Longitudinal changes in insulin-like growth factor-I, insulin sensitivity, and secretion from birth to age three years in small-for-gestational-age children

INTRODUCTION: Insulin resistance (IR) develops as early as age 1 to 3 yr in small for gestational age (SGA) infants who show rapid catch-up postnatal weight gain. In contrast, greater insulin secretion is related to infancy height gains. We hypothesized that IGF-I levels could be differentially related to gains in length and weight and also differentially related to IR and insulin secretion. METHODS: In a prospective study of 50 SGA (birth weight < 5th percentile) and 14 normal birth weight [appropriate for gestational age (AGA)] newborns, we measured serum IGF-I levels at birth, 1 yr, and 3 yr. IR (by homeostasis model assessment) and insulin secretion (by short iv glucose tolerance test) were also measured at 1 yr and 3 yr. RESULTS: SGA infants had similar mean length and weight at 3 yr compared with AGA infants. SGA infants had lower IGF-I levels at birth (P < 0.0001), but conversely they had higher IGF-I levels at 3 yr (P = 0.003) than AGA infants. Within the SGA group, at 1 yr IGF-I was associated with length gain from birth and insulin secretion (P < 0.0001); in contrast at 3 yr IGF-I was positively related to weight, body mass index, and IR. CONCLUSIONS: IGF-I levels increased rapidly from birth in SGA, but not AGA children. During the key first-year growth period, IGF-I levels were related to beta-cell function and longitudinal growth. In contrast, by 3 yr, when catch-up growth was completed, IGF-I levels were related to body mass index and IR, and these higher IGF-I levels in SGA infants might indicate the presence of relative IGF-I resistance.     

A prospective study of serum insulin-like growth factor I (IGF-I) and IGF-binding protein-3 in 942 healthy infants: associations with birth weight, gender, growth velocity, and breastfeeding

CONTEXT: Many aspects of hormonal regulation and mechanisms of normal infancy growth are poorly understood. OBJECTIVE: The objective of this study was to establish the determinants of serum growth factor levels in infancy and their association with growth. DESIGN: A prospective, longitudinal, population-based birth cohort between 1997-2001 was studied. PARTICIPANTS: Study participants were 942 healthy appropriate weight for gestational age (AGA) infants (538 boys and 404 girls) and 49 small for gestational age (SGA) children (29 boys and 20 girls). Interventions: Interventions were anthropometrical measurements (0, 3, 18, and 36 months) and serum samples (3 months). MAIN OUTCOME MEASURES: Height, weight, and serum IGF-I and IGF-binding protein-3 (IGFBP-3) were the main outcome measures. RESULTS: IGF-I levels showed no gender difference [boys, 92 ng/ml (confidence interval, 49, 162); girls, 91 ng/ml (47, 149); P = 0.50]. IGFBP-3 levels were significantly higher in females [2174 ng/ml (1295, 3330)] than in males [2103 ng/ml (1266, 3143); P = 0.04]. Infants receiving breast milk had lower IGF-I levels [90 ng/ml (48, 154)] than infants receiving formula [n = 62; 97 ng/ml (58, 165)] or both [n = 123; 94 ng/ml (48, 169); P < 0.001]. IGF-I and IGFBP-3 levels were positively associated with weight gain and height gain from birth to 3 months of age in AGA, but not in SGA, children. SGA children had significantly lower IGF-I [88.0 ng/ml (28, 145); P = 0.05] and IGFBP-3 [1835 ng/ml (1180, 2793); P < 0.001] levels than AGA children. CONCLUSION: We found a significant, but weak, association between IGF-I and IGFBP-3 levels at 3 months and postnatal growth in AGA, but not SGA, children. Factors other than IGF-I must contribute to the regulation of normal postnatal growth, and these may differ between AGA and SGA children. IGFBP-3, but not IGF-I, showed a gender difference, which may reflect an influence of the postnatal activation of the pituitary-gonadal axis on binding protein levels.     

Cord blood leptin concentrations in relation to intrauterine growth

OBJECTIVE: Leptin, a hormone that signals the amount of energy stores to the brain, has recently been shown to play a role in the regulation of several hypothalamic pituitary axes, including the growth hormone axis. To investigate a potential association between cord blood leptin concentrations and intrauterine growth we measured leptin concentrations in the cord blood of small for gestational age (SGA), appropriate for gestational age (AGA) and large for gestational age (LGA) healthy newborns. PATIENTS AND MEASUREMENTS: Cord blood leptin concentrations were evaluated in 25 SGA, 100 AGA, and 45 LGA, neonates. RESULTS: Leptin was detectable in all newborns in concentrations comparable with those found in adults. Moreover, SGA newborns had lower leptin concentrations (3.70 +/- 1.81 micrograms/l) than AGA (5.65 +/- 4.98 micrograms/l) and LGA newborns (11.99 +/- 7.06 micrograms/ l)(P < 0.01). Cord blood leptin concentrations were significantly associated with ponderal index, cord blood insulin concentrations, placental weight and maternal serum leptin concentrations. Importantly, the association between cord blood leptin concentrations and intrauterine growth status persisted after adjusting for adiposity, placental weight, maternal serum leptin concentrations and cord blood insulin concentrations. CONCLUSIONS: Cord blood leptin concentrations are independently associated with intrauterine growth. Future studies are needed to elucidate the underlying mechanism and clarify the role of leptin in regulating growth and controlling appetite in newborns.     

Cord plasma concentrations of adiponectin and leptin in healthy term neonates: positive correlation with birthweight and neonatal adiposity

OBJECTIVE: Adiponectin is negatively associated with leptin, insulin and obesity in children and adults. Whereas increases in fetal insulin and leptin are associated with increased weight and adiposity at birth, the role of adiponectin in fetal growth has not yet been determined. The aims of this study were to examine the relationships between adiponectin and insulin, leptin, weight and adiposity at birth in healthy term infants. DESIGN AND METHODS: Anthropometric parameters including weight, length, circumferences and skinfold thickness were measured, and plasma lipid profiles, insulin, leptin and adiponectin concentrations in cord blood samples from 226 singleton infants born at term after uncomplicated pregnancies were assayed. RESULTS: Cord plasma adiponectin, leptin and insulin levels correlated significantly and positively with birthweight (P = 0.001, P < 0.001, P < 0.001, respectively) and the sum of skinfold thicknesses (P < 0.001, P < 0.001, P < 0.001, respectively). Mean cord plasma adiponectin and leptin levels, but not insulin level, were significantly higher in large-for-gestational-age (LGA) infants compared with appropriate-for-gestational-age (AGA) infants. Cord plasma leptin concentration, but not adiponectin concentration, was significantly higher in female infants than in male infants (P = 0.003 and P = 0.94, respectively). Cord plasma adiponectin concentration correlated positively with leptin level (P = 0.007) but not with insulin level (P = 0.78). CONCLUSIONS: High adiponectin levels are present in the cord blood. Cord plasma adiponectin and leptin levels are positively correlated with birthweight and adiposity. This suggests that adiponectin may be involved in regulating fetal growth.     

Adiponectin levels in the first two years of life in a prospective cohort: relations with weight gain, leptin levels and insulin sensitivity

Adiponectin, a novel adipocytokine with insulin sensitizing properties, is inversely related to obesity and insulin resistance in adults. We recently reported large variations in weight gain and insulin sensitivity during the first year in infants born small for gestational age (SGA) or appropriate for gestational age (AGA). We now determined whether adiponectin levels were related to postnatal growth and insulin sensitivity in a prospective cohort followed from birth to two years old (n = 85) (55 female/30 male, 65 SGA/20 AGA). Serum adiponectin levels at one year and two years were higher compared to reported levels in adults and older children, and decreased from one year (21.6 +/- 0.6 microg/ml) to two years (15.7 +/- 0.7 microg/ml) (p < 0.05). At two years adiponectin levels were lower in females (15.3 +/- 0.4 microg/ml) than males (16.4 +/- 0.6 microg/ml) (p < 0.05), but no gender difference was seen in leptin or insulin levels. No differences in adiponectin levels were seen between SGA and AGA infants at one or two years. However, in SGA infants changes in adiponectin between one to two years old were inversely related to weight gain (r = -0.310, p < 0.05). Changes in leptin levels between one to two years were positively related to weight gain in both SGA and AGA infants (r = 0.450 and r = 0.500 respectively, both p < 0.05). Adiponectin levels were unrelated to insulin levels at one or two years, nor to change in insulin levels between one to two years. In multiple regression analysis, adiponectin levels were related only to postnatal age; omitting age from the model, the determinants of higher adiponectin levels were male gender (p = 0.03), lower postnatal body weight (p < 0.001), and higher birth weight SD score (p = 0.004). In conclusion, fall in serum adiponectin levels during the first two years of life were related to increasing age and greater weight gain SGA infants, but were unrelated to insulin sensitivity.     

Early development of adiposity and insulin resistance after catch-up weight gain in small-for-gestational-age children

CONTEXT AND OBJECTIVE: Low birth weight followed by rapid postnatal weight gain is associated with long-term risks for central obesity and insulin resistance. However, the timing of these changes is unclear. SETTING, DESIGN, AND PATIENTS: This was a longitudinal cohort study in low birth weight (SGA; birth weight < -2 sd; n = 29) and normal birth weight (AGA; n = 22) children from Barcelona. MAIN OUTCOME MEASURES: Body composition, by dual-energy x-ray absorptiometry scan, and insulin sensitivity, assessed longitudinally at ages 2, 3, and 4 yr, were measured. RESULTS: Mean height, weight, and body mass index at ages 2, 3, and 4 yr were not different between SGA and AGA children. At age 2 yr, SGA children had similar body composition but were more insulin sensitive than AGA children and had lower serum IGF-I levels and lower neutrophil counts. Between ages 2 and 4 yr, despite similar gains in weight and body mass index, SGA children gained more abdominal fat and body adiposity and less lean mass than AGA children; by age 4 yr, SGA children had greater adiposity, insulin resistance, and higher neutrophil counts than AGA children (P = 0.01-0.0004). In SGA children, total and abdominal fat mass at 4 yr was more closely related to rate of weight gain between 0 and 2 yr (P = 0.002-0.0003) than between 2 and 4 yr (P = 0.04-0.1). CONCLUSION: Consequent to catch-up weight gain between birth and 2 yr, SGA children showed a dramatic transition toward central adiposity and insulin resistance between ages 2 and 4 yr. Understanding the mechanisms underlying this predisposition to adverse future health could lead to specific preventive interventions during early childhood.     

Visceral adiposity without overweight in children born small for gestational age

CONTEXT: Children born small for gestational age (SGA) tend to develop catch-up growth in infancy and become overweight by the age of 6 yr. Weight control is advocated as a preventive measure, but it is unknown whether such control suffices to prevent visceral fat excess and hypoadiponectinemia. SETTING: The study was performed at a university hospital. STUDY POPULATION AND DESIGN: A total of 64 children (32 matched pairs) aged 6 yr, of whom 32 were born appropriate for gestational age and 32 were born SGA, and had subsequently developed spontaneous catch-up growth were included in the study; matching was performed for gender, height, weight, and, thus, body mass index. MAIN OUTCOMES: Fasting insulin, IGF-I, high molecular weight adiponectin, leptin, visfatin, and lean and fat mass were calculated by absorptiometry, and abdominally sc and visceral fat by magnetic resonance imaging. RESULTS: After strict matching, SGA children had a total lean mass, total fat mass, leptinemia, and visfatinemia comparable to those in the appropriate for gestational age children, but they still had higher fasting insulin and IGF-I levels (P < 0.01), much lower high molecular weight adiponectin levels (P < 0.0001), and a striking shift from abdominally sc to visceral fat (P < 0.0001). Fasting insulin (r = 0.52; P < 0.00001) was a major determinant of visceral fat in boys and girls, explaining 28% of its variance. CONCLUSIONS: SGA children tend to be viscerally adipose and hypo-adiponectinemic, even if they are not overweight. Therefore, measures beyond weight control seem to be needed to allow most SGA children to normalize their body composition and endocrine-metabolic homeostasis.     

Serum adiponectin levels, insulin resistance, and lipid profile in children born small for gestational age are affected by the severity of growth retardation at birth

OBJECTIVE: Insulin resistance has been linked to intrauterine growth retardation (IUGR); adiponectin is a protein with insulin-sensitizing properties. This study was designed to test whether being born small for gestational age (SGA) has an effect on blood levels of adiponectin and leptin, insulin resistance parameters, and lipid profile in pre-puberty, taking into consideration the severity of IUGR. METHODS: Serum levels of adiponectin, leptin, total cholesterol (t-CHOL), high density lipoprotein (HDL)-cholesterol, low density lipoprotein (LDL)-cholesterol, triglycerides, apolipoproteins A-1 (Apo A-1), Apo B and Apo E, lipoprotein(a) (Lp(a)), fasting glucose, and insulin (Ins), the homeostasis model assessment insulin resistance index (HOMA-IR) and anthropometric indices were evaluated in 70 children aged 6-8 years, born appropriate for gestational age (AGA; n = 35) and SGA (n = 35), matched for age, gender, height, and BMI. SGA children were divided into two subgroups according to the severity of IUGR: SGA<3rd percentile (n = 20), and SGA 3rd-10th percentile (n = 15). They were also subdivided in two subgroups, those with (n = 25) and those without (n = 10) catch-up growth, considering their actual height corrected for mid-parental height. RESULTS: SGA children had higher Ins and HOMA-IR than AGA children (Ins, 42 +/- 23 vs 32 +/- 11 pmol/l; HOMA-IR, 1.30 +/- 0.8 vs 0.92 +/- 0.3; P<0.05). No significant difference in serum leptin was found between the SGA and the AGA groups but adiponectin showed a trend to be higher in SGA children (13.6 +/- 5.7 vs 10.8 +/- 5.9 microg/ml respectively). SGA children without catch-up growth had higher adiponectin (15.6 +/- 8.5 microg/ml, P<0.05) than AGA children. Among the SGA children, the subgroup <3rd percentile had higher Lp(a) than the subgroup 3rd-10th percentile (P<0.05). An independent positive correlation between adiponectin and Lp(a) was observed in SGA children (R = 0.59, P<0.01). CONCLUSION: SGA children, although more insulin resistant, had similar or higher adiponectin levels than matched AGA children in pre-puberty. The severity of IUGR appears to affect their metabolic profile during childhood.     

Markers of insulin sensitivity in placentas and cord serum of intrauterine growth-restricted newborns

Objective  Intrauterine growth restriction (IUGR) has been related to a higher incidence of insulin resistance in adult life, which is associated with low adiponectin and high resistin, insulin and interleukin (IL)-6 serum concentrations. This study assessed cortisol, insulin, total insulin receptor, resistin, adiponectin and IL-6 concentrations, as markers of insulin sensitivity, in placental lysates and cord serum of IUGR and appropriate for gestational age (AGA) newborns, to establish relationships among peptides and with growth parameters at birth.
Design and patients  Whole villous tissue and cord serum at birth were collected from 24 AGA and 18 IUGR newborns of comparable gestational age.
Measurements  Hormonal and peptide concentrations were assayed in placental lysates and cord serum using specific commercial kits. Concentrations in lysates were adjusted per mg of total protein content.
Results  Cortisol, insulin and resistin concentrations and the total amount of insulin receptor were similar in both groups. IL-6 concentration in lysates was significantly higher in IUGR compared with AGA newborns. Adiponectin was significantly lower in lysates from IUGR compared with AGA newborns. Placental insulin and resistin concentrations were positively correlated. Placental adiponectin concentration was positively correlated with the weight of the placenta, birthweight and head circumference. IL-6 concentration in lysates was negatively correlated with birth length, birthweight and head circumference.
Conclusions  This study evaluated the markers of insulin sensitivity in the placentas of subjects born IUGR, showing new potential roles for adiponectin and IL-6 in particular, and suggesting a role for the placenta in the programming of these hormones.     

Serum levels of adiponectin and IGFBP-1 in short children born small for gestational age

OBJECTIVE: The aim of this study was to quantify serum adiponectin concentrations in short children born small for gestational age (SGA) compared with those in children born appropriate for gestational age (AGA), and to assess the relationship between the serum levels of adiponectin and insulin-like growth factor binding protein-1 (IGFBP-1) known as a predictor of the development of type 2 diabetes mellitus and cardiovascular disease. SUBJECTS AND METHODS: Sixteen prepubertal short children born SGA and 20 short children born AGA, matched for age, body mass index, height, pubertal status, gestational age, bone age and midparental height, were included in the study. The serum levels of adiponectin, IGFBP-1, insulin and insulin-like growth factor-I (IGF-I) were measured in the fasting state. RESULTS: The levels of serum adiponectin were significantly lower in the SGA than in AGA children (10.5 +/- 4.2 vs. 13.9 +/- 5.1 micro g/ml, P < 0.05). The levels of serum IGFBP-1, insulin and IGF-I were all similar in both groups. Overall, there was a significant positive correlation between adiponectin and IGFBP-1 (r = 0.40, P < 0.05). CONCLUSIONS: Our results suggest that hypoadiponectinaemia in short SGA children without catch-up growth may reflect insulin resistance and imply a higher risk of developing type 2 diabetes mellitus. Additionally, adiponectin may be a more sensitive indicator for latent insulin resistance than IGFBP-1 in short SGA children.     

Low serum adiponectin levels in subjects born small for gestational age: impact on insulin sensitivity

OBJECTIVE: Increasing evidence point to the role of the adipose tissue on the insulin resistance associated with reduced fetal growth. Since adiponectin, exclusively produced by the adipose tissue, exerts an important insulin-sensitizing activity, it appears critical to investigate the effect of being born small for gestational age (SGA) on adiponectin production in adulthood and its relationship with insulin sensitivity. SUBJECTS AND METHODS: Serum adiponectin concentrations were measured in 486 young adults born SGA, precisely selected on birth data, who were compared to 573 age-matched subjects born appropriate for gestational age (AGA). The relationship between serum adiponectin levels and insulin-resistance indices measured under OGTT were tested and compared between the two groups. RESULTS: The SGA group demonstrated significantly reduced serum adiponectin levels than controls (12.6 +/- 6.9 vs 13.2 +/- 6.4 microg/ml, P = 0.02) and the difference remained significant when the key regulatory factors were taken into account (P = 0.008). In the AGA group, fasting I/G taken as an insulin-resistance index negatively correlated with serum adiponectin concentrations (P = 0.02), while the relationship followed a U-shape with increased fasting I/G ratio despite high concentrations of serum adiponectin in the SGA group (P = 0.12). CONCLUSION: Subjects born SGA demonstrated significantly reduced serum adiponectin levels, which were not related to insulin-resistance indices in comparison to what observed in age-matched subjects born AGA. Although this defect in adiponectin production and in its insulin-sensitizing action remains to be elucidated at the molecular level, it strengthens the critical contribution of the adipose tissue in the metabolic complications associated with reduced fetal growth.     

Both intrauterine growth restriction and postnatal growth influence childhood serum concentrations of adiponectin

OBJECTIVE: Insulin resistance has been linked to intrauterine growth restriction; adiponectin is a strong determinant of insulin sensitivity. We aimed at studying the contributions of birthweight and insulin sensitivity to circulating adiponectin in children born small for gestational age (SGA). DESIGN: Cross-sectional, hospital-based study dealing with insulin sensitivity in SGA children. PATIENTS: Thirty-two prepubertal children born SGA (age 5.4 +/- 2.9 years) and 37 prepubertal children born appropriate for gestational age (AGA, age 5.9 +/- 3.0 years). MEASUREMENTS: Serum levels of fasting glucose, serum lipids, insulin (immunometric assay) and adiponectin concentrations (ELISA) were assessed, and insulin resistance (IR) and insulin secretion (beta-cell) were calculated by the homeostasis model of assessment (HOMA). RESULTS: SGA children had similar HOMA-IR, HOMA-beta-cell and adiponectin concentrations than AGA children. However, in a separate analysis of subjects older than 3 years of age, SGA children showed higher HOMA-IR after adjusting for sex, age and body mass index (BMI) standard deviation score (SDS). Circulating adiponectin was higher in SGA children [adjusted means: 14.5 mg/l (95% CI 12.9-16.1) and 18.7 mg/l (95% CI 17.0-20.3) for AGA and SGA children, respectively; P < 0.0001]. Further analysis revealed that the group of overweight SGA (arbitrarily defined as being in the higher quartile for the BMI SDS distribution in the sample) had decreased serum concentrations of adiponectin, compared to lean SGA children [adjusted means: 12.9 mg/l (95% CI 9.3-16.5) vs. 19.0 (95% CI 16.8-21.3), respectively; P = 0.001]. In a multiple regression model, HOMA-IR and SGA status explained 35% and 15% of adiponectin variance, respectively. CONCLUSIONS: Prenatal growth restriction is associated with insulin resistance but relatively increased adiponectin concentrations, provided overweight does not ensue. The contributions of circulating adiponectin to the increased risks for developing insulin resistance and type-2 diabetes in formerly SGA subjects merit further studies.     

The association between the FTO gene and fat mass in humans develops by the postnatal age of two weeks

OBJECTIVE: Little is known about the genetic determinants of fat mass around birth. We hypothesized that the common rs9939609 single-nucleotide polymorphism (SNP) in FTO is associated with fat mass and metabolic parameters in neonates. DESIGN: We conducted a cross-sectional, hospital-based study. PATIENTS: Patients included 234 full-term, healthy newborns [122 girls and 112 boys; gestational age (mean, range), 39.0 (37.0-42.0) wk; birth weight, 3.2 (1.9-4.2) kg]. METHODS: Cord-blood insulin, IGF-I, IGF-binding protein-1, adiponectin, and visfatin were measured by specific immunoassays. Body composition was assessed by dual-energy x-ray absorptiometry at about 13 d (range, 9-20 d). Genotyping of rs9939609 was achieved by restriction fragment length polymorphism analysis. RESULTS: The rs9939609 SNP in FTO was not associated with birth weight; however, it was associated with serum visfatin (P < 0.001), with weight and ponderal index at age 2 wk (P < 0.05), and with total, truncal, and abdominal fat (P < 0.05 to P = 0.01), so that AA homozygotes had 37% higher plasma visfatin concentration and 17, 20, and 17% higher total, truncal, and abdominal fat mass, respectively, than T-carrier neonates. CONCLUSION: Our findings support a role of the common rs9939609 SNP in FTO gene in the early stages of fat accretion in humans and disclose novel associations between this SNP and both serum visfatin and abdominal fat mass in neonates.     

Early development of visceral fat excess after spontaneous catch-up growth in children with low birth weight

CONTEXT: The sequence of prenatal growth restraint and infantile catch-up of weight is by the age of 4 yr associated with hyperinsulinemic adiposity. We studied whether the adiposity of post-catch-up children born small for gestational age (SGA) is further amplified between age 4 and 6 yr and whether visceral fat excess has already emerged by the age of 6 yr. SETTING: The study took place at a university hospital. STUDY POPULATION AND DESIGN: A longitudinal cohort (age 2-6 yr) of 22 children born appropriate for gestational age (AGA) and 29 born SGA were studied. Auxological, endocrine, metabolic, and body composition (by absorptiometry) assessments were made at 2, 4, and 6 yr, and visceral fat was assessed (by magnetic resonance imaging) at 6 yr. MAIN OUTCOMES: Outcome measures included fasting glucose, insulin, IGF-I, neutrophil to lymphocyte ratio, lean mass, and total, abdominal, and visceral fat mass. RESULTS: Between ages 4-6 yr, the relative adiposity of SGA children was further amplified. Between ages 2-6 yr, SGA children gained more total and abdominal fat and raised their insulin, IGF-I, and neutrophil to lymphocyte ratio more than did AGA children (all P<0.0001). At age 6 yr, the average amount of visceral fat was in SGA children more than 50% higher than in AGA children (P<0.005). The 0- to 2-yr increment in weight Z-score together with the 2- to 6-yr increment in fasting insulin accounted for 62% of visceral fat variability at age 6 yr. CONCLUSION: The amount of visceral fat is in post-catch-up SGA children excessive by the age of 6 yr. In populations at risk for type 2 diabetes or metabolic syndrome after fetal growth restraint, the time window for early intervention may have to be advanced into prepubertal childhood.     

The insulin-like growth factor-I (IGF-I) gene in individuals born small for gestational age (SGA)

OBJECTIVE: To investigate the association of genetic variation of the insulin-like growth factor-I (IGF-I) gene with birth size small for gestational age (SGA). SUBJECTS: We have studied a cohort of 120 SGA patients and 147 appropriate for gestational age (AGA) controls from Haguenau, France. METHODS: PCR-SSCP analysis was performed to detect sequence variation in the coding region of the IGF-I gene. Microsatellite markers near the IGF-I gene (intronic and D12S78) were selected and amplified to perform further analysis by association studies. RESULTS: A novel polymorphism in intron 2 was discovered, but allele-specific PCR analysis in the 120 SGA patients and 147 AGA controls found no association between this polymorphism and birth size SGA. Chi squared (chi2) analysis found no statistically significant association between the allele distribution of the microsatellite markers in the SGA subjects and the AGA controls. Power calculations estimate that the D12S78 marker has an 80% chance of detecting a 10-15% difference. CONCLUSIONS: These studies suggest that genetic variation of IGF-I alone does not result in birth size small for gestational age in this population. Thus, if this gene influences fetal size, it plays only a minor role in a multifactorial disorder which involves other genetic and environmental factors.     

Comparison of leptin levels, body composition and insulin sensitivity and secretion by OGTT in healthy, early pubertal girls born at either appropriate- or small-for-gestational age

BACKGROUND: Small for gestational age (SGA) has been associated with decreased insulin sensitivity (IS). A possible mechanism is the postnatal development of a metabolically disadvantageous body composition (BC). AIM: To determine whether there are differences between IS and BC in girls in early puberty who were SGA (birth weight < 10th percentile) or appropriate for gestational age (AGA, 10th-90th percentile). METHODS: Age-matched (SGA/AGA) early pubertal girls (Tanner II) were recruited from local schools. We determined waist circumference (WC), the sum of four skinfolds (S4S), and per cent fat mass (fat %) by impedanciometry. Leptin and OGTT assays were performed. The insulinogenic index (I-In), HOMA-IR (homeostasis model assessment of insulin resistance) and WBISI (whole body insulin sensitivity) were calculated. RESULTS: Median age (interquartile range) for 30 SGA and 35 AGA girls was 10.2 (1.1) vs. 9.8 (0.9), respectively (P = NS). BMI percentiles were 62.6 (56) vs. 67.4 (39); WC 60.5 (9.5) vs. 62.2 (6.5) cm; S4S 52 (30) vs. 52.2 (29.5) cm, and fat %[26.2 (6.7) vs. 28.5 (6.3)] was similar in both groups. SGA girls had higher leptin levels [15.4 (9.7) vs. 9.6 (11) ng/ml; P = 0.01] and I-In [2.05 (1.86) vs. 1.47 (1.27) microU/ml* mg/dl; P = 0.02]. No differences between HOMA-IR [2.07 (1.26) vs. 2.04 (1.4)] and WBISI [5.3 (3.3) vs. 5.1 (3.1)] were found between groups. CONCLUSION: The higher leptin level and I-In in girls born SGA at the beginning of puberty may be early indicators of an underlying subtle degree of insulin resistance, despite similar BMI and BC to AGA girls.     

小于胎龄儿青春前期线性生长方式与血清胰岛素水平关系的研究

目的 探讨小于胎龄儿(small for gestational age,SGA)出生后生长追赶状态与血清胰岛素水平的关系.方法 青春前期30例有生长追赶SGA(catch-up growth SGA,CUG-SGA组)、37例无生长追赶SGA(NCUG-SGA组)和42例适于胎龄儿(appropriate for gestational age,AGA组),测定空腹血糖、空腹胰岛素(FINS)和血清胰岛素样生长因子I(IGF-I).结果 (1)与NCUG-SGA和AGA组比较,CUG-SGA组FINS和稳态模型评估的胰岛素抵抗指数(HOMA-IR)显著为高(P<0.01或P<0.05),而NCUG-SGA组与AGA组则无显著性差异(P>0.05).CUG-SGA组血清IGF-I水平较NCUG-SGA组显著为高[(212.61±17.81对137.40±14.66)ng/ml,P=0.001],但与AGA组无显著性差异(P=0.095).(2)SGA组HOMA-IR与年龄、身高标准差分值增值(AHtSDS)和体重指数分别正相关;≤6岁SGA组FINS与△HtSDS呈正相关,>6岁组FINS与体重标准差分值增值呈正相关.结论 生后早期胰岛素可能以生长因子角色参与了SGA儿的生长追赶;胰岛素抵抗程度与生长追赶程度相随.

Abstract：

Objective To evaluate the association between two different linear growth patterns with the levels of serum insulin in children bem small for gestational age(SGA).Methods Serum fasting glucose,fasting insulin,and insulin-like growth factor-I(IGF-I)concentrations were determined in 30 catch-up growth(CUG)children bern SGA [CUG-SGA,16 females,14males,(6.62±0.66)year],37 non-catch-up growth(NCUG)children born SGA[NCUG-SGA,15 females,22 males,(5.97±0.56)year],and42 appropriate for gestational age(AGA)children with normal height[AGA,16females,26males,(7.05±0.39)year].Results (1) Basal fasting insulin and homeostasis model assessment for insulin resistance(HOMA-IR)were significantly higher in CUG-SGA group than in NCUG-SGA and AGA group(P<0.01 or P<0.05).But there was no difference in fasting insulin between NCUG-SGA group and AGA group.IGF-I levels in CUG-SGA were significantly higher than in NCUG-SGA group[(212.61±17.81 vs 137.40±14.66)ng/ml,P=0.001],but showed no difference from AGA group(P=0.095).(2)In the SGA group,HOMA-IR showed positive correlation with age,△height SDS,and current body mass index.Fasting insulin showed positive correlation with △height SDS(r=0.500,P=0.002)in≤6 year group as well as with △weight SDS(r=0.496,P=0.030)in>6 year group.Conclusions Insulin as a growth factor may participate in postnatal catch-up growth accompanied with increased insulin resistance in SGA children.     

Insulin, adiponectin, IGFBP-1 levels and body composition in small for gestational age born non-obese children during prepubertal ages

Background Being small for gestational age (SGA) at birth and postnatal growth pattern may have an impact on insulin resistance and body composition in later life. Adiponectin is a strong determinant of insulin sensitivity. Objective The aim of this study was to evaluate insulin resistance and adiponectin levels in SGA born children with catch‐up growth (CUG) in the absence of obesity in prepubertal ages and relations with body composition and insulin‐like growth factor binding protein (IGFBP)‐1. Methods Twenty‐four (15F, 9M) SGA born children with CUG but without obesity were evaluated at age 6·3 ± 0·5 years with respect to glucose, insulin, IGFBP‐1, leptin and adiponectin levels, and body composition by dual‐energy X‐ray absorptiometry (DEXA). Their data were compared to that of 62 (27F, 35M) appropriate for gestational age (AGA) children. Results SGA and AGA children had similar height standard deviation score (SDS) corrected for parental height and body mass index (BMI) SDS. Homeostasis model for insulin resistance (HOMA‐IR) was significantly high in SGA (0·7 ± 0·6) than in AGA children (0·4 ± 0·2) (P = 0·029). There were no significant differences in leptin, IGFBP‐1, adiponectin, and total and truncal fat between SGA and AGA children. However, being born SGA and having higher BMI in the upper half for the distribution in the sample, although within normal ranges, was associated with lower adiponectin levels (estimated means of log adiponectin levels 3·8 ± 0·3 vs. 4·4 ± 0·1 µg/ml, P = 0·040). Conclusions SGA children with CUG and with no obesity have higher insulin levels compared to AGA children. Both SGA birth and recent size seem to have an effect on serum adiponectin levels in childhood.     

Longitudinal changes in insulin sensitivity and secretion from birth to age three years in small- and appropriate-for-gestational-age children

Aims/hypothesis Insulin resistance and type 2 diabetes risk in human subjects who were small-for-gestational-age (SGA) at birth may be a consequence of rapid early postnatal weight gain. Materials and methods We prospectively studied early changes in fasting insulin sensitivity and insulin secretion, assessed by a short intravenous glucose tolerance test that was conducted several times from birth to 3 years of age in 55 SGA (birthweight below fifth percentile) newborns and in 13 newborns with a birthweight appropriate for gestational age (AGA). Results Most SGA infants showed postnatal upward weight centile crossing and by 3 years were similar in size to AGA infants. SGA infants had lower pre-feed insulin levels at postnatal age 48 h than AGA infants (median 34.4 vs 59.7 pmol/l, p<0.05), but by the age of 3 years they had higher fasting insulin levels (median 38.9 vs 23.8 pmol/l, p<0.005), which were related to rate of weight gain between 0 and 3 years (r=0.47, p=0.0003). First-phase insulin secretion did not differ between SGA and AGA infants, but SGA infants had a lower glucose disposition index (beta cell compensation) (median 235 vs 501 min mmol⁻¹ l⁻¹, p=0.02), which persisted after allowing for postnatal weight gain (p=0.009). Conclusions/interpretation SGA infants showed a marked transition from lower pre-feed insulin and increased insulin sensitivity at birth to insulin resistance over the first 3 years of life. This transition was related to rapid postnatal weight gain, which could indicate a propensity to central fat deposition. The additional observation of reduced compensatory beta cell secretion underlines the need for long-term surveillance of glucose homeostasis in all SGA subjects, whether or not they show postnatal catch-up growth.     

Functional hypersomatotropism in small for gestational age (SGA) newborn infants

Basal plasma GH levels and the GH responses to an injection of 1 microgram/kg 1-44(NH2) GHRH were determined on day 3 postnatally in 5 small gestational age (SGA) twin newborns and their appropriate gestational age (AGA) co-twins, and in 10 SGA singleton newborns and 6 AGA singleton newborns. The mean basal plasma GH level was higher in the SGA than in the AGA infants but the difference was significant only for singleton newborns (p less than 0.01). The mean peak plasma GH level was markedly increased in SGA compared to AGA infants (p less than 0.05 for twins, p less than 0.01 for singletons). Twelve SGA infants re-tested at 1 month had lower basal and peak plasma GH levels (p less than 0.001 and p less than 0.01). In 21 SGA and 17 AGA infants, serum IGF-I, measured by RIA between 12 and 96 hours after birth, was significantly higher in SGA than in AGA (p less than 0.001). These results suggest that, whatever the mechanism, functional hypersomatotropism is present at day 3 in SGA infants. This hypersomatotropism may participate in the early catch-up growth process.