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.     

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.     

Serum leptin levels and insulin resistance are associated with gallstone disease in overweight subjects

AIM: To establish an association between the serum leptin levels and the development of gallstone disease (GD). METHODS: We carried out a non-matched case-controlled study in a university hospital in Mexico City. Two hundred and eighty-seven subjects were included: 97 cases with gallstones and 190 controls. Body mass index (BMI), fasting plasma leptin, insulin, serum lipid, and lipoprotein levels were measured. Insulin resistance was calculated by homeostasis model assessment (HOMA-IR). Unconditional logistic regression analysis (univariate and multivariate) stratified by BMI was used to calculate the risk of GD. RESULTS: The multivariate conditional regression analysis revealed a model for those patients with BMI <30. The selected variables in the model were HOMA-IR index with OR = 1.31, P= 0.02 and leptin higher than median with OR = 2.11, P = 0.05. In the stratum of BMI ≥30, we did not find a useful model. CONCLUSION: We concluded that insulin resistance and the development of GD appears to be associated with serum leptin levels in subjects with overweight, but not in obese subjects with similar metabolic profiles.     

Adiponectin is an indicator of insulin resistance in non-obese prepubertal children born large for gestational age (LGA) and is affected by birth weight

Background and objective Being born as large for gestational age (LGA) has an increased risk of developing insulin resistance. Hypoadiponectinaemia is associated with insulin resistance. The aim of this study was to evaluate adiponectin levels and insulin resistance in association with body composition in LGA born non‐obese children at prepubertal ages. Patients and methods Thirty‐five (17 female and 18 male) LGA born non‐obese children (mean age 4·8 ± 0·3 years) were evaluated with respect to glucose, insulin, IGFBP‐1, leptin, adiponectin levels and body composition by DEXA. Their data were compared to that of non‐obese 49 (20 female, 29 male) appropriate for gestational age (AGA) children (mean age 3·8 ± 0·1 year). Results LGA children, who had similar body mass index standard deviation scores (BMI SDS) as AGA children, had significantly higher insulin (P = 0·043) and statistically borderline significant homeostasis model assessment‐insulin resistance (HOMA‐IR) levels (P = 0·054) than those of AGA children. Adiponectin levels were significantly lower in LGA than AGA children (P = 0·004) even after controlling for age, sex and BMI (P = 0·016). IGFBP‐1, leptin levels and body composition did not show a difference. When the LGA group was divided into subgroups according to birth weight, the analysis revealed that after controlling for BMI, being an LGA and having a higher birth weight in the upper half were associated with lower adiponectin levels (estimated marginal means of logarithmic adiponectin levels 2·6 ± 0·2 vs. 2·1 ± 0·2 µg/ml, P = 0·042). Conclusion LGA children have higher insulin and lower adiponectin levels than AGA children in spite of similar BMI. Adiponectin is a better indicator of insulin resistance in LGA children at prepubertal ages and is affected by birth weight.     

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.     

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.     

Pathophysiology of insulin resistance in subjects born small for gestational age

Over the last 15 years, a number of long-term health risks associated with reduced fetal growth have been identified, including cardiovascular diseases, hypertension, dyslipidaemia and type 2 diabetes. A common feature of these conditions is insulin resistance, which is thought to play a pathogenic role. However, despite abundant data in the literature, it is still difficult to trace the pathway by which fetal events, environmental or not, may lead to increased morbidity later in life. To explain this association, several hypotheses have been proposed pointing to the role of a detrimental fetal environment, a genetic susceptibility or an interaction between the two, and of the particular dynamic changes in adiposity that occur during catch-up growth. The relative impact of early postnatal events in relation to fetal growth has to be considered for designing health policy strategies for early interventions aimed at decreasing disease risk throughout life.     

Adiponectin levels are reduced in children born small for gestational age and are inversely related to postnatal catch-up growth

Adiponectin is an adipocytokine with insulin-sensitizing and antiatherogenic properties. Reduced concentrations of adiponectin precede the onset of type 2 diabetes and the development of atherosclerosis. Our aim was to quantify adiponectin concentrations in small for gestational age (SGA) children. Fifty-one SGA children, 24 obese, and 17 short-normal children with birth weight appropriate for gestational age (short-AGA) were studied. The statures of the SGA children were corrected for their midparental height and subdivided into two groups according to their corrected height: catch-up growth group, children with corrected height of 0 z-score or greater (n = 17); and noncatch-up growth group, subjects with corrected height less than 0 z-score (n = 34). SGA children showed adiponectin levels significantly lower than short- normal children (35.2 +/- 3.5 vs. 80.4 +/- 26.6 micro g/ml; P < 0.0001) and obese children (77.5 +/- 39.4 micro g/ml; P < 0.0001). Catch-up growth children showed adiponectin levels significantly lower than noncatch-up growth subjects (29.4 +/- 10.3 vs. 38.1 +/- 11.5 micro g/ml; P = 0.01). Adiponectin concentrations were inversely related to height z-score, corrected stature, weight, and body mass index and were positively related to birth weight. Our results suggest that adiponectin levels are reduced in SGA children and are even lower in those with postnatal catch-up growth. Whether this finding implies a higher risk of developing type 2 diabetes and atherosclerosis remains to be established.     

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

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.     

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.     

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

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.     

Serum thyroid hormone levels in healthy children from birth to adulthood and in short children born small for gestational age

Context: Age-appropriate reference ranges for thyroid hormones are required for detecting pediatric thyroid dysfunction. Data on thyroid hormones and peripheral thyroid metabolism in short children born small for gestational age (SGA) before and during GH treatment are lacking. Objectives: Our objectives were to obtain pediatric thyroid hormone reference ranges; to investigate thyroid hormones in short SGA children before puberty, during puberty, and during postponement of puberty by GnRH analog; and to evaluate thyroid hormones during GH treatment. Patients and Design: In 512 healthy children (225 females; 0-18 yr), free T(4) (FT(4)), TSH, total T(4), T(3), rT(3), and T(4)-binding globulin were determined. Reference ranges were calculated using the linearity, median, and skewness method. In 125 short SGA children (62 females; mean age 11.3 yr), thyroid hormones were analyzed before and after 2 yr of GH treatment and additional GnRH analog. Results: Thyroid references showed wide ranges postnatally and age-specific patterns thereafter, similar in boys and girls. Untreated short SGA children had similar FT(4) and T(4) levels as the reference population but significantly higher T(3), rT(3), and T(4)-binding globulin levels. During puberty and during GH treatment, FT(4) and rT(3) significantly decreased, whereas T(3) significantly increased. Conclusion: Age-specific thyroid reference ranges are presented. Puberty and GH treatment both induce changes in peripheral thyroid metabolism, resulting in more biologically active T(3) at the expense of less inactive rT(3), possibly mediated by IGF-I. GH treatment induces altered peripheral thyroid metabolism but does not result in thyroid dysfunction.     

Glucose tolerance,insulin sensitivity,and insulin secretion in children born small for gestational age

Intrauterine growth retardation is associated with an increased risk of developing adult diseases, such as noninsulin-dependent diabetes mellitus (NIDDM). NIDDM could result from a decreased insulin sensitivity or a reduced insulin secretion or a combination of both. Glucose tolerance, insulin sensitivity, and insulin secretion were studied in prepubertal children born small for gestational age (SGA). Twenty-nine SGA children with a mean age of 9.1 +/- 1.1 yr and 24 children born appropriate for gestational age (AGA), with a mean age of 9.0 +/- 1.1 yr, were studied. All children were born at term and were prepubertal. Children were studied on two separate days after 12 h of overnight fasting. Day 1: Glucose tolerance was studied with an oral glucose tolerance test. AUC(ins0-120 min)/AUC(gluc0-120 min) was used to estimate beta-cell function in the two groups. Day 2: A hyperinsulinemic euglycemic clamp study was performed to determine insulin sensitivity (M-value). Glucose tolerance and beta-cell function were not different between the two groups. M-value in SGA children was significantly lower than M-value in AGA children: 12.9 +/- 4.0 mg/kg.min vs. 15.6 +/- 2.3 mg/kg.min [P = 0.009; after adjustment for appropriate gestational age body mass index (BMI), P = 0.001]. The M-value tended to be higher in SGA children without catch-up growth compared with SGA children with catch-up growth (15.8 +/- 4.3 vs. 12.3 +/- 3.8 mg/kg.min; P = 0.079) and was comparable to AGA controls (15.6 +/- 2.3 mg/kg.min). The M-value in SGA children who had shown catch-up growth was comparable to AGA children (13.4 +/- 3.4 vs. 15.6 +/- 2.3 mg/kg.min; P = 0.06), provided they had a BMI of 17 kg/m(2) or less. However, the SGA children with catch-up growth and a BMI greater than 17 kg/m(2) were those having the lowest M-values (9.3 +/- 3.4 mg/kg.min). In conclusion, during oral glucose tolerance tests, no differences were found in glucose tolerance and beta-cell function between the SGA and AGA groups. However, the hyperinsulinemic clamp showed a reduced insulin sensitivity in SGA children, which may contribute to the enhanced risk of developing NIDDM in adult life, especially in SGA children with catch-up growth and a high BMI. The implications of our findings in relation to height are unclear, but might be of potential importance when considering GH treatment. In addition, interventions to improve fetal growth and to control obesity in childhood seem to be important factors in the prevention of NIDDM.     

IGFBP-1 levels in adult women born small for gestational age suggest insulin resistance in spite of normal BMI

OBJECTIVE: Impaired fetal development may contribute to decreased insulin sensitivity. This study was designed to characterize serum markers of insulin resistance in adults born small for date or born prematurely. STUDY DESIGN: Fifty subjects, all women, were evaluated at a mean age +/- SD of 26 +/- 2 years (range: 23-30 years). They were allocated to three groups: (i) born fullterm with birth weight <2600 g (n = 18) (small for gestational age, SGA), (ii) born before gestational week 32 (n = 15) (ex-preterm), and (iii) controls, born fullterm with appropriate birth weight (n = 17). Anthropometric data as well as fasting serum samples of plasma B-glucose, serum lipids, insulin, insulin-like growth factor-I (IGF-I) and insulin-like growth factor binding protein-1 (IGFBP-1) levels were determined. RESULTS: In the SGA group final height was lower and they weighed less compared with the controls. Fasting insulin and glucose levels did not differ amongst the groups. Triglycerides were lower in the SGA group and in the ex-preterm group compared with the controls (P < 0.05). The SGA group showed lower IGFBP-1 levels compared with the controls median 17 (range 3-121) vs. 26 (7-67) microg L-1; P < 0.05]. The IGF-I levels in the SGA, ex-preterm and control groups were 212 +/- 58, 259 +/- 37 and 216 +/- 32 microg L-1, respectively, corresponding to a mean SD score of -0.8 +/- 1.0, 0.1 +/- 0.6 and -0.6 +/- 0.6. CONCLUSION: As IGFBP-1 is a marker of insulin sensitivity, the low levels observed in adult women with normal BMI, born small for date, suggest relative insulin resistance in spite of normal BMI.     

Adiposity in children born small for gestational age

Epidemiological studies indicate that children born small for gestational age (SGA) have an increased risk of metabolic and cardiovascular disorders as adults. This suggests that foetal undernutrition leads to permanent metabolic alterations, which predispose to metabolic abnormalities upon exposure to environmental factors such as low physical activity and/or high-energy intake in later life (thrifty phenotype hypothesis). However, this relationship is not restricted to foetal undernutrition or intrauterine growth retardation, but is also found for children born premature, or for high birth weight children. Furthermore, early post-natal nutrition, and more specifically catch-up growth, appear to modulate cardiovascular risk as well. Intrauterine growth retardation can be induced in animal models by energy/protein restriction, or ligation of uterine arteries. In such models, altered glucose homeostasis, including low beta-cell mass, low insulin secretion and insulin resistance is observed after a few weeks of age. In humans, several studies have confirmed that children born SGA have insulin resistance as adolescents and young adults. Alterations of glucose homeostasis and increased lipid oxidation can indeed be observed already in non-diabetic children born SGA at early pubertal stages. These children also have alterations of stature and changes in body composition (increased fat mass), which may contribute to the pathogenesis of insulin resistance. Permanent metabolic changes induced by foetal/early neonatal nutrition (metabolic inprinting) may involve modulation of gene expression through DNA methylation, or alterations of organ structure. It is also possible that events occurring during foetal/neonatal development lead to long-lasting alterations of the hypothalamo-pituitary-adrenal axis or the hypothalamo-pituitary-insulin-like growth factor-1 axis.     

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.     

Serum dehydroepiandrosterone sulfate levels and pubarche in short children born small for gestational age before and during growth hormone treatment

It has been suggested that the programming of the endocrine axes occurs during critical phases of fetal development and will be affected by intrauterine growth retardation. As a result, children born small for gestational age (SGA) might have several hormonal disturbances. In later life, one of the questions that might arise is: Do short children born SGA have higher serum dehydroepiandrosterone sulfate (DHEAS) levels than their peers? Therefore, we compared serum DHEAS levels of 181 short prepubertal children aged 3-9 yr born SGA [birth length (SD score) below -2 for gestational age] with a control group of 170 prepubertal age-matched, normal-statured children born appropriate for gestational age (birth length between -2 and +2 SD score). Because relatively high serum DHEAS levels at a young age might result in a premature pubarche, we investigated the incidence of premature pubarche. We also investigated the association between serum DHEAS levels and bone maturation. In addition, we analyzed whether 1 yr of GH treatment with 1 and 2 mg/m(2).d ( approximately 0.035 and 0.070 mg/kg.d, respectively) had an effect on serum DHEAS levels of prepubertal short SGA children. Serum DHEAS levels of the SGA group were comparable with those of age-matched appropriate for gestational age controls. The incidence of premature pubarche was comparable with that of the normal population. There was a weak negative correlation between serum DHEAS levels and bone maturation after the age of 7 yr. After 1 yr of GH treatment, the increase of serum DHEAS levels was the same for both GH dosage groups and the untreated group. In conclusion, this study shows that small size at birth, which might be a feature of fetal growth restriction, has no effect on serum DHEAS levels before the age of 9 yr. The incidence of premature pubarche is comparable with the normal population. Finally, 1 yr of GH treatment has no effect on serum DHEAS levels.