Search Results (272)

Resveratrol (RSV), a bioactive polyphenol, has emerged as a pleiotropic modulator within the integrated pathophysiology of cardiovascular disease (CVD) across the life course. Effective CVD management requires a transition from organ-centric frameworks to systems-level models that acknowledge dynamic crosstalk among metabolic, renal, and cardiovascular networks. Oxidative stress constitutes a central unifying axis in this interconnected biology, propagating cross-organ injury from early developmental stages onward. Mechanistically, RSV acts as a redox-responsive gene regulator by activating the Nrf2–ARE pathway, restoring nitric oxide bioavailability, and orchestrating SIRT1, AMPK, and NF-κB signaling to recalibrate mitochondrial function, inflammatory tone, and endothelial integrity. Within the Developmental Origins of Health and Disease (DOHaD) paradigm, RSV exhibits reprogramming potential that attenuates the intergenerational transmission of hypertension, kidney disease, and metabolic dysfunction. Although clinical translation is constrained by limited bioavailability and rapid metabolism, advanced delivery systems and artificial intelligence-enabled optimization strategies provide promising avenues to enhance therapeutic precision and scalability. This narrative review integrates mechanistic and translational insights to position RSV as a systems-oriented life-course intervention with sustained and intergenerational relevance in CVD. Full article

Maternal nutrition during critical windows of development plays a pivotal role in shaping long-term disease susceptibility, including cancer risk. This study investigated whether maternal exposure to lipotropes (methyl donor nutrients) during pregnancy and lactation modulates gene expression in 7,12-dimethylbenzanthracene (DMBA)-induced mammary tumors in adult female offspring. Timed-pregnant Sprague-Dawley rats were fed with either a control or lipotrope-supplemented diet, with or without vitamin B6. Female offspring were exposed to DMBA at puberty, and mammary tumors were evaluated histologically and molecularly. DMBA-induced tumors displayed ductal carcinoma in situ-like morphology and significant upregulation of fetal mammary developmental genes (Tbx2 and Tbx3), the tumorigenesis-associated gene Tp53, and key epigenetic regulators (Hdac1, Dnmt1, and Mthfr). Estrogen receptor 1 (Esr1) mRNA expression also showed a significant increase. Maternal lipotropes supplementation significantly attenuated the expression of these genes in offspring tumors. Collectively, these findings demonstrate that maternal methyl donor nutrition modulates tumor-associated gene expression patterns, potentially by limiting the reactivation of developmental and epigenetic pathways in adulthood. This study highlights maternal nutrition as a modifiable early-life factor with important implications for long-term health programming. Full article

Serotonin is a critical morphogen in early development, yet the mechanisms regulating its homeostasis in the preimplantation embryo remain unclear, particularly under conditions of maternal antidepressant exposure. Here, we investigated embryonic serotonergic autonomy using mouse models of pharmacological transport blockade (maternal fluoxetine treatment) and in vitro treatment with the monoamine oxidase inhibitor pargyline. We employed immunofluorescence, RT-qPCR, and live-cell imaging to assess metabolic flux, gene expression, and physiological health. We demonstrate that monoamine oxidase functions as a metabolic firewall, progressively maturing from zygote to blastocyst to degrade excess amines. Paradoxically, maternal serotonin transporter blockade triggered significant intracellular serotonin hyper-accumulation in blastocysts, associated with a trend toward a compensatory upregulation of the biosynthetic gene Ddc. While this serotonin overload did not compromise morphology, mitochondrial function, or pluripotency marker expression, it induced a robust epigenetic response. Excess serotonin promoted elevated H3Q5ser immunoreactivity in both nuclear and cytoplasmic compartments via a transglutaminase-dependent mechanism. These findings reveal that the preimplantation embryo possesses a resilient, autonomous serotonergic system capable of compensatory synthesis. However, environmental fluctuations are chemically recorded via transglutaminase-mediated serotonylation, representing an epigenetic mark that warrants further long-term study within the Developmental Origins of Health and Disease (DOHaD) framework. Full article

Nitric oxide (NO) functions as a master integrative regulator of cardiovascular–kidney–metabolic (CKM) homeostasis, yet it displays a profound Janus face, defined by concentration- and context-dependent roles in both health and disease. This narrative review examines NO signaling from a life-course perspective, beginning with fetal programming, during which the NO–asymmetric dimethylarginine (ADMA) axis orchestrates placental development and nephron endowment. Perturbations during this critical window—such as maternal ADMA elevation—can imprint a maladaptive trajectory toward adult-onset hypertension and chronic kidney disease. In adulthood, this initially silent dysregulation of NO signaling is amplified by Western dietary patterns and environmental pollutants, culminating in the clinical manifestation of the CKM triad. This pathological transition is driven by eNOS uncoupling and ADMA accumulation, which shift redox balance toward peroxynitrite formation and precipitate mitochondrial bioenergetic failure. Moreover, while constitutive NO production is essential for vascular homeostasis, pathological induction of inducible NOS generates excessive NO fluxes that promote insulin resistance and tissue injury. With advancing age, a progressive loss of NO resilience further exacerbates multi-organ vulnerability. To mitigate the cumulative burden of CKM disease, this review highlights developmental reprogramming strategies—such as perinatal L-citrulline supplementation and ADMA-lowering interventions—as interventions to restore physiological NO signaling. Integrating such early-life strategies with contemporary pharmacological therapies offers a coherent framework for maintaining NO bioavailability and extending health span across the life course. Full article

Background: Fetal Growth Retardation (FGR) is considered a risk factor for atherosclerosis and coronary artery disease in adulthood. Osteoprotegerin (OPG), a member of the tumor necrosis factor receptor superfamily, is reported to be elevated in atherosclerosis. Objectives: In this case-control study, we investigated whether FGR affects postnatal OPG serum concentrations and the possible association between OPG levels and aortic intima–media thickness (aIMT), an index of preclinical atherosclerosis. Methods: We studied 30 infants with FGR and 30 appropriate for gestational age (AGA) infants matched for gestational age and sex. Quantitative determination of plasma OPG was performed via enzyme immunoassay on the second (DOL2) and fifth (DOL5) day of life. aIMT was measured in the distal abdominal aorta and adjusted for aortic lumen diameter. Results: Infants with FGR had significantly higher OPG levels on both DOL2 and DOL5 as compared to controls (DOL2: 5.4 ± 1.0 pmol/L vs. 4.6 ± 1.0 pmol/L, p = 0.002 and DOL5: 5.1 ± 0.8 pmol/L vs. 3.9 ± 0.7 pmol/L, p < 0.001). Between DOL2 and DOL5, OPG concentrations did not change significantly in infants with FGR (difference 0.3 ± 0.2 pmol/L, p = 0.087) but decreased slightly in controls (difference 0.7 ± 0.3 pmol/L, p = 0.003). FGR was also associated with increased aIMT (0.11 ± 0.03 vs. 0.06 ± 0.02, p < 0.001). There was a positive correlation between OPG and aIMT on DOL2 (r = 0.494, p < 0.001), which became stronger on DOL5 (r = 0.791, p < 0.001). Conclusions: We report significantly increased concentrations of OPG in infants with FGR and a positive correlation with aIMT. Follow-up studies with repeat OPG and aIMT measurements may be indicated to evaluate whether these findings represent a permanent effect of FGR on the offspring. Full article

Melatonin, a multifunctional hormone with antioxidant, anti-inflammatory, and chronobiotic effects, is essential for a healthy pregnancy and fetal development. In the context of the Developmental Origins of Health and Disease (DOHaD), excessive oxidative stress acts as a key driver of maladaptive fetal programming, increasing lifelong susceptibility to cardiovascular, kidney, and metabolic (CKM) disorders. Importantly, most evidence derives from rodent models, and the protective effects of maternal melatonin supplementation appear partial and model-dependent rather than universal. Experimental studies indicate that maternal melatonin supplementation can prevent programmed hypertension, renal dysfunction, and metabolic derangements by restoring redox homeostasis, influencing epigenetic and nutrient-sensing pathways, and modulating the gut microbiome. Early clinical investigations in pregnancies complicated by preeclampsia or intrauterine growth restriction suggest that melatonin is well tolerated, improves placental function, and benefits neonatal outcomes. However, optimal dosing and long-term safety for offspring remain to be established. This review synthesizes mechanistic and translational evidence, framing melatonin as an integrative biological mediator with potential to guide preventive strategies and mitigate the intergenerational risk of CKM syndrome. Full article

Chronic kidney disease (CKD) represents a major global health burden, with growing evidence indicating that its origins extend back to early developmental stages. This narrative review integrates epidemiological, clinical, and mechanistic experimental evidence to position inflammation as a life-course driver of kidney vulnerability rather than a late-stage consequence. Inflammation has emerged as a central mechanistic link connecting adverse prenatal and postnatal exposures to lifelong kidney vulnerability. We highlight the translational potential by identifying pathways amenable to early-life interventions that could modify disease trajectory. During fetal development, maternal nutritional status, metabolic stress, and inflammatory exposures influence nephron endowment, immune maturation, and epigenetic regulation, thereby shaping long-term CKD risk. In childhood, early immune dysregulation and low-grade inflammation contribute to disease initiation, defining critical windows for preventive and renoprotective interventions that can be implemented in at-risk populations. In adulthood and aging, persistent activation of cytokine signaling, inflammasomes, oxidative stress pathways, autophagy–mitophagy imbalance, and cellular senescence drives progressive kidney injury, further amplified by gut microbiota dysbiosis and renin–angiotensin system interactions. Emerging life-course strategies include maternal nutrition optimization, early-life risk stratification, targeted anti-inflammatory and immunomodulatory therapies, and microbiota-directed interventions tailored to developmental stage and individual risk profile. By emphasizing inflammation as a developmentally programmed and preventable process, this review underscores opportunities for early-life and transgenerational CKD prevention, translating mechanistic insights into actionable strategies for preventive medicine and public health. Full article

Within the Developmental Origins of Health and Disease (DOHaD) framework, breast-feeding is a modifiable early postnatal exposure, but its long-term associations are difficult to separate from socioeconomic and family context. We conducted a structured literature search (PubMed/MEDLINE and Scopus; January 2015–December 2025) and prioritised large prospective/birth cohorts and genetic epidemiology studies reporting quantitative associations between breastfeeding in infancy (ever versus never, duration and, where available, exclusivity) and adult outcomes. Eighteen key primary studies were included in evidence tables across cardiometabolic, cancer, and neurocognitive domains. Overall, breastfeeding was associated with modestly lower all-cause and cardiovascular mortality, small reductions in cardiovascular disease and type 2 diabetes, and slightly more favour-able cardiometabolic profiles, including lower adiposity and higher HDL cholesterol. Where reported, effect sizes were generally small (e.g., hazard ratios typically close to 1.00), indicating limited clinical impact at the individual level but potential population relevance. Genetic analyses provide cautious support for a protective association with coronary outcomes, although lipid-mediated pathways appear to explain only a small proportion of the observed associations. Evidence for adult cancer outcomes remains mixed and largely inconclusive, while longer breastfeeding is associated with small ad-vantages in cognitive performance, educational attainment and selected psychological outcomes. Taken together, current evidence suggests that breastfeeding is associated with modestly more favourable adult cardiometabolic and neurobehavioural profiles, but its contribution to long-term health is small relative to the influence of later-life lifestyle and clinical risk factors and should therefore be interpreted cautiously. Full article

Background/Objectives: Circulating inflammatory cytokines and tissue sensitivity are both elevated following heat stress-induced intrauterine growth restriction (IUGR). Cytokines disrupt myoblast function and muscle growth, and thus we hypothesized that suppressing inflammatory tone in IUGR-born lambs by supplementing anti-inflammatory nutraceuticals would improve early postnatal growth. Methods: IUGR lambs produced by maternal heat stress were supplemented daily with 42 mg/kg oral omega-3 polyunsaturated fatty acid (ω-3 PUFA) Ca²⁺ salts or placebo from birth to 28 days of age. Results: By day 28, the 21% lighter bodyweights for IUGR lambs were fully resolved by ω-3 PUFA due to the complete recovery of average daily gain. Subcutaneous fat deposition and visceral organ growth were modestly diminished in IUGR-born lambs, but skeletal muscle mass was more markedly restricted. This coincided with 63% less muscle AdipoR2 but 27% greater circulating adiponectin. ω-3 PUFA reduced or eliminated deficits in subcutaneous fat, visceral organs, and five of the six individual muscles assessed, which corresponded with rescue of myoblast populations and AdipoR2 content. In turn, asymmetric growth restriction was resolved at one month of age. Conclusions: These findings show that targeting heightened inflammatory tone during the neonatal period in IUGR-born offspring can recover early growth in skeletal muscle and other soft tissues. Full article

Accumulating evidence recognizes cardiovascular–kidney–metabolic syndrome (CKMS) as a life-course disorder arising from dynamic and maladaptive interactions among the heart, vasculature, kidneys, liver, and pancreas. Beyond a late-onset clinical entity, CKMS susceptibility is increasingly understood to be programmed during critical developmental periods. Redox imbalance has emerged as a central integrative mechanism in this process, functioning as a mechanistic interface through which adverse early-life environments translate into persistent multi-organ vulnerability. Perturbation of the reactive oxygen species–nitric oxide axis during development disrupts organogenesis, vascular maturation, and metabolic regulation, resulting in enduring structural and functional alterations that predispose individuals to hypertension, metabolic dysfunction, and chronic kidney disease. These insights position redox biology not merely as a pathogenic mechanism but as a strategic entry point for precision intervention. Addressing the escalating global burden of CKMS requires a paradigm shift toward redox-driven precision medicine. This framework integrates biologically informed phenotyping, life-course–based risk stratification, early precision prevention through developmental reprogramming, and phenotype-guided therapeutics to stabilize interconnected organ networks. Transitioning from reactive, fragmented care to a proactive, systems-oriented approach offers a transformative opportunity to interrupt intergenerational risk transmission and achieve durable improvements in cardiovascular–kidney–metabolic health across the lifespan. Full article

Childhood malnutrition remains a pressing public health challenge in Europe, where stunting, wasting, and underweight coexist with rising rates of childhood overweight and obesity. This policy review provides a strategic roadmap for promoting healthy nutrition in early childhood by synthesizing WHO and EU guidance and proposing coordinated action across three time horizons. Short-term goals (1–3 years) include harmonizing food-based dietary guidelines, implementing universal nutrition screening in pediatric care, and strengthening breastfeeding-supportive environments. Mid-term priorities (3–7 years) focus on fiscal levers, such as sugar taxes and healthy food subsidies; reformulating children’s products; and embedding nutrition education within school curricula. Long-term strategies (7+ years) emphasize harmonized EU-wide monitoring systems, alignment of early-life nutrition with social protection policies, and sustained investment in research on the DOHaD. Through a unified, multisectoral strategy emphasizing early-life nutrition, equitable access to healthy foods, education, and robust regulation, Europe can effectively address the double burden of malnutrition and sustainably reduce childhood obesity. Full article

Maternal consumption of a high-fructose (HF) diet or exposure to microplastics (MPs) can each independently affect kidney development and increase the risk of hypertension in adult offspring, yet their combined impact remains poorly understood. Dysregulation of hydrogen sulfide (H₂S) signaling and alterations in gut microbiota are potential mediators of this programming. Pregnant rats received either standard chow or a 60% HF diet, with half of each group additionally exposed to sulfate-modified MPs (1 mg/L) with a 5 μm diameter throughout pregnancy and lactation. Male offspring were divided into four groups (n = 7–8 per group): control, HF, MP, and HF+MP. Maternal HF or MP exposure raised offspring blood pressure (BP), with additive effects when combined, and MP exposure caused renal injury. MP treatment also suppressed renal H₂S-generating enzymes and reduced H₂S production. Both HF and MP exposures altered gut microbial composition linked to BP regulation and induced metabolic changes in taurine/hypotaurine and sulfur pathways, suggesting impaired H₂S production. These results indicate that maternal HF and MP exposures interfere with H₂S signaling, gut microbiota, and metabolic programming, highlighting the H₂S signaling as a potential target to reduce long-term kidney and cardiometabolic risks. Full article

Introduction: Gestational hypoxia (GH) increases the risk of cardiovascular diseases by inducing oxidative stress and vascular dysfunction. This study investigates whether prenatal melatonin can mitigate these effects in guinea pigs. Methods: Pregnant guinea pigs were exposed to normoxia or hypoxia and treated with melatonin (1 mg/kg/day). Echocardiography, vascular reactivity, and molecular assays were used to assess cardiovascular structure, function, and redox balance in neonates. Results: GH reduced neonatal birth weight and altered left ventricular (LV) development, resulting in increased LV systolic function and aortic blood flow velocity. Melatonin treatment reversed these effects, restoring endothelial-dependent vasodilation and decreasing oxidative stress in the LV and thoracic aorta. Catalase antioxidant enzyme activity was elevated in melatonin-treated hypoxic neonates. Unexpectedly, melatonin treatment altered cardiac structure in normoxic pregnancies, increasing LV length and decreasing LV myocardial nuclei density. Conclusions: Prenatal melatonin partially modulates GH-induced endothelial dysfunction and oxidative stress, offering potential therapeutic value. However, its effects under normoxic conditions deserve caution, emphasizing the need for targeted use only in pregnancies with evident hypoxic and oxidative stress conditions. Full article

Individuals born after intrauterine growth restriction (IUGR) are at increased risk of long-term cardiovascular complications, including elevated blood pressure, endothelial dysfunction, and arterial stiffness. Endothelial progenitor cells (EPCs), particularly endothelial colony-forming cells (ECFCs), play a critical role in maintaining vascular homeostasis. Previously, Simoncini et al. observed that in a rat model of IUGR, six-month-old males exhibited elevated systolic blood pressure (SBP) and microvascular rarefaction compared with control (CTRL) rats. These vascular alterations were accompanied by reduced numbers and impaired function of bone marrow-derived ECFCs, which were associated with oxidative stress and stress-induced premature senescence (SIPS). In contrast, IUGR females of the same age and from the same litter did not exhibit higher SBP or microvascular rarefaction, raising the question of whether ECFC dysfunction in IUGR female rats can be present without vascular alterations. So, we investigated ECFCs isolated from six-month-old female IUGR offspring (maternal 9% casein diet) and CTRL females (23% casein diet). To complete the vascular assessment, we performed in vivo and in vitro investigations. No alteration in pulse wave velocity (measured by echo-Doppler) was observed; however, IUGR females showed decreased aortic collagen and increased elastin content compared with CTRL. Regarding ECFCs, those from IUGR females maintained their endothelial identity (CD31⁺/CD146⁺ ratio among viable CD45⁻ cells) but exhibited slight alterations in progenitor marker expression (CD34) compared with those of CTRL females. Functionally, IUGR-ECFCs displayed a delayed proliferation phase between 6 and 24 h, while their ability to form capillary-like structures remained unchanged, however their capacity to form capillary-like structures was preserved. Regarding the nitric oxide (NO) pathway, a biologically relevant trend toward reduced NO levels and decreased endothelial nitric oxide synthase expression was observed, whereas oxidative stress and SIPS markers remained unchanged. Overall, these findings indicate that ECFCs from six-month-old female IUGR rats exhibit only minor functional alterations, which may contribute to vascular protection against increase SBP, microvascular rarefaction, and arterial stiffness. Full article

Background/Objectives: Gestational exposure to a high-fat diet (HFD) reprograms hypothalamic orexigenic circuits prenatally. However, whether astrocytes, critical modulators of this system, are also imprinted by HFD in the fetal brain remains unknown. We investigated the impact of HFD on the prenatal neuroglial architecture of the lateral hypothalamic area (LHA). Methods: Female Wistar rats were fed a control or a 60% fat diet for 12 weeks. Upon reaching obesity (Lee index ≥ 310), dams were mated. Fetuses were harvested via cesarean section at term, and their brains were processed for immunohistochemistry and morphometry to assess cell proliferation, orexin neuron density, and astrocytic reactivity in the LHA. Results: HFD significantly increased cell proliferation and orexinergic neuron density, and induced early signs of astrocyte reactivity in the fetal LHA. These findings reveal that both neuronal and glial components of the LHA orexigenic axis are structurally reprogrammed before birth. Conclusions: This study provides the first evidence that HFD simultaneously alters neuronal and glial developmental trajectories in the fetal hypothalamus. The concurrent programming of astrocytes and orexigenic neurons suggests a prenatal origin for neuroinflammatory susceptibility, reframing obesity as a neurodevelopmental disorder shaped by early life nutritional environments. Full article