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35 result(s) for "Vanoli, Emilio"
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Interplay Among Gut Microbiota-Derived TMAO, Autonomic Nervous System Dysfunction, and Heart Failure Progression
The gut microbiota is crucial for metabolic homeostasis and cardiovascular health. Dysbiosis triggers a gut–brain–heart axis dysfunction: vagal signaling promotes neuroinflammation and cerebral damage, which in turn impairs cardiac function. This bidirectional cycle is further exacerbated by reduced cerebral perfusion. Trimethylamine-N-oxide (TMAO), a metabolite of dietary choline and L-carnitine, acts as a primary mediator in this network. Elevated TMAO levels—resulting from bacterial conversion and hepatic oxidation—are linked to atherosclerosis and heart failure. Mechanistically, TMAO activates the NLRP3 inflammasome, inhibits the SIRT3-SOD2 pathway, and promotes platelet hyperreactivity. Furthermore, it modulates the autonomic nervous system, enhancing sympathetic activity and cardiac arrhythmias. Clinical evidence suggests TMAO is a potent predictor of mortality in HF. While current HF therapies focus on end-organ response (beta-blockers) or humoral pathways (ACE inhibitors), directly targeting the microbiota and TMAO offers a novel therapeutic frontier. Integrating TMAO assessment into risk models and utilizing advanced in vitro gut–brain models will be essential for developing personalized, groundbreaking cardiovascular interventions. Within this framework, the main aim of the present review is to describe how cardiac autonomic control can be directly modulated by the microbiota and its byproducts like TMAO. This latter is a leading target candidate for novel HF prevention and therapy interventions.
Trimethylamine-N-Oxide (TMAO) as a Rising-Star Metabolite: Implications for Human Health
The intestinal microbiota, hosting trillions of microorganisms that inhabit the gastrointestinal tract, functions as a symbiotic organism that plays a crucial role in regulating health by producing biologically active molecules that can enter systemic circulation. Among them, trimethylamine-N-oxide (TMAO), an organic compound derived from dietary sources and microbial metabolism, has emerged as a critical biomarker linking diet, the gut microbiota, and the host metabolism to various pathological conditions. This comprehensive review highlights TMAO’s biosynthesis, physiological functions, and clinical significance, focusing on its mechanistic contributions to cardiovascular and neurodegenerative diseases. Notably, TMAO-mediated pathways include endothelial dysfunction, inflammation via NLRP3 inflammasome activation, and cholesterol metabolism disruption, which collectively accelerate atherosclerosis and disease progression. Nonetheless, this work underscores the innovative potential of targeting TMAO through dietary, nutraceutical, and microbiota-modulating strategies to mitigate its pathological effects, marking a transformative approach in the prevention and management of TMAO-related disorders.
Risk of heart failure progression in patients with reduced ejection fraction: mechanisms and therapeutic options
Transition from stage C to stage D of heart failure (HF) represents an irreversible process toward end-stage disease. Crucial interventions to be adopted in the attempt to interfere with this process are represented by the identification of patients at high risk to develop HF progression and by an effective and prompt management. Markers of worse prognosis and disease progression are well established and include recurrence of HF decompensation, intolerance to the neurohormonal standard pharmacological treatment, and resistance to loop diuretics. In addition, both NT-proBNP and sympathetic nervous system (SNS) overdrive are strong predictors of adverse clinical outcome and allow to identify high-risk HF patients even in the presence of mild symptoms. To counteract the deleterious effects of the SNS activation, new strategies such as a new drug combining angiotensin receptor and neprilysin inhibition and baroreceptor stimulation therapy (BAT) have been investigated. Inability to properly counteract the SNS overdrive leads to acute HF decompensation by different mechanisms. The leading ones are represented by the progressive sodium and water retention with fluid overload and by the blood volume redistribution between splanchnic and non-splanchnic regions. The correct understanding of these mechanisms, together with the availability of new therapeutic options such as peritoneal ultrafiltration, represent the rationale but not infrequently overlooked therapeutic options to improve congestion management in HF patients.
CardioMEMS, the real progress in heart failure home monitoring
The burden of hospitalizations driven by exacerbation of acute heart failure remains unacceptably high. The associated use of hospital resources drives increasing patient, caregiver, and economic costs. Noninvasive telemedical systems investigated in randomized controlled trials have failed to demonstrate to reduce hospitalization rates probably because of the indirect (non-linear) relationship of the measured biological signals with the patient congestion status. Instead, there is increasing evidence that direct measure of intracardiac and pulmonary artery pressure can effectively guide heart failure management and reduce hospitalizations. Early studies adopting implantable hemodynamic monitors in the right heart unveiled the potential of pressure-based heart failure management, whereas subsequent investigations showed the powerful preemptive approach for heart failure exacerbations. One large randomized trial (CHAMPION) proved that a direct pulmonary pressure monitor system (CardioMEMS) substantially reduced heart failure hospitalizations in subjects randomized to active pulmonary pressure-guided management. The system monitoring safety and efficacy were also excellent. The study proved that early management in response to increased pulmonary pressure is able to provide the most effective therapeutic intervention to prevent heart failure exacerbations.
Use of dual-flow bioreactor to develop a simplified model of nervous-cardiovascular systems crosstalk: A preliminary assessment
Chronic conditions requiring long-term rehabilitation therapies, such as hypertension, stroke, or cancer, involve complex interactions between various systems/organs of the body and mutual influences, thus implicating a multiorgan approach. The dual-flow IVTech LiveBox2 bioreactor is a recently developed inter-connected dynamic cell culture model able to mimic organ crosstalk, since cells belonging to different organs can be connected and grown under flow conditions in a more physiological environment. This study aims to setup for the first time a 2-way connected culture of human neuroblastoma cells, SH-SY5Y, and Human Coronary Artery Smooth Muscle Cells, HCASMC through a dual-flow IVTech LiveBox2 bioreactor, in order to represent a simplified model of nervous-cardiovascular systems crosstalk, possibly relevant for the above-mentioned diseases. The system was tested by treating the cells with 10nM angiotensin II (AngII) inducing PKCβII/HuR/VEGF pathway activation, since AngII and PKCβII/HuR/VEGF pathway are relevant in cardiovascular and neuroscience research. Three different conditions were applied: 1- HCASMC and SH-SY5Y separately seeded in petri dishes (static condition); 2- the two cell lines separately seeded under flow (dynamic condition); 3- the two lines, seeded in dynamic conditions, connected, each maintaining its own medium, with a membrane as interface for biohumoral changes between the two mediums, and then treated. We detected that only in condition 3 there was a synergic AngII-dependent VEGF production in SH-SY5Y cells coupled to an AngII-dependent PKCβII/HuR/VEGF pathway activation in HCASMC, consistent with the observed physiological response in vivo . HCASMC response to AngII seems therefore to be generated by/derived from the reciprocal cell crosstalk under the dynamic inter-connection ensured by the dual flow LiveBox 2 bioreactor. This system can represent a useful tool for studying the crosstalk between organs, helpful for instance in rehabilitation research or when investigating chronic diseases; further, it offers the advantageous opportunity of cultivating each cell line in its own medium, thus mimicking, at least in part, distinct tissue milieu .
Clonal Hematopoiesis and Gut Microbiota-Derived TMAO as Candidate Amplifiers of Cardiovascular Inflammation: The CHIDT Hypothesis
Clonal hematopoiesis of indeterminate potential (CHIP) and the gut microbiota-derived metabolite trimethylamine N-oxide (TMAO) are both linked to NLRP3-mediated cardiovascular inflammation, but their interaction has not previously been explored. This work proposes the CHIDT axis (clonal hematopoiesis-dysbiosis-TMAO), a feed-forward mechanism in which TET2 loss-of-function CHIP- and TMAO-generating Gram-negative gut dysbiosis mutually enhance cardiovascular risk. The model proceeds in three nodes. CHIP-associated intestinal immune dysregulation promotes luminal expansion of Gammaproteobacteria, which produce both trimethylamine via CntA/CntB-mediated L-carnitine oxidation and ADP-heptose as an obligate LPS biosynthetic intermediate. TMAO amplifies NLRP3 inflammasome activation through the SIRT3 → SOD2 → mtROS pathway. The evidence base of the CHIDT model is strongest for TET2-CHIP; the proposed extension to DNMT3A-CHIP rests on indirect, associative data and requires dedicated experimental confirmation before it can be considered established. TXNIP cascade, with predicted disproportionate potency in macrophages epigenetically primed by TET2 haploinsufficiency. High concentrations of TMAO have also been shown to suppress TET2 expression in endothelial cells through CYTB promoter hypermethylation, inducing NLRP3-GSDMD-dependent pyroptosis, although it remains unclear whether physiological TMAO levels can trigger this effect. Concurrently, ADP-heptose activates the ALPK1-TIFA-NF-κB pathway in bone marrow progenitors, favoring the expansion of mutant hematopoietic stem and progenitor cells. The model identifies three potential therapeutic strategies: NLRP3 inhibition, microbial TMA lyase inhibition, and microbiome-targeted reduction in Gram-negative bacteria. None has been tested in CHIP carriers stratified by plasma TMAO. Further studies in preclinical models and human cohorts integrating CHIP genotyping and TMAO quantification are needed to validate the CHIDT axis as a target for precision cardiovascular prevention.
Current challenges in sudden cardiac death prevention
Ischemic heart disease and non-ischemic dilated cardiomyopathy are the most common causes of arrhythmic sudden cardiac death (SCD). Implantable cardioverter defibrillator (ICD) therapy is the only strategy that proved to be effective in preventing SCD in high-risk individuals while the role of antiarrhythmic drugs is limited to symptoms relief. Current guidelines recommend selecting candidates to ICD implantation based on etiology, symptoms of heart failure (NYHA class), and severely depressed left ventricular ejection fraction, but these parameters are neither sensitive nor specific. The review addresses the mechanisms of SCD in patients with heart failure of either ischemic or non-ischemic etiology, risk stratification, and strategies for prevention of SCD in the clinical practice (including optimization of heart failure therapy, avoidance of triggering factors, antiarrhythmic drugs, ICD therapy, early resuscitation, and public access defibrillators).
Benefits of Taurisolo in Diabetic Patients with Peripheral Artery Disease
Trimethyl-N-oxide (TMAO) has been linked to peripheral artery disease (PAD). TaurisoloⓇ is a natural, balanced phytocomplex containing resveratrol, quercetin, catechins, procianidins, gallic acid, and caffeic acid. Numerous studies have shown that TaurisoloⓇ reduces the damage of TMAO and exerts a protective effect on endothelial cells (ECs). The aim of this randomized, double-blind, single-center study was to evaluate the effects of TaurisoloⓇ on claudication in patients with PAD (Rutheford grade I, category II, Fontaine Classification: Stage IIA, American Medical Association Whole Person Impairment Classification: Class 0—WPI 0%) in two parallel groups of 31 patients. The primary outcomes were an increase in the pain-free walking distance and the ankle/brachial pressure index at the beginning and at the end of the treatment with Taurisolo. The secondary endpoint was the serum TMAO changes. The claudication distance improved by 14.1% in the Taurisolo group and by 2.0% in the placebo group, while the maximal distance increased by 15.8% and 0.6% only, respectively (both p < 0.05). The TMAO plasma levels decreased from 3.97 ± 2.13 micromole/L to 0.87 ± 0.48 (p < 0.0001) in the treated group. All these changes were highly significant both in univariate mixed models as well as in the adjusted model. Ultimately, TaurisoloⓇ might be an effective intervention to ameliorate intermittent claudication.
Percutaneous left atrial appendage occlusion pushing down pedunculated thrombus
Percutaneous left atrial appendage occlusion (LAAO) was chosen as the only viable approach in a 82-year-old man with permanent atrial fibrillation (AF), chronic systolic heart failure, advanced chronic kidney disease (eGFR ≤30 ml/min), and extensive intestinal vascular malformation not susceptible of treatment. According to applicable Guidelines, the presence of LAA thrombosis is generally considered an absolute contraindication to LAAO due to the risk of distal embolization. [...]the management of selected patients deemed at high risk of both thromboembolism and bleeding, may become challenging.
Autonomic Modulation With Baroreflex Activation Therapy in Heart Failure
Baroreflex activation therapy (BAT) produces a central inhibition of cardiac sympathetic outflow and, concomitantly, an increased cardiac vagal activity via a physiological reflex pathway. In a pilot study in 11 patients with NYHA class III heart failure (HF), BAT produced a persistent significant reduction of muscle sympathetic nerve activity over a 21-month follow-up and a dramatic decrease in the number and length of hospitalizations. In a multinational, prospective, randomized, parallel-controlled, clinical trial in 146 NYHA functional class III HF, BAT produced a significant N-terminal pro-brain natriuretic peptide reduction ( p  = 0.02). This was associated with a trend toward few in hospital days for HF. BAT might become a powerful tool to manipulate autonomic alterations of HF at their origin and thus profoundly affect advanced HF patient prognosis.