medicine leads and catalyses the efforts of a large and expanding Functional Medicine ecosystem, including providers, educators, payers, industry leaders, regulators, and influencers.
2023
Abstract
This IFM insight investigates the growing link between persistent organic pollutants (POPs) and increased rates of metabolic syndrome. There is evidence that POPs may also impair metabolic functioning of ‘normal weight’ individuals and not just those who are overweight or obese due to their potential impact on the gut microbiome. Underlying mechanisms are explored as well as the risks of eliminating POPs from the body. They review dietary approaches that may be targeted to support individuals with metabolic syndrome along with a high toxic burden in light of the ubiquity of POPs in our food environment.
2.
A Review of Dietary (Phyto)Nutrients for Glutathione Support.
Minich, DM, Brown, BI
Nutrients. 2019;11(9)
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Glutathione is made up of 3 amino acids (cysteine, glutamic acid and glycine) and plays important roles in the body, including oxidative stress reduction, supporting the immune system and contributing to detoxification processes. Evidence suggests that it is an important marker and target for treatment in many chronic, age-related diseases. This review article explores the evidence of nutritional strategies to improve glutathione status. The authors examine the evidence for supplementation of the precursors of glutathione as well as with various forms of supplemental glutathione itself, and the impacts on glutathione status and clinical impacts. Crucially, the review article provides information on dietary sources of precursors of glutathione and glutathione itself, which will provide Nutrition Practitioners with compelling information for use in clinic. Lean protein, brassica vegetables, polyphenol-rich fruits and vegetables, green tea, herbs and spices and omega-3 rich foods are all discussed in detail.
Abstract
Glutathione is a tripeptide that plays a pivotal role in critical physiological processes resulting in effects relevant to diverse disease pathophysiology such as maintenance of redox balance, reduction of oxidative stress, enhancement of metabolic detoxification, and regulation of immune system function. The diverse roles of glutathione in physiology are relevant to a considerable body of evidence suggesting that glutathione status may be an important biomarker and treatment target in various chronic, age-related diseases. Yet, proper personalized balance in the individual is key as well as a better understanding of antioxidants and redox balance. Optimizing glutathione levels has been proposed as a strategy for health promotion and disease prevention, although clear, causal relationships between glutathione status and disease risk or treatment remain to be clarified. Nonetheless, human clinical research suggests that nutritional interventions, including amino acids, vitamins, minerals, phytochemicals, and foods can have important effects on circulating glutathione which may translate to clinical benefit. Importantly, genetic variation is a modifier of glutathione status and influences response to nutritional factors that impact glutathione levels. This narrative review explores clinical evidence for nutritional strategies that could be used to improve glutathione status.
3.
Sorting out the Value of Cruciferous Sprouts as Sources of Bioactive Compounds for Nutrition and Health.
Abellán, Á, Domínguez-Perles, R, Moreno, DA, García-Viguera, C
Nutrients. 2019;11(2)
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Vegetable sprouts are naturally rich in nutrients and other beneficial compounds. The sprouts of cruciferous vegetables, such as broccoli, kale, radish and pak choi, stand out due to their high contents of glucosinolates and phenolic compounds. The aim of this review was to compile and update the available knowledge on the production, nutritional composition, and health benefits of cruciferous sprouts. A number of studies have found that compounds found in cruciferous sprouts have anti-cancer, anti-inflammatory, and antioxidant capacities. Consumption of cruciferous sprouts contributes to healthy glucose, insulin and fat levels in the blood, and may be beneficial for the treatment of some metabolic disorders, such as type 2 diabetes. There is evidence that compounds in cruciferous sprouts are a useful tool for enhancing phase II enzymes in the liver, and benefit levels of interleukine-6, C-reactive protein, and tumour necrosis factor-α, and inhibition of NF-κB, among others. The active compounds in these sprouts have an influence on several cardiovascular processes, potentially reducing the risk of several diseases. The lack of consistency between studies with regard to sampling schedules, doses, sample size, etc. means that it is not possible at this time to state the effective dose of sprouts or their active compounds needed in order to achieve health benefits. Further research is needed in this area.
Abstract
Edible sprouts with germinating seeds of a few days of age are naturally rich in nutrients and other bioactive compounds. Among them, the cruciferous (Brassicaceae) sprouts stand out due to their high contents of glucosinolates (GLSs) and phenolic compounds. In order to obtain sprouts enriched in these phytochemicals, elicitation is being increasing used as a sustainable practice. Besides, the evidence regarding the bioavailability and the biological activity of these compounds after their dietary intake has also attracted growing interest in recent years, supporting the intake of the natural food instead of enriched ingredients or extracts. Also, there is a growing interest regarding their uses, consumption, and applications for health and wellbeing, in different industrial sectors. In this context, the present review aims to compile and update the available knowledge on the fundamental aspects of production, enrichment in composition, and the benefits upon consumption of diverse edible cruciferous sprouts, which are sources of phenolic compounds and glucosinolates, as well as the evidence on their biological actions in diverse pathophysiological situations and the molecular pathways involved.
4.
Eat the rainbow: your guide to RED FOOD and recipes for delicious health
Leigh Stewart, Head of Atlas Biomed content, trained chef and avid fermenter of edible bacteria
2019
Abstract
Public health advocates want you to eat “five-a-day”, but let’s face it, that's a bit vague. Of course, they mean fruit and veg, because they’re full of fiber and mysterious phytochemicals (that means plant chemicals for all the non-sciencey readers). Today, we’re arguing the case of “eating the rainbow” from a scientific perspective, because it’s a great plan to reshape the communities of microbes in your gut, top up on fiber, and provide essential antioxidants to prevent damage to your body on a cellular level. And it’s going to be practical too. In this series, we’ll cover the five colours of the food rainbow, why they matter, what foods to choose, and even recipe ideas to make it exciting. And we're starting with red foods.
5.
Navy Beans Impact the Stool Metabolome and Metabolic Pathways for Colon Health in Cancer Survivors.
Baxter, BA, Oppel, RC, Ryan, EP
Nutrients. 2018;11(1)
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Colorectal cancer (CRC) is one of the leading cause of cancer-related death around the world. Emerging evidence supports that increased consumption of pulses / legumes, such as navy beans, can reduce risk. Consuming navy beans as part of one's diet has been previously shown to positively affect the relationship between a person's gut bacteria and their health status. This study looked at stool samples to assess the impact of navy bean consumption on health based on the by-products of metabolism generated by gut bacteria (metabolites). The study was a 4-week, randomised-controlled trial with overweight and obese CRC survivors and involved consumption of 1 meal and 1 snack daily. People in the intervention group ate 35g of cooked navy bean daily whereas those in the control group had 0g of navy beans. From amongst the hundreds of metabolites identified in both groups, there was a 5-fold increase in ophthalmate for navy bean consumers, which can indicate an increase in glutathione. Glutathione is an antioxidant and detoxifying substance produced in the human liver. It is involved in cancer control mechanisms such as detoxification of xenobiotics (toxins), antioxidant defense, proliferation, and apoptosis. Other interesting results include the metabolism of the amino acid lysine, which supports health immune function, and an increase in plant-based nutrients or phytochemicals in those who consumed navy bean vs the control group. These results are indicative of an acute response to increased navy bean intake, which merit further investigation for improving colonic health after long-term consumption.
Abstract
Colorectal cancer (CRC) is the third leading cause of cancer-related death in the United States and emerging evidence supports that increased consumption of legumes, such as navy beans, can reduce risk. Navy bean consumption was previously shown to modulate host and microbiome metabolism, and this investigation was performed to assess the impact on the human stool metabolome, which includes the presence of navy bean metabolites. This 4-week, randomized-controlled trial with overweight and obese CRC survivors involved consumption of 1 meal and 1 snack daily. The intervention contained 35 g of cooked navy bean or macronutrient matched meals and snacks with 0 g of navy beans for the control group (n = 18). There were 30 statistically significant metabolite differences in the stool of participants that consumed navy bean at day 28 compared to the participants' baseline (p ≤ 0.05) and 26 significantly different metabolites when compared to the control group. Of the 560 total metabolites identified from the cooked navy beans, there were 237 possible navy bean-derived metabolites that were identified in the stool of participants consuming navy beans, such as N-methylpipecolate, 2-aminoadipate, piperidine, and vanillate. The microbial metabolism of amino acids and fatty acids were also identified in stool after 4 weeks of navy bean intake including cadaverine, hydantoin-5 propionic acid, 4-hydroxyphenylacetate, and caprylate. The stool relative abundance of ophthalmate increased 5.25-fold for navy bean consumers that can indicate glutathione regulation, and involving cancer control mechanisms such as detoxification of xenobiotics, antioxidant defense, proliferation, and apoptosis. Metabolic pathways involving lysine, and phytochemicals were also modulated by navy bean intake in CRC survivors. These metabolites and metabolic pathways represent an acute response to increased navy bean intake, which merit further investigation for improving colonic health after long-term consumption.