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Nature Reviews. Cardiology Sep 2022Interest in epicardial adipose tissue (EAT) is growing rapidly, and research in this area appeals to a broad, multidisciplinary audience. EAT is unique in its anatomy... (Review)
Review
Interest in epicardial adipose tissue (EAT) is growing rapidly, and research in this area appeals to a broad, multidisciplinary audience. EAT is unique in its anatomy and unobstructed proximity to the heart and has a transcriptome and secretome very different from that of other fat depots. EAT has physiological and pathological properties that vary depending on its location. It can be highly protective for the adjacent myocardium through dynamic brown fat-like thermogenic function and harmful via paracrine or vasocrine secretion of pro-inflammatory and profibrotic cytokines. EAT is a modifiable risk factor that can be assessed with traditional and novel imaging techniques. Coronary and left atrial EAT are involved in the pathogenesis of coronary artery disease and atrial fibrillation, respectively, and it also contributes to the development and progression of heart failure. In addition, EAT might have a role in coronavirus disease 2019 (COVID-19)-related cardiac syndrome. EAT is a reliable potential therapeutic target for drugs with cardiovascular benefits such as glucagon-like peptide 1 receptor agonists and sodium-glucose co-transporter 2 inhibitors. This Review provides a comprehensive and up-to-date overview of the role of EAT in cardiovascular disease and highlights the translational nature of EAT research and its applications in contemporary cardiology.
Topics: Adipose Tissue; Atrial Fibrillation; COVID-19; Cardiology; Humans; Pericardium
PubMed: 35296869
DOI: 10.1038/s41569-022-00679-9 -
American Journal of Medical Genetics.... Mar 2020In 2014, an extensive review discussing the major steps of cardiac development focusing on growth, formation of primary and chamber myocardium and the development of the... (Review)
Review
In 2014, an extensive review discussing the major steps of cardiac development focusing on growth, formation of primary and chamber myocardium and the development of the cardiac electrical system, was published. Molecular genetic lineage analyses have since furthered our insight in the developmental origin of the various component parts of the heart, which currently can be unambiguously identified by their unique molecular phenotype. Moreover, genetic, molecular and cell biological analyses have driven insights into the mechanisms underlying the development of the different cardiac components. Here, we build on our previous review and provide an insight into the molecular mechanistic revelations that have forwarded the field of cardiac development. Despite the enormous advances in our knowledge over the last decade, the development of congenital cardiac malformations remains poorly understood. The challenge for the next decade will be to evaluate the different developmental processes using newly developed molecular genetic techniques to further unveil the gene regulatory networks operational during normal and abnormal cardiac development.
Topics: Gene Expression Regulation, Developmental; Gene Regulatory Networks; Heart; Heart Defects, Congenital; Heart Valves; Humans; Pericardium; Phenotype
PubMed: 32048790
DOI: 10.1002/ajmg.c.31778 -
Journal of the American College of... Dec 2020
Topics: Hospitalization; Humans; Morbidity; Pericarditis; Pericardium; Risk Factors
PubMed: 33243383
DOI: 10.1016/j.jacc.2020.10.018 -
Cold Spring Harbor Perspectives in... Feb 2020The epicardium, the outermost tissue layer that envelops all vertebrate hearts, plays a crucial role in cardiac development and regeneration and has been implicated in... (Review)
Review
The epicardium, the outermost tissue layer that envelops all vertebrate hearts, plays a crucial role in cardiac development and regeneration and has been implicated in potential strategies for cardiac repair. The heterogenous cell population that composes the epicardium originates primarily from a transient embryonic cell cluster known as the proepicardial organ (PE). Characterized by its high cellular plasticity, the epicardium contributes to both heart development and regeneration in two critical ways: as a source of progenitor cells and as a critical signaling hub. Despite this knowledge, there are many unanswered questions in the field of epicardial biology, the resolution of which will advance the understanding of cardiac development and repair. We review current knowledge in cross-species epicardial involvement, specifically in relation to lineage specification and differentiation during cardiac development.
Topics: Animals; Cell Differentiation; Pericardium; Regeneration; Stem Cells
PubMed: 31451510
DOI: 10.1101/cshperspect.a037192 -
The British Journal of Radiology Dec 2011Imaging of patients with suspected or known pericardial disease remains challenging. Echocardiography is the first-line investigation for pericardial disease but it has... (Review)
Review
Imaging of patients with suspected or known pericardial disease remains challenging. Echocardiography is the first-line investigation for pericardial disease but it has specific limitations in terms of its abilities to visualise the pericardium fully and to identify extracardiac pathology. Cardiac cross-sectional imaging by both MRI and CT has developed significantly and now has an important role in the investigation of pericardial disease. This article examines the appearances of both healthy and diseased pericardium using CT and MRI. The typical imaging findings across a wide range of conditions are illustrated and the roles of CT and MRI are reviewed. The relative merits and weaknesses of each modality are explored and the specific functional techniques that are available are introduced.
Topics: Heart Diseases; Heart Neoplasms; Humans; Magnetic Resonance Imaging; Mediastinal Cyst; Pericardial Effusion; Pericarditis; Pericarditis, Constrictive; Pericardium; Tomography, X-Ray Computed
PubMed: 22723538
DOI: 10.1259/bjr/16168253 -
Cardiovascular Therapeutics Oct 2011The pericardium is composed of visceral and parietal components. In view of the pericardium's simple structure, pathologic processes involving it are understandably few.... (Review)
Review
The pericardium is composed of visceral and parietal components. In view of the pericardium's simple structure, pathologic processes involving it are understandably few. However, despite a limited number of clinical syndromes, the pericardium is affected by virtually every category of disease, including infectious, neoplastic, immune-inflammatory, metabolic, iatrogenic, and traumatic. Thus, the recognition of pericardial heart disease remains challenging. Treatment of pericardial disease is also problematic in that there is a paucity of randomized, placebo-controlled trials from which appropriate therapy may be selected and important clinical decisions assisted. This article reviews pericarditis and its sequelae, pericardial effusions, cardiac tamponade and constrictive pericarditis.
Topics: Cardiac Surgical Procedures; Cardiac Tamponade; Cardiovascular Agents; Evidence-Based Medicine; Humans; Pericardial Effusion; Pericardiectomy; Pericardiocentesis; Pericarditis; Pericarditis, Constrictive; Pericardium; Treatment Outcome
PubMed: 20406240
DOI: 10.1111/j.1755-5922.2010.00151.x -
American Journal of Physiology. Heart... Feb 2022Obesity is associated with higher risks of cardiac arrhythmias. Although this may be partly explained by concurrent cardiometabolic ill-health, growing evidence suggests... (Review)
Review
Obesity is associated with higher risks of cardiac arrhythmias. Although this may be partly explained by concurrent cardiometabolic ill-health, growing evidence suggests that increasing adiposity independently confers risk for arrhythmias. Among fat depots, epicardial adipose tissue (EAT) exhibits a proinflammatory secretome and, given the lack of fascial separation, has been implicated as a transducer of inflammation to the underlying myocardium. The present review explores the mechanisms underpinning adverse electrophysiological remodeling as a consequence of EAT accumulation and the consequent inflammation. We first describe the physiological and pathophysiological function of EAT and its unique secretome and subsequently discuss the evidence for ionic channel and connexin expression modulation as well as fibrotic remodeling induced by cytokines and free fatty acids that are secreted by EAT. Finally, we highlight how weight reduction and regression of EAT volume may cause reverse remodeling to ameliorate arrhythmic risk.
Topics: Adipose Tissue; Animals; Arrhythmias, Cardiac; Cytokines; Humans; Ion Channels; Pericardium
PubMed: 34890279
DOI: 10.1152/ajpheart.00565.2021 -
Texas Heart Institute Journal 1999We studied the evolution of ventricles by macroscopic examination of the hearts of marine cartilaginous and bony fish, and by angiocardiography and gross examination of...
We studied the evolution of ventricles by macroscopic examination of the hearts of marine cartilaginous and bony fish, and by angiocardiography and gross examination of the hearts of air-breathing freshwater fish, frogs, turtles, snakes, and crocodiles. A right-sided, thin-walled ventricular lumen is seen in the fish, frog, turtle, and snake. In fish, there is external symmetry of the ventricle, internal asymmetry, and a thick-walled left ventricle with a small inlet chamber. In animals such as frogs, turtles, and snakes, the left ventricle exists as a small-cavitied contractile sponge. The high pressure generated by this spongy left ventricle, the direction of the jet, the ventriculoarterial orientation, and the bulbar spiral valve in the frog help to separate the systemic and pulmonary circulations. In the crocodile, the right aorta is connected to the left ventricle, and there is a complete interventricular septum and an improved left ventricular lumen when compared with turtles and snakes. The heart is housed in a rigid pericardial cavity in the shark, possibly to protect it from changing underwater pressure. The pericardial cavity in various species permits movements of the heart-which vary depending on the ventriculoarterial orientation and need for the ventricle to generate torque or spin on the ejected blood- that favor run-off into the appropriate arteries and their branches. In the lower species, it is not clear whether the spongy myocardium contributes to myocardial oxygenation. In human beings, spongy myocardium constitutes a rare form of congenital heart disease.
Topics: Adult; Alligators and Crocodiles; Anatomy, Comparative; Angiocardiography; Animals; Anura; Biological Evolution; Fishes; Heart Ventricles; Hemodynamics; Humans; Pericardium; Snakes; Turtles; Ventricular Function
PubMed: 10524737
DOI: No ID Found -
JACC. Cardiovascular Imaging Jun 2020Frequently, multimodality imaging is indispensable in the care of patients with pericardial disease. With cardiac magnetic resonance imaging, pericardial inflammation... (Review)
Review
Frequently, multimodality imaging is indispensable in the care of patients with pericardial disease. With cardiac magnetic resonance imaging, pericardial inflammation can be characterized as acute, subacute, or chronic. This spectrum of inflammation is variably associated with reduced compliance of the pericardium, which may result in constrictive pathophysiology, typically well-defined with echocardiography. This interplay between inflammation and hemodynamics is often optimally characterized with multimodality imaging and has redefined the approach of pericardiologists to diagnose, prognosticate, and tailor individual therapies.
Topics: Acute Disease; Asymptomatic Diseases; Cardiac Imaging Techniques; Chronic Disease; Clinical Decision-Making; Hemodynamics; Humans; Multimodal Imaging; Pericarditis; Pericardium; Predictive Value of Tests
PubMed: 31734199
DOI: 10.1016/j.jcmg.2019.08.027 -
Folia Histochemica Et Cytobiologica 2016Normal pericardium consists of an outer sac called fibrous pericardium and an inner one called serous pericardium. The two layers of serous pericardium: visceral and... (Review)
Review
Normal pericardium consists of an outer sac called fibrous pericardium and an inner one called serous pericardium. The two layers of serous pericardium: visceral and parietal are separated by the pericardial cavity, which contains 20 to 60 mL of the plasma ultrafiltrate. The pericardium acts as mechanical protection for the heart and big vessels, and a lubrication to reduce friction between the heart and the surrounding structures. A very important role in all aspects of pericardial functions is played by mesothelial cells. The mesothelial cells form a monolayer lining the serosal cavity and play an important role in antigen presentation, inflammation and tissue repair, coagulation and fibrinolysis. The two major types of mesothelial cells, flat or cuboid, differ substantially in their ultrastructure and, probably, functions. The latter display abundant microvilli, RER, Golgi dense bodies, membrane-bound vesicles and intracellular vacuoles containing electron-dense material described as dense bodies. The normal structure and functions of the pericardium determine correct healing after its injury as a result of surgery or microbial infection. The unfavorable resolution of acute or chronic pericarditis leads to the formation of adhesions between pericardial leaflets which may lead to serious complications.
Topics: Animals; Heart; Humans; Pericardium
PubMed: 27654013
DOI: 10.5603/FHC.a2016.0014