Search Results (72)

Sports-associated traumatic brain injury is emerging as an under-recognized driver of acute and chronic cardiovascular diseases. Larger population-based studies show that individuals with moderate-to-severe traumatic brain injury experience up to a two-fold excess risk of incident hypertension, coronary artery disease, myocardial infarction, and stroke that persists for at least a decade. Among former professional American-style football players, a higher lifetime concussion burden is uniquely related to a more atherogenic cardiometabolic profile and greater long-term stroke risk. Mechanistically, an acute “sympathetic storm” triggered by cerebral injury provokes catecholamine surges, endothelial dysfunction, and myocardial stunning, manifesting as neurogenic stunned myocardium or Takotsubo-like cardiomyopathy and malignant arrhythmias. Sub-acute to chronic phases are characterized by persistent autonomic imbalance, reflected by reduced heart-rate variability and impaired baroreflex sensitivity weeks to months after concussion, coupled with neuroinflammation, hypothalamic–pituitary–adrenal axis dysregulation, and lifestyle changes that accelerate atherosclerosis. The interplay of these pathways accounts for the elevated burden of cardiovascular disease observed long after neurological function has been restored. Despite robust evidence linking TBI to adverse cardiac outcomes, contemporary sports–cardiology risk stratification prioritizes hemodynamic load, genetics, and performance-enhancing substances, largely overlooking brain injury history. This review integrates epidemiological, clinical, and mechanistic data to (i) delineate acute neurocardiac complications secondary of sports-related traumatic brain injury, (ii) synthesize evidence for chronic cardiovascular risk, (iii) highlight emerging autonomic and inflammatory biomarkers, and (iv) propose surveillance and therapeutic strategies, ranging from heart-rate-variability-guided return-to-play decisions to aggressive cardiometabolic risk modification aiming to mitigate long-term morbidity in this athletic population. By framing sports-related traumatic brain injury as a modifiable cardiovascular risk factor, we aim to foster interdisciplinary collaboration among neurologists, cardiologists, and sports medicine practitioners, ultimately improving both neurological and cardiovascular outcomes across the athlete’s lifespan. Full article

Background: Cardiovascular diseases (CVD) are major contributors to global morbidity and mortality, and their association with cognitive impairment has gained increasing attention. Recent studies indicate that the prevalence of post-myocardial infarction (MI) cognitive impairment ranges from 22% to 37%, with attention being one of the most frequently affected domains. Moreover, novel approaches, such as normobaric hypoxic training in cardiac rehabilitation, show potential in improving both cardiovascular and cognitive outcomes. Aim: This narrative review aims to synthesize current evidence on the role of hypoxia in the development of cognitive dysfunction among patients with cardiac diseases, emphasizing shared mechanisms along the heart–brain axis. Methods: We performed a narrative search of PubMed, Scopus, and Web of Science databases using the keywords “hypoxia”, “cognitive impairment”, “myocardial infarction”, “heart failure”, and “CABG surgery”. We included original studies, reviews, and meta-analyses published between 2000 and up to the present in English. Priority was given to peer-reviewed human studies; animal models were included when providing mechanistic insights. Exclusion criteria included case reports, conference abstracts, and non-peer-reviewed sources. Narrative reviews, while useful for providing a broad synthesis, carry an inherent risk of selective bias. To minimize this limitation, independent screening of sources and discussions among multiple authors were conducted to ensure balanced inclusion of the most relevant and high-quality evidence. Results: Hypoxia contributes to cognitive decline through multiple pathophysiological pathways, including blood–brain barrier disruption, white matter degeneration, oxidative stress, and chronic neuroinflammation. The concept of “cardiogenic dementia”, although not yet formally classified, highlights cardiac-related contributions to cognitive impairment beyond classical vascular dementia. Clinical assessment tools such as the Stroop test, Trail Making Test (TMT), and Montreal Cognitive Assessment (MoCA) are useful in detecting subtle executive dysfunctions. Both pharmacological treatments (ACE inhibitors, ARBs) and innovative rehabilitation methods (including normobaric hypoxic training) may improve outcomes. Conclusions: Cognitive impairment in cardiac patients is common, clinically relevant, and often underdiagnosed. Routine cognitive screening after cardiac events and integration of cognitive rehabilitation into standard cardiology care are recommended. Future studies should incorporate cognitive endpoints into cardiovascular trials. Full article

Background: A subset of patients with chronic dyspepsia exhibits palpable upper abdominal hardness and systemic symptoms like headache, chest discomfort, neck/shoulder stiffness, fatigue, and depression. In traditional Korean medicine (TKM), this symptom complex is referred to as Damjeok syndrome (痰积症候群, DJS). Although DJS is frequently observed in TKM practice, it lacks a clear case definition and biological mechanism, limiting its integration in gastroenterology research and evidence-based practice. Clarifying its clinical and biological features is essential to understand its pathophysiology and clinical significance. Methods: This case–control study aimed to characterize DJS by comparing 16 female patients diagnosed with DJS and 15 age-matched healthy females as controls. A female-only cohort was selected to reflect the higher prevalence of chronic dyspepsia in women and reduce biological variability. Clinical characteristics and potential DJS-specific biomarkers were evaluated through complete blood count (CBC), serum biochemical tests, heart rate variability (HRV) for autonomic function, and plasma 5-hydroxyindoleacetic acid (5-HIAA), a serotonin metabolite linked to gastrointestinal motility and autonomic regulation. Results: The DJS group had a mean disease duration of 58.0 ± 46.2 months, with epigastric fullness and underlying abdominal hardness as primary complaints. Postprandial distress syndrome (PDS) was the most common (43.8%) dyspepsia subtype, often combined with epigastric pain syndrome (EPS). Extra-gastrointestinal symptoms such as headache/fatigue (87.5%) and anxiety/depression (81.3%) were highly prevalent. Neutrophil counts were significantly lower in the DJS group (p = 0.01), while other hematological or biochemical markers showed no differences (p > 0.1). HRV analysis revealed decreased parasympathetic activity (RMSSD and HF, p < 0.1), and plasma 5-HIAA levels were significantly elevated compared to healthy controls (p = 0.01). Conclusions: DJS aligns with functional gastrointestinal disorders (FGIDs), sharing psychosomatic symptoms and reduced parasympathetic activity, suggesting gut–brain axis dysregulation. However, distinct features like palpable upper abdominal hardness and elevated plasma 5-HIAA levels indicate that DJS may represent a unique subtype within the category of FGIDs. These findings highlight the need for larger, well-designed studies to further elucidate the pathophysiology of DJS. Full article

The heart–brain axis (HBA) is a dynamic system of reciprocal communication between the cardiovascular and central nervous system, incorporating neural, immunologic, molecular and hormonal pathways. The central autonomic network is described as a key regulator of cardiovascular activity and autonomic dysfunction as an important mechanism underlying various neurologic and cardiac disorders. Heart rate variability (HRV) is identified as the key biomarker of the axis reflecting autonomic nervous system balance. Increased understanding of its molecular mechanisms has led to the proposal of new therapeutic strategies focused on modulating heart–brain communication including β-blockers, vagus nerve stimulation, neurotrophin modulation, and nanoparticle-based approaches. The integration of wearables and artificial intelligence (AI) has allowed for real-time monitoring and innovative diagnostic and prognostic applications. The present narrative review summarizes current knowledge on the mechanisms comprising the heart–brain axis, their implication in neurologic and cardiac disorders, and their potential for developing novel therapies. It also highlights how advancements in wearable technology and AI systems are being integrated into clinical practice and transforming the landscape. Full article

The oral microbiota, long recognized for their role in local pathologies, are increasingly implicated in systemic disorders, particularly cardiovascular disease (CVD). This review focuses on emerging evidence linking oral dysbiosis to neuroglial activation and autonomic dysfunction as key mediators of cardiovascular pathology. Pathogen-associated molecular patterns, as well as gingipains and leukotoxin A from Porphyromonas gingivalis, Fusobacterium nucleatum, Treponema denticola, Aggregatibacter actinomycetemcomitans, etc., disrupt the blood–brain barrier, activate glial cells in autonomic centers, and amplify pro-inflammatory signaling. This glia driven sympathetic overactivity fosters hypertension, endothelial injury, and atherosclerosis. Crucially, sex hormones modulate these neuroimmune interactions, with estrogen and testosterone shaping microbial composition, glial reactivity, and cardiovascular outcomes in distinct ways. Female-specific factors such as early menarche, pregnancy, adverse pregnancy outcomes, and menopause exert profound influences on oral microbial ecology, systemic inflammation, and long-term CVD risk. By mapping this oral–brain–heart axis, this review highlights the dual role of oral microbial virulence factors and glial dynamics as mechanistic bridges linking periodontal disease to neurogenic cardiovascular regulation. Integrating salivary microbiome profiling with glial biomarkers [e.g., GFAP (Glial Fibrillary Acidic Protein) and sTREM2 (soluble Triggering Receptor Expressed on Myeloid cells 2)] offers promising avenues for sex-specific precision medicine. This framework not only reframes oral dysbiosis as a modifiable cardiovascular risk factor, but also charts a translational path toward gender tailored diagnostics and therapeutics to reduce the global CVD burden. Full article

The mineralocorticoid receptor (MR), traditionally associated with renal function, has also been identified in various extrarenal tissues, including the heart, brain, and dorsal root ganglion (DRG) neurons in rodents. Previous studies suggest a role for the MR in modulating peripheral nociception, with MR activation in rat DRG neurons by its endogenous ligand, aldosterone. This study aimed to determine whether MR, its protective enzyme 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2), its endogenous ligand aldosterone, and the aldosterone-synthesizing enzyme CYP11B2 are expressed in human DRG neurons and whether they colocalize with key pain-associated signaling molecules as potential targets for genomic regulation. To this end, we performed mRNA transcript profiling and immunofluorescence confocal microscopy on human and rat DRG tissues. We detected mRNA transcripts for MR, 11β-HSD2, and CYP11B2 in human DRG, alongside transcripts for key thermosensitive and nociceptive markers such as TRPV1, the TTX-resistant sodium channel Nav1.8, and the neuropeptides CGRP and substance P (Tac1). Immunofluorescence analysis revealed substantial colocalization of MR with 11β-HSD2 and CGRP, a marker of unmyelinated C-fibers and thinly myelinated Aδ-fibers, in human DRG. MR immunoreactivity was primarily restricted to small- and medium-diameter neurons, with lower expression in large neurons (>70 µm). Similarly, aldosterone colocalized with CYP11B2 and MR with nociceptive markers including TRPV1, Nav1.8, and TrkA in human DRG. Importantly, functional studies demonstrated that prolonged intrathecal inhibition of aldosterone synthesis within rat DRG neurons, using an aldosterone synthase inhibitor significantly downregulated pain-associated molecules and led to sustained attenuation of inflammation-induced hyperalgesia. Together, these findings identify a conserved peripheral MR signaling axis in humans and highlight its potential as a novel target for pain modulation therapies. Full article

Background: Borderline personality disorder (BPD) is a severe psychiatric condition characterised by emotional instability, impulsivity, interpersonal dysfunction, and self-injurious behaviours. Despite growing clinical interest, the neuropsychological mechanisms underlying these symptoms are still not fully understood. This review aims to summarise findings from neuroimaging, psychophysiological, and neurodevelopmental studies in order to clarify the neurobiological and physiological basis of BPD, with a particular focus on emotional dysregulation and implications for the treatment of adolescents. Methods: A narrative review was conducted, integrating results from longitudinal neurodevelopmental studies, functional and structural neuroimaging research (e.g. FMRI and PET), and psychophysiological assessments (e.g., heart rate variability and cortisol reactivity). Studies were selected based on their contribution to understanding the neural correlates of BPD symptom dimensions, particularly emotion dysregulation, impulsivity, interpersonal dysfunction, and self-harm. Results: Findings suggest that early reductions in amygdala volume, as early as age 13 predict later BPD symptoms. Hyperactivity of the amygdala, combined with hypoactivity in the prefrontal cortex, underlies deficits in emotion regulation. Orbitofrontal abnormalities correlate with impulsivity, while disruptions in the default mode network and oxytocin signaling are related to interpersonal dysfunction. Self-injurious behaviour appears to serve a neuropsychological function in regulating emotional pain and trauma-related arousal. This is linked to disruption of the hypothalamic-pituitary-adrenal (HPA) axis and structural brain alterations. The Unified Protocol for Adolescents (UP-A) was more effective to Mentalization-Based Therapy for Adolescents (MBT-A) at reducing emotional dysregulation compared, though challenges in treating identity disturbance and relational difficulties remain. Discussion: The reviewed evidence suggests that BPD has its in early neurodevelopmental vulnerability and is sustained by maladaptive neurophysiological processes. Emotional dysregulation emerges as a central transdiagnostic mechanism. Self-harm may serve as a strategy for regulating emotions in response to trauma-related neural dysregulation. These findings advocate for the integration of neuroscience into psychotherapeutic practice, including the application of neuromodulation techniques and psychophysiological monitoring. Conclusions: A comprehensive understanding of BPD requires a neuropsychologically informed framework. Personalised treatment approaches combining pharmacotherapy, brain-based interventions, and developmentally adapted psychotherapies—particularly DBT, psychodynamic therapy, and trauma-informed care—are essential. Future research should prioritise interdisciplinary, longitudinal studies to further bridge the gap between neurobiological findings and clinical innovation. Full article

Various cardiac pathologies such as ischemic/non-ischemic heart disease, valvular heart disease and genetic heart disease may impair cardiac function and lead to heart failure (HF). Each individual condition but also the common endpoint of HF may involve the brain and the immune system next to the heart. The interaction of these systems plays an important role, particularly in the pathogenesis and prognosis of HF, and stress plays a pivotal role in this interaction. The stress system (SS) of the body can be activated by any stress factor exceeding a predefined threshold and all body structures including brain, heart and immune system can be affected. The SS is also responsible for body homeostasis. Both acute and chronic stress may lead to the development of acute and chronic heart disease. Magnetic Resonance Imaging (MRI) is the ideal noninvasive tool without radiation that can provide valuable information about the effect of the SS in various systems/organs using targeted protocols. A holistic approach provided by MRI has the potential to improve our knowledge regarding stress mechanisms on the axis of heart–brain–immune system in HF that may impact effective, individualized treatment. In this review paper, we describe how MRI can be used as a noninvasive tool to assess the effect of stress on the brain–immune system-heart-axis, discussing current possibilities, limitations and future directions. Full article

Coronary artery disease (CAD) and mental health disorders, particularly depression and anxiety, exhibit a complex, bidirectional relationship that adversely influences clinical outcomes and mortality. Mental illnesses account for approximately 8 million deaths annually, while cardiovascular diseases, including CAD, contribute to about 17 million deaths, with CAD alone responsible for one-third of deaths among individuals aged ≥35 years. This review offers a structured synthesis of current knowledge focusing on the (1) epidemiology, emphasizing the reciprocal risk between CAD and psychiatric conditions; (2) pathophysiological insights, including inflammation, neurohormonal dysregulation, platelet hyperactivation, and shared genetic determinants; and (3) therapeutic approaches, encompassing pharmacological management, psychotherapeutic interventions, and integrated care models. Selective serotonin reuptake inhibitors (SSRIs) remain the pharmacologic agents of choice in patients with CAD and depression due to their favorable cardiac profile, while cognitive behavioral therapy (CBT) offers psychological benefit. However, evidence for mortality reduction remains limited. Emerging research highlights the importance of biomarker-driven care, gut–brain–heart axis modulation, and AI-enabled clinical integration. Full article

Shelter environments can be inherently stressful for dogs, a highly social species that forms strong attachment bond with humans. This study evaluated stress responses in 26 shelter dogs during routine veterinary examinations, analyzing behavioral scores alongside physiological and hormonal parameters, including heart rate, body temperature, cortisol (CRT), oxytocin (OXT), serotonin (5-HT), tryptophan (TRP), and interleukin-6 (IL-6). A significant negative correlation was observed between OXT and CRT (ρ = –0.540, p = 0.007), particularly in dogs exhibiting relaxed behavior. OXT was also negatively correlated with body temperature (ρ = –0.435, p = 0.034), supporting its potential role in modulating stress-induced hyperthermia. No significant associations were found between TRP, 5-HT, IL-6, or other physiological measures and behavioral scores. The absence of correlation between TRP and 5-HT may be due to blood–brain barrier regulation, while IL-6′s lack of association suggests further investigation is needed to clarify its role in canine stress responses. These findings highlight OXT’s possible buffering effect on the hypothalamic–pituitary–adrenal axis and suggest that behavioral assessment may offer a more sensitive measure of canine stress than hormonal or physiological parameters alone. Future studies with larger and more diverse samples are needed to confirm and expand upon these results. Full article

(1) Background: Heart failure (HF) and dementia are commonly associated with the elderly. A significant percentage of patients with HF are at high risk of cognitive decline and progression to dementia. Cognitive impairment is associated with both diseases. However, the molecules and mechanisms that affect the HF–dementia axis are poorly understood. (2) Objective: In this work, we aim to identify potential proteins that modulate HF and dementia. (3) Methods: We applied a pipeline using bioinformatic tools that robustly perform a literature search. (4) Results: Our results show that apolipoprotein E (APOE), c-reactive protein (CRP), interleukin 6 (IL6), renin (REN), and angiotensin-converting enzyme (ACE) proteins are important for maintaining homeostasis in the heart–brain axis. Additionally, deregulated levels of these proteins are associated with neuronal and cardiovascular diseases. (5) Conclusions: Our work highlights proteins that may help in understanding the pathophysiological relationship between HF and dementia. Moreover, these proteins may also be potential biomarkers and/or therapeutic targets. Full article

The intricate brain–heart interaction, essential for physiological balance, is largely governed by the autonomic nervous system (ANS). This bidirectional communication, involving both the sympathetic and parasympathetic branches of the ANS, is critical for maintaining cardiac homeostasis. Dysregulation of the ANS is a significant factor in cardiovascular diseases. Beyond the ANS, higher brain functions, particularly through interoceptive prediction, contribute to this dynamic interplay. The Cav1.3 L-type calcium channel, expressed in both the central nervous system (CNS) and the heart, is crucial for this interaction. Cav1.3, a key regulator of cellular excitability, exhibits genetic variations that are linked to both neurological and cardiac disorders, highlighting its pivotal role in the brain–heart axis. This review aims to delve into the under-explored role of Cav1.3 in brain–heart interaction, specifically examining how it modulates ANS activity and, consequently, the cardiac function. This will illuminate its significant role in the broader context of brain–heart interactions. Full article

In this review article, we discuss and explore the role of bacteria-derived hydrogen sulfide. Hydrogen sulfide is a signaling molecule produced endogenously that plays an important role in health and disease. It is also produced by the gut microbiome. In the setting of microbial disturbances leading to disruption of intestinal homeostasis (dysbiosis), the concentration of available hydrogen sulfide can also vary leading to pathologic sequelae. The brain–gut axis is the original studied paradigm of gut microbiome and host interaction. In recent years, our understanding of microbial and host interaction has expanded greatly to include specific pathways that have branched into their own axes. These axes share a principal concept of microbiota changes, intestinal permeability, and an inflammatory response, some of which are modulated by hydrogen sulfide (H₂S). In this review, we will discuss multiple axes including the gut–immune, gut–heart, and gut–endocrine axes. We will evaluate the role of H₂S in modulation of intestinal barrier, mucosal healing in intestinal inflammation and tumor genesis. We will also explore the role of H₂S in alpha-synuclein aggregation and ischemic injury. Finally, we will discuss H₂S in the setting of metabolic syndrome as int pertains to hypertension, atherosclerosis and glucose-like peptide-1 activity. Majority of studies that evaluate hydrogen sulfide focus on endogenous production; the role of this review is to examine the lesser-known bacteria-derived source of hydrogen sulfide in the progression of diseases as it relates to these axes. Full article

With an aging population, the incidence of both ischemic heart disease and strokes have become the most prevalent diseases globally. These diseases have similar risk factors, such as hypertension, diabetes, and smoking. However, there is also evidence of a relationship between the heart and the brain, referred to as the heart–brain axis. In this relationship, dysfunction of either organs can lead to injury to the other. There are several proposed physiologies to explain this relationship. These theories usually involve vascular, neuromodulatory, and inflammatory processes; however, few articles have explored and compared these different mechanisms of interaction between the heart and brain. A better understanding of the heart–brain axis can inform physicians of current and future treatment and preventive care options in heart and brain pathologies. The relationship between the brain and heart depends on inflammation, vascular anatomy and function, and neuromodulation. The pathways connecting these organs often become injured or dysfunctional when a major pathology, such as a myocardial infarction or stroke, occurs. This leads to long-term impacts on the patient’s overall health and risk for future disease. This study summarizes the current research involved in the heart–brain axis, relates these interactions to different diseases, and proposes future research in the field of neurocardiology. Conditions of the brain and heart are some of the most prevalent diseases. Through understanding the connection between these two organs, we can help inform patients and physicians of novel therapeutics for these pathologies. Full article

Emerging evidence underscores the pivotal role of the gut microbiota in regulating emotional and behavioral responses via the microbiota–gut–brain axis. This study explores associations between pediatric obstructive sleep apnea (OSA), emotional distress (ED), and gut microbiome alterations before and after OSA treatment. Sixty-six children diagnosed with OSA via polysomnography participated, undergoing adenotonsillectomy alongside routine educational sessions. ED was assessed using the OSA-18 questionnaire, categorizing participants into high ED (scores ≥ 11, 52%) and low ED (scores < 11, 48%) groups. Gut microbiome analysis revealed significant diversity differences, with high ED linked to a reduced Shannon index (p = 0.03) and increased beta diversity (p = 0.01). Three months post-treatment, significant improvements were observed in OSA symptoms, ED scores, and gut microbiome alpha diversity metrics among 55 participants (all p < 0.04). Moreover, changes in the relative abundances of Veillonella, Bifidobacterium, Flavonifractor, and Agathobacter, as well as ultra-low frequency power and low frequency power of sleep heart rate variability, were independently associated with ED score alterations. These findings underscore the gut microbiome’s critical role in the emotional and behavioral symptoms associated with pediatric OSA, suggesting that microbiome-targeted interventions could complement traditional treatments for ED reduction and emphasizing the need for further research. Full article