AlmondDCurrieJ. Killing me softly: The fetal origins hypothesis. J Econ Perspect2011; 25: 153–172.
2.
BarkerDJOsmondC. Infant mortality, childhood nutrition, and ischaemic heart disease in England and Wales. Lancet1986; 1: 1077–1081.
3.
KwonEJKimYJ. What is fetal programming?: A lifetime health is under the control of in utero health. Obstet Gynecol Sci2017; 60: 506–519.
4.
PerroneSSantacroceAPicardiA, et al.Fetal programming and early identification of newborns at high risk of free radical-mediated diseases. World J Clin Pediatr2016; 5: 172–181.
5.
BarkerDJWinterPDOsmondC, et al.Weight in infancy and death from ischaemic heart disease. Lancet1989; 2: 577–580.
6.
GluckmanPDHansonMASpencerHG, et al.Environmental influences during development and their later consequences for health and disease: Implications for the interpretation of empirical studies. Proc Biol Sci2005; 272: 671–677.
7.
BerensonGS. Childhood risk factors predict adult risk associated with subclinical cardiovascular disease. The Bogalusa Heart Study. Am J Cardiol2002; 90: 3L–7L.
8.
CrispiFBijnensBFiguerasF, et al.Fetal growth restriction results in remodeled and less efficient hearts in children. Circulation2010; 121: 2427–2436.
9.
De JongeLLvan Osch-GeversLWillemsenSP, et al.Growth, obesity, and cardiac structures in early childhood: The Generation R Study. Hypertension2011; 57: 934–940.
10.
AhmadizarFVoortmanT. Arterial stiffness in childhood: A predictor for later cardiovascular disease?Eur J Prev Cardiol2018; 25: 100–102.
11.
NorrishGCantaruttiNPissaridouE, et al.Risk factors for sudden cardiac death in childhood hypertrophic cardiomyopathy: A systematic review and meta-analysis. Eur J Prev Cardiol2017; 24: 1220–1230.
12.
LipshultzSELawYMAsante-KorangA, et al.Cardiomyopathy in children: Classification and diagnosis: A scientific statement from the American Heart Association. Circulation2019; 140: e9–e68.
13.
MohlkertLAHallbergJBrobergO, et al.The preterm heart in childhood: Left ventricular structure, geometry, and function assessed by echocardiography in 6-year-old survivors of periviable births. J Am Heart Assoc2018; 7: e007742–e007742.
14.
KaramitsosTDFrancisJMNeubauerS. The current and emerging role of cardiovascular magnetic resonance in the diagnosis of nonischemic cardiomyopathies. Prog Cardiovasc Dis2011; 54: 253–265.
15.
StoutKKDanielsCJAboulhosnJA, et al.2018 AHA/ACC Guideline for the management of adults with congenital heart disease: Executive summary: A report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation2019; 139: e637–e697.
16.
ToemenLGaillardRRoestAA, et al.Fetal and infant growth patterns and left and right ventricular measures in childhood assessed by cardiac MRI. Eur J Prev Cardiol. 2020; 27: 63–74.
17.
VijayakumarMFallCHOsmondC, et al.Birth weight, weight at one year, and left ventricular mass in adult life. Br Heart J1995; 73: 363–367.
18.
LewandowskiAJAugustineDLamataP, et al.Preterm heart in adult life: Cardiovascular magnetic resonance reveals distinct differences in left ventricular mass, geometry, and function. Circulation2013; 127: 197–206.
19.
LewandowskiAJBradlowWMAugustineD, et al.Right ventricular systolic dysfunction in young adults born preterm. Circulation2013; 128: 713–720.
20.
HudsmithLEPetersenSETylerDJ, et al.Determination of cardiac volumes and mass with FLASH and SSFP cine sequences at 1.5 vs. 3 Tesla: A validation study. J Magn Reson Imaging2006; 24: 312–318.
21.
GatiSSharmaSPennellD. The role of cardiovascular magnetic resonance imaging in the assessment of highly trained athletes. JACC Cardiovasc Imaging2018; 11: 247–259.
22.
BluemkeDAKronmalRALimaJA, et al.The relationship of left ventricular mass and geometry to incident cardiovascular events: The MESA (Multi-Ethnic Study of Atherosclerosis) study. J Am Coll Cardiol2008; 52: 2148–2155.
23.
RiderOJTylerDJ. Clinical implications of cardiac hyperpolarized magnetic resonance imaging. J Cardiovasc Magn Reson2013; 15: 93–93.
