Polyphenol Metabolism and Personalized Nutrition in Menopause (PolyPause).

Overview

The study aims to evaluate the role of the gut microbiome and phageome in explaining interindividual variability in the metabolic response to polyphenol-rich nutraceuticals among menopausal women. Insights from this research will support the development of personalized nutrition strategies to improve quality of life and reduce cardiovascular disease (CVD) risk during menopause.

This trial aims to investigate the role of the gut microbiome and phageome in mediating interindividual variability in the metabolic response to polyphenol-rich plant extracts among postmenopausal women. Polyphenols are widely recognized for their potential benefits in cardiovascular health, cognitive function, and overall metabolic regulation. However, the magnitude and direction of their effects vary significantly between individuals. Mounting evidence suggests that the gut microbiota plays a critical role in the biotransformation of polyphenols into bioactive metabolites, giving rise to the so-called gut microbiota metabotypes (i.e., metabolic fingerprints of the gut microbiota that produce specific metabolites depending on the individual), thereby modulating the physiological effects of ingested polyphenols. A cohort of postmenopausal women will be studied at four timepoints in a randomized, double-blind, placebo-controlled, crossover trial. Participants will undergo a controlled dietary intervention with standardized polyphenol-rich plant extracts (pomegranate, soy, and resveratrol). The primary outcome will be a ≥15% change in serum oxidized LDL (oxLDL). At each timepoint, gut microbiome and phageome profiles will be characterized using shotgun metagenomic sequencing. TMAO, bile acids, and short-chain fatty acids will be determined by UPLC-QTOF-MS and GC-MS. Additional biomarkers of cardiovascular and metabolic health will be determined, including serum total cholesterol, LDLc, HDLc, and LPS-binding protein (LBP); fecal microbial enzymatic activities (β-glucuronidase and sulfatase); and serum neurotransmitters (GABA, dopamine, serotonin, melatonin, epinephrine, norepinephrine). The distribution of polyphenol metabotypes in this cohort will be assessed through circulating and urinary phenolic-derived metabolites. This will allow exploration of differential individual responses to polyphenol intake and their derived health effects. Untargeted urinary metabolomics will further explore potential changes in metabolites relevant to cardiovascular prevention. Quality of life will be evaluated using the validated Cervantes Scales, which include domains related to menopause-associated symptoms, cognitive issues, and overall health. The study is designed to integrate multi-omic data, combining microbial and phageomic composition with metabolomic and biochemical readouts, to identify patterns and predictors of individual responses to polyphenol intake. Statistical and bioinformatic analyses will focus on associations between microbiome/phageome signatures and metabolic outcomes, aiming to elucidate the mechanisms by which gut microbes and their viruses influence polyphenol biotransformation and subsequent systemic effects. This study therefore seeks to advance precision nutrition strategies for postmenopausal women. Insights gained may inform personalized dietary recommendations aimed at enhancing cardiovascular health, metabolic regulation, and overall quality of life during menopause. Moreover, the inclusion of the phageome represents a highly innovative and largely unexplored aspect of the study, offering new avenues for microbiota-targeted interventions. Overall, this research will contribute to understanding the complex interactions between diet, the gut ecosystem, and human metabolism, ultimately supporting the development of evidence-based, individualized nutritional strategies to reduce cardiovascular disease risk and improve health outcomes in the postmenopausal population.

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Outcomes