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Congenital heart defect

November 26, 2023

A congenital heart defect (CHD), also known as a congenital heart anomaly, congenital cardiovascular malformation, and congenital heart disease, is a defect in the structure of the heart or great vessels that is present at birth.[7] A congenital heart defect is classed as a cardiovascular disease.[10] Signs and symptoms depend on the specific type of defect.[3] Symptoms can vary from none to life-threatening.[7] When present, symptoms are variable and may include rapid breathing, bluish skin (cyanosis), poor weight gain, and feeling tired.[2] CHD does not cause chest pain.[2] Most congenital heart defects are not associated with other diseases.[3] A complication of CHD is heart failure.[2]

Congenital heart defect
Other namesCongenital heart anomaly, congenital heart disease
The normal structure of the heart (left) in comparison to two common locations for a ventricular septal defect (right), the most common form of congenital heart defect[1]
SpecialtyCardiology
SymptomsRapid breathing, bluish skin, poor weight gain, feeling tired[2]
ComplicationsHeart failure[2]
TypesCyanotic heart defects, non-cyanotic heart defects[3]
CausesOften unknown[4]
Risk factorsRubella infection during pregnancy, alcohol or tobacco, parents being closely related, poor nutritional status, taking antidepressant during pregnancy or obesity in the mother[3][5]
TreatmentNone, catheter based procedures, heart surgery, heart transplantation[6][3]
PrognosisGenerally good (with treatment)[7]
Frequency48.9 million (2015)[8]
Deaths303,300 (2015)[9]

Congenital heart defects are the most common birth defect.[3][11] In 2015, they were present in 48.9 million people globally.[8] They affect between 4 and 75 per 1,000 live births, depending upon how they are diagnosed.[3][12] In about 6 to 19 per 1,000 they cause a moderate to severe degree of problems.[12] Congenital heart defects are the leading cause of birth defect-related deaths:[3] in 2015, they resulted in 303,300 deaths, down from 366,000 deaths in 1990.[9][13] The cause of a congenital heart defect is often unknown.[4] Risk factors include certain infections during pregnancy such as rubella, use of certain medications or drugs such as alcohol or tobacco, parents being closely related, or poor nutritional status or obesity in the mother.[3][5] Having a parent with a congenital heart defect is also a risk factor.[12] A number of genetic conditions are associated with heart defects, including Down syndrome, Turner syndrome, and Marfan syndrome.[3] Congenital heart defects are divided into two main groups: cyanotic heart defects and non-cyanotic heart defects, depending on whether the child has the potential to turn bluish in color.[3] The defects may involve the interior walls of the heart, the heart valves, or the large blood vessels that lead to and from the heart.[7]

Congenital heart defects are partly preventable through rubella vaccination, the adding of iodine to salt, and the adding of folic acid to certain food products.[3] Some defects do not need treatment.[7] Others may be effectively treated with catheter based procedures or heart surgery.[6] Occasionally a number of operations may be needed,[6] or a heart transplant may be required.[6] With appropriate treatment, outcomes are generally good, even with complex problems.[7]

Signs and symptoms edit

 
Digital clubbing with cyanotic nail beds in an adult with tetralogy of Fallot

Signs and symptoms are related to type and severity of the heart defect. Symptoms frequently present early in life, but it is possible for some CHDs to go undetected throughout life.[14] Some children have no signs while others may exhibit shortness of breath, cyanosis, fainting,[15] heart murmur, under-development of limbs and muscles, poor feeding or growth, or respiratory infections. Congenital heart defects cause abnormal heart structure resulting in production of certain sounds called heart murmur. These can sometimes be detected by auscultation; however, not all heart murmurs are caused by congenital heart defects.[citation needed]

Associated conditions edit

Congenital heart defects are associated with an increased incidence of seven other specific medical conditions, together being called the VACTERL association:[citation needed]

Ventricular septal defect (VSD), atrial septal defects, and tetralogy of Fallot are the most common congenital heart defects seen in the VACTERL association. Less common defects in the association are truncus arteriosus and transposition of the great arteries.[citation needed]

Causes edit

The cause of congenital heart disease may be genetic, environmental, or a combination of both.[16]

Genetic edit

Genetic mutations, often sporadic, represent the largest known cause of congenital heart defects.[17] They are described in the table below.

Genetic lesions Attributable percent Examples Primary genetic testing method
Aneuploidies 5–8%[16] Survivable autosomal trisomies (chromosomes 13, 18, 21), chromosome X monosomy (Turner syndrome) Karyotyping
Copy number variants 10–12%[18] 22q11.2 deletion/duplication (velocardiofacial/DiGeorge syndrome), 1q21.1 deletion/duplication, 8p23.1 deletion/duplication, 15q11.2 deletion (Burnside-Butler syndrome) Array comparative genomic hybridization (also known as chromosomal microarray analysis)
Inherited protein-coding single nucleotide variant (SNV) or small insertion/deletion (indel) 3–5%[19] Holt–Oram syndrome, Noonan syndrome, Alagille syndrome Gene panel
De novo protein-coding SNV or indel ~10%[20][17] Mutations in genes highly expressed during heart development Whole exome sequencing

Molecular pathways edit

The genes regulating the complex developmental sequence have only been partly elucidated. Some genes are associated with specific defects. A number of genes have been associated with cardiac manifestations. Mutations of a heart muscle protein, α-myosin heavy chain (MYH6) are associated with atrial septal defects.[21] Several proteins that interact with MYH6 are also associated with cardiac defects. The transcription factor GATA4 forms a complex with the TBX5 which interacts with MYH6. Another factor, the homeobox (developmental) gene, NKX2-5 also interacts with MYH6. Mutations of all these proteins are associated with both atrial and ventricular septal defects; In addition, NKX2-5 is associated with defects in the electrical conduction of the heart and TBX5 is related to the Holt–Oram syndrome which includes electrical conduction defects and abnormalities of the upper limb. The Wnt signaling co-factors BCL9, BCL9L and PYGO might be part of these molecular pathways, as when their genes are mutated, this causes phenotypes similar to the features present in Holt-Oram syndrome.[22] Another T-box gene, TBX1, is involved in velo-cardio-facial syndrome DiGeorge syndrome, the most common deletion which has extensive symptoms including defects of the cardiac outflow tract including tetralogy of Fallot.[23]

Examples of gene products and associated features
MYH6 GATA4 NKX2-5 TBX5 TBX1
Locus 14q11.2-q13 8p23.1-p22 5q34 12q24.1 22q11.2
Syndrome Holt–Oram DiGeorge
Atrial septal defects
Ventricular septal defects
Electrical conduction abnormalities
Outflow tract abnormalities
Non-cardiac manifestations[24] Upper limb abnormalities Small or absent thymus
Small or absent parathyroids
Facial abnormalities

The notch signaling pathway, a regulatory mechanism for cell growth and differentiation, plays broad roles in several aspects of cardiac development. Notch elements are involved in determination of the right and left sides of the body plan, so the directional folding of the heart tube can be impacted. Notch signaling is involved early in the formation of the endocardial cushions and continues to be active as the develop into the septa and valves. It is also involved in the development of the ventricular wall and the connection of the outflow tract to the great vessels. Mutations in the gene for one of the notch ligands, Jagged1, are identified in the majority of examined cases of arteriohepatic dysplasia (Alagille syndrome), characterized by defects of the great vessels (pulmonary artery stenosis), heart (tetralogy of Fallot in 13% of cases), liver, eyes, face, and bones. Though less than 1% of all cases, where no defects are found in the Jagged1 gene, defects are found in Notch2 gene. In 10% of cases, no mutation is found in either gene. For another member of the gene family, mutations in the Notch1 gene are associated with bicuspid aortic valve, a valve with two leaflets instead of three. Notch1 is also associated with calcification of the aortic valve, the third most common cause of heart disease in adults.[25][26]

Mutations of a cell regulatory mechanism, the Ras/MAPK pathway are responsible for a variety of syndromes, including Noonan syndrome, LEOPARD syndrome, Costello syndrome and cardiofaciocutaneous syndrome in which there is cardiac involvement.[27] While the conditions listed are known genetic causes, there are likely many other genes which are more subtle. It is known that the risk for congenital heart defects is higher when there is a close relative with one.[28]

Environmental edit

Known environmental factors include certain infections during pregnancy such as rubella, drugs (alcohol, hydantoin, lithium and thalidomide) and maternal illness (diabetes mellitus, phenylketonuria, and systemic lupus erythematosus).[29] Alcohol exposure in the father also appears to increase the risk of congenital heart defects.[30]

Being overweight or obese increases the risk of congenital heart disease.[5] Additionally, as maternal obesity increases, the risk of heart defects also increases.[31] A distinct physiological mechanism has not been identified to explain the link between maternal obesity and CHD, but both pre-pregnancy folate deficiency and diabetes have been implicated in some studies.[32]

Mechanism edit

Main article: Heart development

There is a complex sequence of events that result in a well formed heart at birth and disruption of any portion may result in a defect.[28] The orderly timing of cell growth, cell migration, and programmed cell death ("apoptosis") has been studied extensively and the genes that control the process are being elucidated.[23] Around day 15 of development, the cells that will become the heart exist in two horseshoe shaped bands of the middle tissue layer (mesoderm),[23] and some cells migrate from a portion of the outer layer (ectoderm), the neural crest, which is the source of a variety of cells found throughout the body. On day 19 of development, a pair of vascular elements, the "endocardial tubes", form. The tubes fuse when cells between then undergo programmed death and cells from the first heart field migrate to the tube, and form a ring of heart cells (myocytes) around it by day 21. On day 22, the heart begins to beat and by day 24, blood is circulating.[33]

At day 22, the circulatory system is bilaterally symmetrical with paired vessels on each side and the heart consisting of a simple tube located in the midline of the body layout. The portions that will become the atria and will be located closest to the head are the most distant from the head. From days 23 through 28, the heart tube folds and twists, with the future ventricles moving left of center (the ultimate location of the heart) and the atria moving towards the head.[33]

On day 28, areas of tissue in the heart tube begin to expand inwards; after about two weeks, these expansions, the membranous "septum primum" and the muscular "endocardial cushions", fuse to form the four chambers of the heart. A failure to fuse properly will result in a defect that may allow blood to leak between chambers. After this happens, cells that have migrated from the neural crest begin to divide the bulbus cordis, the main outflow tract is divided in two by the growth a spiraling septum, becoming the great vessels—the ascending segment of the aorta and the pulmonary trunk. If the separation is incomplete, the result is a "persistent truncus arteriosus". The vessels may be reversed ("transposition of the great vessels"). The two halves of the split tract must migrate into the correct positions over the appropriate ventricles. A failure may result in some blood flowing into the wrong vessel (e.g.overriding aorta). The four-chambered heart and the great vessels have features required for fetal growth. The lungs are unexpanded and cannot accommodate the full circulatory volume. Two structures exist to shunt blood flow away from the lungs. Cells in part of the septum primum die creating a hole while muscle cells, the "septum secundum", grow along the right atrial side the septum primum, except for one region, leaving a gap through which blood can pass from the right artium to the left atrium, the foramen ovale. A small vessel, the ductus arteriosus allows blood from the pulmonary artery to pass to the aorta.[33]

Changes at birth edit

The ductus arteriosus stays open because of circulating factors including prostaglandins. The foramen ovale stays open because of the flow of blood from the right atrium to the left atrium. As the lungs expand, blood flows easily through the lungs and the membranous portion of the foramen ovale (the septum primum) flops over the muscular portion (the septum secundum). If the closure is incomplete, the result is a patent foramen ovale. The two flaps may fuse, but many adults have a foramen ovale that stays closed only because of the pressure difference between the atria.[33]

Theories edit

Rokitansky (1875) explained congenital heart defects as breaks in heart development at various ontogenesis stages.[34] Spitzer (1923) treats them as returns to one of the phylogenesis stages.[35] Krimski (1963), synthesizing two previous points of view, considered congenital heart diseases as a stop of development at the certain stage of ontogenesis, corresponding to this or that stage of the phylogenesis.[36] Hence these theories can explain feminine and neutral types of defects only.[citation needed]

Diagnosis edit

Many congenital heart defects can be diagnosed prenatally by fetal echocardiography. This is a test which can be done during the second trimester of pregnancy, when the woman is about 18–24 weeks pregnant.[37][38] It can be an abdominal ultrasound or transvaginal ultrasound.[citation needed]

If a baby is born with cyanotic heart disease, the diagnosis is usually made shortly after birth due to the blue colour of their skin (called cyanosis).[38]

If a baby is born with a septal defect or an obstruction defect, often their symptoms are only noticeable after several months or sometimes even after many years.[38]

Classification edit

A number of classification systems exist for congenital heart defects. In 2000 the International Congenital Heart Surgery Nomenclature was developed to provide a generic classification system.[39]

Hypoplasia edit

Main articles: Hypoplastic left heart syndrome and Hypoplastic right heart syndrome

Hypoplasia can affect the heart, typically resulting in the underdevelopment of the right ventricle or the left ventricle. This causes only one side of the heart to be capable of pumping blood to the body and lungs effectively. Hypoplasia of the heart is rare but is the most serious form of CHD. It is called hypoplastic left heart syndrome when it affects the left side of the heart and hypoplastic right heart syndrome when it affects the right side of the heart. In both conditions, the presence of a patent ductus arteriosus (and, when hypoplasia affects the right side of the heart, a patent foramen ovale) is vital to the infant's ability to survive until emergency heart surgery can be performed, since without these pathways blood cannot circulate to the body (or lungs, depending on which side of the heart is defective). Hypoplasia of the heart is generally a cyanotic heart defect.[40]

Obstructive defects edit

Main article: Ventricular outflow tract obstruction

Obstructive defects occur when heart valves, arteries, or veins are abnormally narrow or blocked. Common defects include pulmonic stenosis, aortic stenosis, and coarctation of the aorta, with other types such as bicuspid aortic valve stenosis and subaortic stenosis being comparatively rare. Any narrowing or blockage can cause heart enlargement or hypertension.[41]

Septal defects edit

The septum is a wall of tissue which separates the left heart from the right heart. Defects in the interatrial septum or the interventricular septum allow blood to flow from the left side of the heart to the right, reducing the heart's efficiency.[41] Ventricular septal defects are collectively the most common type of CHD,[42] although approximately 30% of adults have a type of atrial septal defect called probe patent foramen ovale.[43]

Cyanotic defects edit

Cyanotic heart defects are called such because they result in cyanosis , a bluish-grey discoloration of the skin due to a lack of oxygen in the body. Such defects include persistent truncus arteriosus, total anomalous pulmonary venous connection, tetralogy of Fallot, transposition of the great vessels, and tricuspid atresia.[41]

Defects edit

Some conditions affect the great vessels or other vessels in close proximity to the heart, but not the heart itself, but are often classified as congenital heart defects.[citation needed]

Some constellations of multiple defects are commonly found together.[citation needed]

Treatment edit

CHD may require surgery and medications. Medications include diuretics, which aid the body in eliminating water, salts, and digoxin for strengthening the contraction of the heart. This slows the heartbeat and removes some fluid from tissues. Some defects require surgical procedures to restore circulation back to normal and in some cases, multiple surgeries are needed.[citation needed]

Interventional cardiology now offers minimally invasive alternatives to surgery for some patients. The Melody Transcatheter Pulmonary Valve (TPV), approved in Europe in 2006 and in the U.S. in 2010 under a Humanitarian Device Exemption (HDE), is designed to treat congenital heart disease patients with a dysfunctional conduit in their right ventricular outflow tract (RVOT). The RVOT is the connection between the heart and lungs; once blood reaches the lungs, it is enriched with oxygen before being pumped to the rest of the body. Transcatheter pulmonary valve technology provides a less-invasive means to extend the life of a failed RVOT conduit and is designed to allow physicians to deliver a replacement pulmonary valve via a catheter through the patient's blood vessels.[citation needed]

Many people require lifelong specialized cardiac care, first with a pediatric cardiologist and later with an adult congenital cardiologist. There are more than 1.8 million adults living with congenital heart defects.[44]

Mental health edit

Supporting people with chronic diseases such as congenital heart disease with emotional problems and mental health is a treatment consideration.[45] Since some people with congenital heart disease have a lower quality of life that is related to their condition, some people may struggle with finding a job, engaging in physical exercise, with their fertility, and clinical depression as examples. An estimated 31% of adults with congenital heart disease also have mood disorders.[45] Psychotherapy may be helpful for treating some people who have congenital heart disease and depression, however further research is needed to determine the best way to reduce depression including the length of treatments required for an improvement, type of psychotherapy treatments, and how the psychotherapy sessions are delivered.[45]

Epidemiology edit

 
Congenital heart anomalies deaths per million persons in 2012
  0-8
  9-12
  13-23
  24-31
  32-39
  40-47
  48-50
  51-56
  57-63
  64-124

Heart defects are among the most common birth defect, occurring in 1% of live births (2–3% including bicuspid aortic valve).[11] In 2013, 34.3 million people had CHD. In 2010, they resulted in 223,000 deaths, down from 278,000 deaths in 1990.[46]

For congenital heart defects that arise without a family history (de novo), the recurrence risk in offspring is 3–5%.[47][48] This risk is higher in left ventricular outflow tract obstructions, heterotaxy, and atrioventricular septal defects.[47][48]

Terminology edit

Congenital heart defects are known by a number of names including congenital heart anomaly, congenital heart disease, heart defects, and congenital cardiovascular malformations.[49]

See also edit

References edit

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  48. ^ a b Canobbio MM, Warnes CA, Aboulhosn J, Connolly HM, Khanna A, Koos BJ, et al. (February 2017). "Management of Pregnancy in Patients With Complex Congenital Heart Disease: A Scientific Statement for Healthcare Professionals From the American Heart Association". Circulation. 135 (8): e50–e87. doi:10.1161/CIR.0000000000000458. PMID 28082385.
  49. ^ "Other Names for Congenital Heart Defects". July 1, 2011. from the original on 27 July 2015. Retrieved 10 August 2015.

External links edit

  • Congenital heart defect at Curlie
  • information for parents.

November 26, 2023
congenital, heart, defect, congenital, heart, defect, also, known, congenital, heart, anomaly, congenital, cardiovascular, malformation, congenital, heart, disease, defect, structure, heart, great, vessels, that, present, birth, congenital, heart, defect, clas. A congenital heart defect CHD also known as a congenital heart anomaly congenital cardiovascular malformation and congenital heart disease is a defect in the structure of the heart or great vessels that is present at birth 7 A congenital heart defect is classed as a cardiovascular disease 10 Signs and symptoms depend on the specific type of defect 3 Symptoms can vary from none to life threatening 7 When present symptoms are variable and may include rapid breathing bluish skin cyanosis poor weight gain and feeling tired 2 CHD does not cause chest pain 2 Most congenital heart defects are not associated with other diseases 3 A complication of CHD is heart failure 2 Congenital heart defectOther namesCongenital heart anomaly congenital heart diseaseThe normal structure of the heart left in comparison to two common locations for a ventricular septal defect right the most common form of congenital heart defect 1 SpecialtyCardiologySymptomsRapid breathing bluish skin poor weight gain feeling tired 2 ComplicationsHeart failure 2 TypesCyanotic heart defects non cyanotic heart defects 3 CausesOften unknown 4 Risk factorsRubella infection during pregnancy alcohol or tobacco parents being closely related poor nutritional status taking antidepressant during pregnancy or obesity in the mother 3 5 TreatmentNone catheter based procedures heart surgery heart transplantation 6 3 PrognosisGenerally good with treatment 7 Frequency48 9 million 2015 8 Deaths303 300 2015 9 Congenital heart defects are the most common birth defect 3 11 In 2015 they were present in 48 9 million people globally 8 They affect between 4 and 75 per 1 000 live births depending upon how they are diagnosed 3 12 In about 6 to 19 per 1 000 they cause a moderate to severe degree of problems 12 Congenital heart defects are the leading cause of birth defect related deaths 3 in 2015 they resulted in 303 300 deaths down from 366 000 deaths in 1990 9 13 The cause of a congenital heart defect is often unknown 4 Risk factors include certain infections during pregnancy such as rubella use of certain medications or drugs such as alcohol or tobacco parents being closely related or poor nutritional status or obesity in the mother 3 5 Having a parent with a congenital heart defect is also a risk factor 12 A number of genetic conditions are associated with heart defects including Down syndrome Turner syndrome and Marfan syndrome 3 Congenital heart defects are divided into two main groups cyanotic heart defects and non cyanotic heart defects depending on whether the child has the potential to turn bluish in color 3 The defects may involve the interior walls of the heart the heart valves or the large blood vessels that lead to and from the heart 7 Congenital heart defects are partly preventable through rubella vaccination the adding of iodine to salt and the adding of folic acid to certain food products 3 Some defects do not need treatment 7 Others may be effectively treated with catheter based procedures or heart surgery 6 Occasionally a number of operations may be needed 6 or a heart transplant may be required 6 With appropriate treatment outcomes are generally good even with complex problems 7 Contents 1 Signs and symptoms 1 1 Associated conditions 2 Causes 2 1 Genetic 2 1 1 Molecular pathways 2 2 Environmental 3 Mechanism 3 1 Changes at birth 3 2 Theories 4 Diagnosis 4 1 Classification 4 1 1 Hypoplasia 4 1 2 Obstructive defects 4 1 3 Septal defects 4 1 4 Cyanotic defects 4 1 5 Defects 5 Treatment 5 1 Mental health 6 Epidemiology 7 Terminology 8 See also 9 References 10 External linksSigns and symptoms edit nbsp Digital clubbing with cyanotic nail beds in an adult with tetralogy of FallotSigns and symptoms are related to type and severity of the heart defect Symptoms frequently present early in life but it is possible for some CHDs to go undetected throughout life 14 Some children have no signs while others may exhibit shortness of breath cyanosis fainting 15 heart murmur under development of limbs and muscles poor feeding or growth or respiratory infections Congenital heart defects cause abnormal heart structure resulting in production of certain sounds called heart murmur These can sometimes be detected by auscultation however not all heart murmurs are caused by congenital heart defects citation needed Associated conditions edit Congenital heart defects are associated with an increased incidence of seven other specific medical conditions together being called the VACTERL association citation needed V Vertebral anomalies A Anal atresia C Cardiovascular anomalies T Tracheoesophageal fistula E Esophageal atresia R Renal Kidney and or radial anomalies L Limb defectsVentricular septal defect VSD atrial septal defects and tetralogy of Fallot are the most common congenital heart defects seen in the VACTERL association Less common defects in the association are truncus arteriosus and transposition of the great arteries citation needed Causes editThe cause of congenital heart disease may be genetic environmental or a combination of both 16 Genetic edit Genetic mutations often sporadic represent the largest known cause of congenital heart defects 17 They are described in the table below Genetic lesions Attributable percent Examples Primary genetic testing methodAneuploidies 5 8 16 Survivable autosomal trisomies chromosomes 13 18 21 chromosome X monosomy Turner syndrome KaryotypingCopy number variants 10 12 18 22q11 2 deletion duplication velocardiofacial DiGeorge syndrome 1q21 1 deletion duplication 8p23 1 deletion duplication 15q11 2 deletion Burnside Butler syndrome Array comparative genomic hybridization also known as chromosomal microarray analysis Inherited protein coding single nucleotide variant SNV or small insertion deletion indel 3 5 19 Holt Oram syndrome Noonan syndrome Alagille syndrome Gene panelDe novo protein coding SNV or indel 10 20 17 Mutations in genes highly expressed during heart development Whole exome sequencingMolecular pathways edit The genes regulating the complex developmental sequence have only been partly elucidated Some genes are associated with specific defects A number of genes have been associated with cardiac manifestations Mutations of a heart muscle protein a myosin heavy chain MYH6 are associated with atrial septal defects 21 Several proteins that interact with MYH6 are also associated with cardiac defects The transcription factor GATA4 forms a complex with the TBX5 which interacts with MYH6 Another factor the homeobox developmental gene NKX2 5 also interacts with MYH6 Mutations of all these proteins are associated with both atrial and ventricular septal defects In addition NKX2 5 is associated with defects in the electrical conduction of the heart and TBX5 is related to the Holt Oram syndrome which includes electrical conduction defects and abnormalities of the upper limb The Wnt signaling co factors BCL9 BCL9L and PYGO might be part of these molecular pathways as when their genes are mutated this causes phenotypes similar to the features present in Holt Oram syndrome 22 Another T box gene TBX1 is involved in velo cardio facial syndrome DiGeorge syndrome the most common deletion which has extensive symptoms including defects of the cardiac outflow tract including tetralogy of Fallot 23 Examples of gene products and associated features MYH6 GATA4 NKX2 5 TBX5 TBX1Locus 14q11 2 q13 8p23 1 p22 5q34 12q24 1 22q11 2Syndrome Holt Oram DiGeorgeAtrial septal defects Ventricular septal defects Electrical conduction abnormalities Outflow tract abnormalities Non cardiac manifestations 24 Upper limb abnormalities Small or absent thymus Small or absent parathyroids Facial abnormalitiesThe notch signaling pathway a regulatory mechanism for cell growth and differentiation plays broad roles in several aspects of cardiac development Notch elements are involved in determination of the right and left sides of the body plan so the directional folding of the heart tube can be impacted Notch signaling is involved early in the formation of the endocardial cushions and continues to be active as the develop into the septa and valves It is also involved in the development of the ventricular wall and the connection of the outflow tract to the great vessels Mutations in the gene for one of the notch ligands Jagged1 are identified in the majority of examined cases of arteriohepatic dysplasia Alagille syndrome characterized by defects of the great vessels pulmonary artery stenosis heart tetralogy of Fallot in 13 of cases liver eyes face and bones Though less than 1 of all cases where no defects are found in the Jagged1 gene defects are found in Notch2 gene In 10 of cases no mutation is found in either gene For another member of the gene family mutations in the Notch1 gene are associated with bicuspid aortic valve a valve with two leaflets instead of three Notch1 is also associated with calcification of the aortic valve the third most common cause of heart disease in adults 25 26 Mutations of a cell regulatory mechanism the Ras MAPK pathway are responsible for a variety of syndromes including Noonan syndrome LEOPARD syndrome Costello syndrome and cardiofaciocutaneous syndrome in which there is cardiac involvement 27 While the conditions listed are known genetic causes there are likely many other genes which are more subtle It is known that the risk for congenital heart defects is higher when there is a close relative with one 28 Environmental edit Known environmental factors include certain infections during pregnancy such as rubella drugs alcohol hydantoin lithium and thalidomide and maternal illness diabetes mellitus phenylketonuria and systemic lupus erythematosus 29 Alcohol exposure in the father also appears to increase the risk of congenital heart defects 30 Being overweight or obese increases the risk of congenital heart disease 5 Additionally as maternal obesity increases the risk of heart defects also increases 31 A distinct physiological mechanism has not been identified to explain the link between maternal obesity and CHD but both pre pregnancy folate deficiency and diabetes have been implicated in some studies 32 Mechanism editMain article Heart development There is a complex sequence of events that result in a well formed heart at birth and disruption of any portion may result in a defect 28 The orderly timing of cell growth cell migration and programmed cell death apoptosis has been studied extensively and the genes that control the process are being elucidated 23 Around day 15 of development the cells that will become the heart exist in two horseshoe shaped bands of the middle tissue layer mesoderm 23 and some cells migrate from a portion of the outer layer ectoderm the neural crest which is the source of a variety of cells found throughout the body On day 19 of development a pair of vascular elements the endocardial tubes form The tubes fuse when cells between then undergo programmed death and cells from the first heart field migrate to the tube and form a ring of heart cells myocytes around it by day 21 On day 22 the heart begins to beat and by day 24 blood is circulating 33 At day 22 the circulatory system is bilaterally symmetrical with paired vessels on each side and the heart consisting of a simple tube located in the midline of the body layout The portions that will become the atria and will be located closest to the head are the most distant from the head From days 23 through 28 the heart tube folds and twists with the future ventricles moving left of center the ultimate location of the heart and the atria moving towards the head 33 On day 28 areas of tissue in the heart tube begin to expand inwards after about two weeks these expansions the membranous septum primum and the muscular endocardial cushions fuse to form the four chambers of the heart A failure to fuse properly will result in a defect that may allow blood to leak between chambers After this happens cells that have migrated from the neural crest begin to divide the bulbus cordis the main outflow tract is divided in two by the growth a spiraling septum becoming the great vessels the ascending segment of the aorta and the pulmonary trunk If the separation is incomplete the result is a persistent truncus arteriosus The vessels may be reversed transposition of the great vessels The two halves of the split tract must migrate into the correct positions over the appropriate ventricles A failure may result in some blood flowing into the wrong vessel e g overriding aorta The four chambered heart and the great vessels have features required for fetal growth The lungs are unexpanded and cannot accommodate the full circulatory volume Two structures exist to shunt blood flow away from the lungs Cells in part of the septum primum die creating a hole while muscle cells the septum secundum grow along the right atrial side the septum primum except for one region leaving a gap through which blood can pass from the right artium to the left atrium the foramen ovale A small vessel the ductus arteriosus allows blood from the pulmonary artery to pass to the aorta 33 Changes at birth edit The ductus arteriosus stays open because of circulating factors including prostaglandins The foramen ovale stays open because of the flow of blood from the right atrium to the left atrium As the lungs expand blood flows easily through the lungs and the membranous portion of the foramen ovale the septum primum flops over the muscular portion the septum secundum If the closure is incomplete the result is a patent foramen ovale The two flaps may fuse but many adults have a foramen ovale that stays closed only because of the pressure difference between the atria 33 Theories edit Rokitansky 1875 explained congenital heart defects as breaks in heart development at various ontogenesis stages 34 Spitzer 1923 treats them as returns to one of the phylogenesis stages 35 Krimski 1963 synthesizing two previous points of view considered congenital heart diseases as a stop of development at the certain stage of ontogenesis corresponding to this or that stage of the phylogenesis 36 Hence these theories can explain feminine and neutral types of defects only citation needed Diagnosis editMany congenital heart defects can be diagnosed prenatally by fetal echocardiography This is a test which can be done during the second trimester of pregnancy when the woman is about 18 24 weeks pregnant 37 38 It can be an abdominal ultrasound or transvaginal ultrasound citation needed If a baby is born with cyanotic heart disease the diagnosis is usually made shortly after birth due to the blue colour of their skin called cyanosis 38 If a baby is born with a septal defect or an obstruction defect often their symptoms are only noticeable after several months or sometimes even after many years 38 Classification edit A number of classification systems exist for congenital heart defects In 2000 the International Congenital Heart Surgery Nomenclature was developed to provide a generic classification system 39 Hypoplasia edit Main articles Hypoplastic left heart syndrome and Hypoplastic right heart syndrome Hypoplasia can affect the heart typically resulting in the underdevelopment of the right ventricle or the left ventricle This causes only one side of the heart to be capable of pumping blood to the body and lungs effectively Hypoplasia of the heart is rare but is the most serious form of CHD It is called hypoplastic left heart syndrome when it affects the left side of the heart and hypoplastic right heart syndrome when it affects the right side of the heart In both conditions the presence of a patent ductus arteriosus and when hypoplasia affects the right side of the heart a patent foramen ovale is vital to the infant s ability to survive until emergency heart surgery can be performed since without these pathways blood cannot circulate to the body or lungs depending on which side of the heart is defective Hypoplasia of the heart is generally a cyanotic heart defect 40 Obstructive defects edit Main article Ventricular outflow tract obstruction Obstructive defects occur when heart valves arteries or veins are abnormally narrow or blocked Common defects include pulmonic stenosis aortic stenosis and coarctation of the aorta with other types such as bicuspid aortic valve stenosis and subaortic stenosis being comparatively rare Any narrowing or blockage can cause heart enlargement or hypertension 41 Septal defects edit The septum is a wall of tissue which separates the left heart from the right heart Defects in the interatrial septum or the interventricular septum allow blood to flow from the left side of the heart to the right reducing the heart s efficiency 41 Ventricular septal defects are collectively the most common type of CHD 42 although approximately 30 of adults have a type of atrial septal defect called probe patent foramen ovale 43 Cyanotic defects edit Cyanotic heart defects are called such because they result in cyanosis a bluish grey discoloration of the skin due to a lack of oxygen in the body Such defects include persistent truncus arteriosus total anomalous pulmonary venous connection tetralogy of Fallot transposition of the great vessels and tricuspid atresia 41 Defects edit Aortic stenosis Arrhythmogenic right ventricular cardiomyopathy Atrial septal defect ASD Atrioventricular septal defect AVSD Bicuspid aortic valve Cardiomyopathy Complete heart block CHB Dextrocardia Double inlet left ventricle DILV Double outlet right ventricle DORV Ebstein s anomaly Early Repolarization Syndrome Holmes heart Hypoplastic left heart syndrome HLHS Hypoplastic right heart syndrome HRHS Mitral stenosis Myocardial bridge Persistent truncus arteriosus Pulmonary atresia Pulmonary stenosis Rhabdomyomas Tumors of the Heart Transposition of the great vessels dextro Transposition of the great arteries d TGA levo Transposition of the great arteries l TGA Tricuspid atresia Ventricular septal defect VSD Wolff Parkinson White syndrome WPW Some conditions affect the great vessels or other vessels in close proximity to the heart but not the heart itself but are often classified as congenital heart defects citation needed Coarctation of the aorta CoA Double aortic arch aberrant subclavian artery and other malformations of the great arteries Interrupted aortic arch IAA Patent ductus arteriosus PDA Scimitar syndrome SS Partial anomalous pulmonary venous connection PAPVC Total anomalous pulmonary venous connection TAPVC Some constellations of multiple defects are commonly found together citation needed Tetralogy of Fallot ToF Pentalogy of Cantrell Shone s syndrome Shone s complex Shone s anomalyTreatment editCHD may require surgery and medications Medications include diuretics which aid the body in eliminating water salts and digoxin for strengthening the contraction of the heart This slows the heartbeat and removes some fluid from tissues Some defects require surgical procedures to restore circulation back to normal and in some cases multiple surgeries are needed citation needed Interventional cardiology now offers minimally invasive alternatives to surgery for some patients The Melody Transcatheter Pulmonary Valve TPV approved in Europe in 2006 and in the U S in 2010 under a Humanitarian Device Exemption HDE is designed to treat congenital heart disease patients with a dysfunctional conduit in their right ventricular outflow tract RVOT The RVOT is the connection between the heart and lungs once blood reaches the lungs it is enriched with oxygen before being pumped to the rest of the body Transcatheter pulmonary valve technology provides a less invasive means to extend the life of a failed RVOT conduit and is designed to allow physicians to deliver a replacement pulmonary valve via a catheter through the patient s blood vessels citation needed Many people require lifelong specialized cardiac care first with a pediatric cardiologist and later with an adult congenital cardiologist There are more than 1 8 million adults living with congenital heart defects 44 Mental health edit Supporting people with chronic diseases such as congenital heart disease with emotional problems and mental health is a treatment consideration 45 Since some people with congenital heart disease have a lower quality of life that is related to their condition some people may struggle with finding a job engaging in physical exercise with their fertility and clinical depression as examples An estimated 31 of adults with congenital heart disease also have mood disorders 45 Psychotherapy may be helpful for treating some people who have congenital heart disease and depression however further research is needed to determine the best way to reduce depression including the length of treatments required for an improvement type of psychotherapy treatments and how the psychotherapy sessions are delivered 45 Epidemiology edit nbsp Congenital heart anomalies deaths per million persons in 2012 0 8 9 12 13 23 24 31 32 39 40 47 48 50 51 56 57 63 64 124Heart defects are among the most common birth defect occurring in 1 of live births 2 3 including bicuspid aortic valve 11 In 2013 34 3 million people had CHD In 2010 they resulted in 223 000 deaths down from 278 000 deaths in 1990 46 For congenital heart defects that arise without a family history de novo the recurrence risk in offspring is 3 5 47 48 This risk is higher in left ventricular outflow tract obstructions heterotaxy and atrioventricular septal defects 47 48 Terminology editCongenital heart defects are known by a number of names including congenital heart anomaly congenital heart disease heart defects and congenital cardiovascular malformations 49 See also editCongenital Heart Surgeons Society Congenital heart blockReferences edit Hoffman JI Kaplan S June 2002 The incidence of congenital heart disease Journal of the American College of Cardiology 39 12 1890 900 doi 10 1016 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Heart Archived from the original on 20 June 2010 Retrieved 30 July 2010 Ventricular Septal Defect eMedicine Health Archived from the original on 18 July 2010 Retrieved 30 July 2010 Circulatory Changes at Birth University of California at Berkeley Archived from the original on 18 July 2010 Retrieved 30 July 2010 Adult Congenital Heart Association Adult Congenital Heart Association Archived from the original on 20 June 2010 Retrieved 30 July 2010 a b c Leo Donato Giuseppe Islam Umar Lotto Robyn R Lotto Attilio Lane Deirdre A 2023 10 03 Cochrane Heart Group ed Psychological interventions for depression in adolescent and adult congenital heart disease Cochrane Database of Systematic Reviews 2023 10 doi 10 1002 14651858 CD004372 pub3 PMC 10546482 PMID 37787122 Lozano R Naghavi M Foreman K Lim S Shibuya K Aboyans V et al December 2012 Global and regional mortality from 235 causes of death for 20 age groups in 1990 and 2010 a systematic analysis for the Global Burden of Disease Study 2010 Lancet 380 9859 2095 128 doi 10 1016 S0140 6736 12 61728 0 hdl 10536 DRO DU 30050819 PMID 23245604 S2CID 1541253 a b Donofrio Mary T Moon Grady Anita J Hornberger Lisa K Copel Joshua A Sklansky Mark S Abuhamad Alfred Cuneo Bettina F Huhta James C Jonas Richard A Krishnan Anita Lacey Stephanie Lee Wesley Michelfelder Erik C Rempel Gwen R Silverman Norman H 2014 05 27 Diagnosis and treatment of fetal cardiac disease a scientific statement from the American Heart Association Circulation 129 21 2183 2242 doi 10 1161 01 cir 0000437597 44550 5d ISSN 1524 4539 PMID 24763516 S2CID 39191574 a b Canobbio MM Warnes CA Aboulhosn J Connolly HM Khanna A Koos BJ et al February 2017 Management of Pregnancy in Patients With Complex Congenital Heart Disease A Scientific Statement for Healthcare Professionals From the American Heart Association Circulation 135 8 e50 e87 doi 10 1161 CIR 0000000000000458 PMID 28082385 Other Names for Congenital Heart Defects July 1 2011 Archived from the original on 27 July 2015 Retrieved 10 August 2015 External links editCongenital heart defect at Curlie Congenital heart disease information for parents Retrieved from https en wikipedia org w index php title Congenital heart defect amp oldid 1180425092, wikipedia, wiki, book, books, library,

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