| P2093 | author name string | D Gallagher | |
| | F X Pi-Sunyer | |
| | C Paley | |
| | T Toro-Ramos | |
| P2860 | cites work | Pediatric DXA: technique and interpretation | Q24676076 |
| | DENSITOMETRIC ANALYSIS OF BODY COMPOSITION: REVISION OF SOME QUANTITATIVE ASSUMPTIONS | Q28191036 |
| | Measuring body composition | Q28972343 |
| | Quantitative magnetic resonance fat measurements in humans correlate with established methods but are biased | Q30511987 |
| | Measurement of fetal fat in utero in normal and diabetic pregnancies using magnetic resonance imaging | Q30584465 |
| | Noninvasive measurements of body composition and body water via quantitative magnetic resonance, deuterium water, and dual-energy x-ray absorptiometry in cats | Q30620451 |
| | Noninvasive measurements of body composition and body water via quantitative magnetic resonance, deuterium water, and dual-energy x-ray absorptiometry in awake and sedated dogs | Q30620453 |
| | Body composition from birth to 6 mo of age in Ethiopian infants: reference data obtained by air-displacement plethysmography. | Q30663846 |
| | Studies on human body composition during the first 4 months of life using magnetic resonance imaging and isotope dilution | Q30819569 |
| | Body composition during the first 2 years of life: an updated reference | Q30870903 |
| | Accuracy and reproducibility of adipose tissue measurements in young infants by whole body magnetic resonance imaging | Q30897988 |
| | Validation of a quantitative magnetic resonance method for measuring human body composition | Q31144241 |
| | Quantitative magnetic resonance (QMR) method for bone and whole-body-composition analysis | Q31166215 |
| | A semi-automated method for non-invasive internal organ weight estimation by post-mortem magnetic resonance imaging in fetuses, newborns and children | Q33366166 |
| | QMR: validation of an infant and children body composition instrument using piglets against chemical analysis | Q33523267 |
| | Adipose tissue distribution in children: automated quantification using water and fat MRI. | Q33614945 |
| | Validation of quantitative magnetic resonance body composition analysis for infants using piglet model | Q33768631 |
| | Human body composition: in vivo methods | Q33881280 |
| | Distribution of adipose tissue in the newborn | Q75185464 |
| | The effect of growth and development on the composition of mammals | Q75672051 |
| | Assessment of body fatness in young children using the skinfold technique and BMI vs body water dilution | Q76383553 |
| | The extracellular (thiosulfate) space in the human body during growth | Q76497179 |
| | Hydration of fat-free body mass: new physiological modeling approach | Q77855215 |
| | Estimation of neonatal body composition: isotope dilution versus total-body electrical conductivity | Q77893001 |
| | Subcutaneous fat in the fetal abdomen as a predictor of growth restriction | Q78082796 |
| | Bone and body composition measurements of small subjects: discrepancies from software for fan-beam dual energy X-ray absorptiometry | Q81240188 |
| | Ultrasound assessment of intrauterine growth restriction: relationship to neonatal body composition | Q82444821 |
| | Whole body magnetic resonance imaging of healthy newborn infants demonstrates increased central adiposity in Asian Indians | Q83290041 |
| | Relationship between body composition changes and changes in physical function and metabolic risk factors in aging | Q95789670 |
| | In vivo measurement of body composition of chickens using quantitative magnetic resonance | Q33960129 |
| | Prediction equations for body-fat percentage in Indian infants and young children using skinfold thickness and mid-arm circumference | Q34307714 |
| | Newborn adiposity measured by plethysmography is not predicted by late gestation two-dimensional ultrasound measures of fetal growth | Q35149973 |
| | The volume of distribution of sodium thiosulfate as a measure of the extracellular fluid space | Q35189695 |
| | Higher infant body fat with excessive gestational weight gain in overweight women | Q35206822 |
| | The fetal body compartments and their detection during pregnancy. A review. | Q35584197 |
| | Clinical implications of postnatal alterations in body water distribution | Q35682639 |
| | Pediatric obesity phenotyping by magnetic resonance methods | Q35846444 |
| | Excess early postnatal weight gain leads to increased abdominal fat in young children | Q35977579 |
| | Chemical development in utero | Q36006562 |
| | Skinfold thickness as an indication of maturity of the newborn | Q36061062 |
| | Fetal body composition | Q36276998 |
| | Cadaver studies and their impact on the understanding of human adiposity | Q36336541 |
| | Crossvalidation of anthropometry against magnetic resonance imaging for the assessment of visceral and subcutaneous adipose tissue in children. | Q36339818 |
| | Reliability of routine clinical measurements of neonatal circumferences and research measurements of neonatal skinfold thicknesses: findings from the Born in Bradford study | Q36494959 |
| | The potential use of nuclear magnetic resonance imaging in pregnancy | Q36501760 |
| | Validation and application of dual-energy x-ray absorptiometry to measure bone mass and body composition in small infants | Q36756749 |
| | Air-displacement plethysmography pediatric option in 2-6 years old using the four-compartment model as a criterion method | Q36772736 |
| | Ultrasound estimates of visceral and subcutaneous-abdominal adipose tissues in infancy | Q36844994 |
| | Is body composition important for paediatricians? | Q36931401 |
| | Diagnosis of IUGR: traditional biometry | Q37164857 |
| | Bariatric surgeries: beyond restriction and malabsorption | Q37930951 |
| | Use of MRI and CT for fat imaging in children and youth: what have we learned about obesity, fat distribution and metabolic disease risk? | Q38004143 |
| | Body composition assessment in the infant | Q38178519 |
| | Body composition at 6 months of life: comparison of air displacement plethysmography and dual-energy X-ray absorptiometry | Q38463329 |
| | Fetal and maternal factors associated with neonatal adiposity as measured by air displacement plethysmography: a large cross-sectional study | Q39362932 |
| | Body fat mass of exclusively breastfed infants born to overweight mothers | Q39569892 |
| | Evaluation of air-displacement plethysmography for body composition assessment in preterm infants. | Q39607607 |
| | Lean body mass-body fat interrelationships in humans | Q39667273 |
| | Water distribution in the foetus and newborn infant | Q40156898 |
| | Nutrition from conception to extreme old age. | Q40252248 |
| | Multicomponent models in body composition research: opportunities and pitfalls | Q41098745 |
| | Calibration and validation of EchoMRI™ whole body composition analysis based on chemical analysis of piglets, in comparison with the same for DXA | Q41164836 |
| | Dynamic coordination of macronutrient balance during infant growth: insights from a mathematical model | Q42060543 |
| | A customized standard to assess fetal growth in a US population | Q43882633 |
| | Ultrasonographic estimation of fetal body composition for children of diabetic mothers | Q43896879 |
| | Fetal subcutaneous tissue thickness (SCTT) in healthy and gestational diabetic pregnancies. | Q44702221 |
| | Quantification of the subcutaneous fat layer with MRI in fetuses of healthy mothers with no underlying metabolic disease vs. fetuses of diabetic and obese mothers. | Q45174127 |
| | Intra- and inter-observer reliability in anthropometric measurements in children. | Q45901696 |
| | Fetal weight estimation: comparison of two-dimensional US and MR imaging assessments. | Q46648380 |
| | Estimation of fetal weight with the use of head, body, and femur measurements--a prospective study | Q47228242 |
| | Postnatal weight loss and contraction of the extracellular compartment is triggered by atrial natriuretic peptide | Q47229279 |
| | Magnetic resonance imaging compared to ultrasonography in fetal weight and volume estimation in diabetic and normal pregnancy | Q47242565 |
| | Fetal organ weight estimation by postmortem high-field magnetic resonance imaging before 20 weeks' gestation | Q47322240 |
| | Greater maternal weight gain during pregnancy predicts a large but lean fetal phenotype: a prospective cohort study | Q47345859 |
| | Fetal weight estimation by echo-planar magnetic resonance imaging | Q47378059 |
| | The composition of the adult human body as determined by chemical analysis. | Q47822758 |
| | Nuclear magnetic resonance imaging--a new look at the fetus | Q48447916 |
| | Energy requirements derived from total energy expenditure and energy deposition during the first 2 y of life | Q48708946 |
| | Differential growth of fetal tissues during the second half of pregnancy | Q48811470 |
| | Estimating total body fat using a skinfold prediction equation in Brazilian children. | Q51425770 |
| | Quantitative nuclear magnetic resonance to measure fat mass in infants and children. | Q51546035 |
| | Post-mortem examination of human fetuses: a comparison of whole-body high-field MRI at 9.4 T with conventional MRI and invasive autopsy. | Q51816078 |
| | Reduction of subcutaneous mass, but not lean mass, in normal fetuses in Denver, Colorado. | Q52053209 |
| | Body composition techniques and the four-compartment model in children. | Q52075776 |
| | Four-component model of body composition in children: density and hydration of fat-free mass and comparison with simpler models. | Q52215875 |
| | An evaluation of dual-energy X-Ray absorptiometry and underwater weighing to estimate body composition by means of carcass analysis in piglets. | Q52236564 |
| | A new air displacement method for the determination of human body composition. | Q52322347 |
| | Cross-validation of the Slaughter skinfold equations for children and adolescents. | Q52391436 |
| | Revised equations for calculating CO2 production from doubly labeled water in humans. | Q52395586 |
| | Skinfold equations for estimation of body fatness in children and youth. | Q52551678 |
| | Fetal nonmuscular soft tissue: a prenatal assessment. | Q52886313 |
| | Skinfold thickness in neonates. | Q54444524 |
| | A new air displacement plethysmograph for the measurement of body composition in infants. | Q55036374 |
| | Small head circumference at birth and early age at adiposity rebound | Q57402802 |
| | Is fetal abdominal subcutaneous fat comparable with established indices of growth restriction? | Q58009716 |
| | Body composition of the reference fetus | Q68232805 |
| | Fetal fat measurement by magnetic resonance imaging | Q69675635 |
| | Magnetic resonance imaging in human pregnancy | Q69914936 |
| | Body composition of reference children from birth to age 10 years | Q70362000 |
| | Gross tissue weights in the human body by cadaver dissection | Q70646273 |
| | Dual-energy X-ray absorptiometry and body composition | Q71609601 |
| | Inhibitors of the arachidonic acid cascade dissociate 48/80-induced Ca2+ influx and Ca2+ release in mast cells | Q72077498 |
| | NMR imaging in pregnancy | Q72541984 |
| | Estimation of total body fat and subcutaneous adipose tissue in full-term infants less than 3 months old | Q72644069 |
| | Indirect estimates of body composition are useful for groups but unreliable in individuals | Q73083622 |
| | Dual-energy X-ray absorptiometry: analysis of pediatric fat estimate errors due to tissue hydration effects | Q73221637 |
| | Prediction of intra-abdominal and subcutaneous abdominal adipose tissue in healthy pre-pubertal children | Q74780895 |
| P433 | issue | 12 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | infancy stage | Q49257364 |
| P304 | page(s) | 1279-1289 | |
| P577 | publication date | 2015-08-05 | |
| P1433 | published in | European Journal of Clinical Nutrition | Q15756702 |
| P1476 | title | Body composition during fetal development and infancy through the age of 5 years | |
| P478 | volume | 69 | |