Assessment of Epicardial Fat Thickness in Children With Familial Dyslipidemia
- Conditions
- Dyslipidemia
- Interventions
- Diagnostic Test: echoCARDIOGRAPHY
- Registration Number
- NCT06101771
- Lead Sponsor
- Assiut University
- Brief Summary
Aim of the study: 1- Detect common types of familial dyslipidemia. 2- Significance and relationship between Epicardial fat thickness and familial dyslipidemia.
- Detailed Description
Dyslipidemias or dyslipoproteinemias are quantitative changes in total cholesterol concentration, respective fractions, or triglycerides in the plasma. Lipids, such as cholesterol or triglycerides, are absorbed from the intestines and are carried throughout the body via lipoproteins for energy, steroid production, or bile acid formation . Major contributors to these pathways are cholesterol, low-density lipoprotein cholesterol (LDL-C), triglycerides, and high-density lipoprotein (HDL). An imbalance of any of these factors, either from organic or nonorganic causes, can lead to dyslipidemia. Dyslipidemias can result from primary lipoprotein metabolism changes due to different genetic causes (primary dyslipidemias) or as a consequence of exogenous factors or other pathologies (secondary dyslipidemias). Primary dyslipidemia can be due to familial disorders as well. Autosomal dominant mutations cause most cases of familial hypercholesterolemia in LDL receptors, which causes an elevation in LDL-C levels. Other mutations in the cholesterol pathway have been identified but are less common. Several health behaviors can have effects and increase lipid levels. Examples include tobacco use, physical inactivity, nutrition, and obesity. Specifically, nutrition risk factors include the insufficient consumption of fruits, nuts/seeds, vegetables, or high consumption of saturated fats.
The heart and vessels are surrounded by layers of adipose tissue, which is a complex organ composed of adipocytes, stromal cells, macrophages, and a neuronal network, all nourished by a rich microcirculation . The layers of adipose tissue surrounding the heart can be subdivided into intra- and extrapericardial fat. Their thicknesses and volumes can be quantified by echocardiography and CT or magnetic resonance imaging, respectively.
The term extrapericardial fat defines thoracic adipose tissue external to the parietal pericardium. It originates from primitive thoracic mesenchymal cells and thus derives its blood supply from noncoronary sources. Intrapericardial fat is further subdivided into epicardial and pericardial fat. Anatomically, Epicardial and pericardial adipose tissues are clearly different.
Epicardial fat is located between the outer wall of the myocardium and the visceral layer of pericardium. Epicardial adipose tissue (EAT) is a component of visceral adiposity and mediates cardiac function and atherosclerosis via expression of several bioactive molecules.
EAT is a measure of the adipose tissue between the myocardium and visceral pericardium which can be visualized using transthoracic echocardiogram as a non-invasive assessment of EAT. Some studies have used EAT as a marker for metabolic syndrome; however, it does not have standard utility related to other cardiac syndromes. This fat layer buffers the coronary arteries from cardiac contraction and arterial pulse wave while providing the myocardium with necessary substrate through diffusion of free fatty acids. 4 When there is a surplus of energy, free fatty acids are readily converted into triglycerides and stored in epicardial adipocytes, increasing the volume of the epicardial adipose layer and serving as a triglyceride depot for the myocardium to draw from during periods of higher energy needs. Studies in adults suggest that increased EAT results in greater cytokine production in the fat directly surrounding the coronary vessels, including tumor necrosis factor-αas well as several interleukins. These cytokines contribute to atherosclerosis by increasing lipolysis, increasing inflammation, and causing endothelial dysfunction. Endothelial dysfunction coupled with migration of macrophages, basophils, and other cells further exacerbate plaque formation and eventually causes disruption in the structure of the intima and flow within the lumen.8,9Recent studies suggest that increased EAT is predictive of incident CVD in adults with T1D independent of traditional CVD risk factors such as BMI. Although the majority of studies examining EAT have been conducted in the adult population, EAT has been measured in pediatric studies of obesity and metabolic syndrome.
Recruitment & Eligibility
- Status
- NOT_YET_RECRUITING
- Sex
- All
- Target Recruitment
- 42
-
Normal weight children more than 1 month and till age of 18 years that attend Assiut University children Hospital with Clinical manifestation:
- Non-symptomatic accidentally discovered dyslipidemia.
- Steatorrhea.
- Fatty liver
1- Patients who had poor echo window : chest deformities, chronic lung disease, pericardial and/or pleural effusion on transthoracic echocardiography, and chronic kidney disease were not included in the study.
- Congenital heart diseases. 3. Children with liver diseases that cause 2ry dyslipidemia. 4. Children with Diabetes that cause 2ry dyslipidemia
Study & Design
- Study Type
- OBSERVATIONAL
- Study Design
- Not specified
- Arm && Interventions
Group Intervention Description dyslipidemia echoCARDIOGRAPHY Normal weight children more than 1 month and till age of 18 years that attend Assiut University children Hospital with Clinical manifestation: 1. Non-symptomatic accidentally discovered dyslipidemia. 2. Steatorrhea. 3. Fatty liver.
- Primary Outcome Measures
Name Time Method assessment epicardial fat thickness in children with familial dyslipidemia baseline All cases included in the study will be evaluated by:
1. - Fasting lipid profile: Total cholesterol, High-density lipoprotein (HDL) cholesterol, Low-density lipoprotein (LDL) cholesterol, Triglycerides (TG). (18)
2. - Transthoracic Echocardiography.
- Secondary Outcome Measures
Name Time Method