Abstract
Background:
Preterm, very-low-birth-weight (PT-VLBW) neonates are at-risk for metabolic syndrome later in life. At 1–3 y, they exhibit excessive weight-for-length z-scores (Wt-LZ) and elevated systolic blood pressures (SBP). Serum adipokines are biomarkers of adiposity, but expression in PT-VLBW infants is unclear. We examined the correlation between serum adipokine levels, anthropometric measures and SBP in PT-VLBW neonates at follow-up.
Methods:
This was a cross-sectional cohort study of PT-VLBW infants at 1, 2, and 3 y of age (40/cohort). We measured SBP, abdominal circumference (AC) and anthropometrics; calculated age/gender-specific z-scores for Wt, L, Wt-L and subscapular skin fold (SSZ), and measured serum adipokines.
Results:
Serum leptin was unaffected by chronologic age and gender, but was positively correlated with weight, Wt-LZ, AC, and SSZ at 1 and 3 y (P < 0.01). Female infants at 1 and 3 y had a more significant relationship than males between serum leptin and SSZ (P < 0.001, R = 0.75 and P < 0.001, R = 0.70, respectively). Adiponectin levels were 16–20% lower at 3 vs. 1–2 y (P = 0.02, ANOVA) and negatively correlated with SBP.
Conclusion:
Although serum leptin was unrelated to advancing age, gender, and SBP in PT-VLBW infants, levels correlated with measures of adiposity at 1 and 3 y, females > males, suggesting leptin resistance may occur in early infancy.
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Main
Infants born very preterm (PT; ≤32 wk of gestation) and very-low-birth-weight (VLBW; birth weight (BW) ≤1,500 g) are at increased risk of obesity, metabolic syndrome (MBS), and hypertension later in life compared to their term counterparts (1,2,3). They have reduced insulin sensitivity, which persists after correcting for appropriateness of intrauterine growth (2). In addition, women born PT (≤37 wk of gestation) are at greater risk of metabolic derangement than men (3). Although altered fetal programming may contribute to the pathogenesis of these findings (4), postnatal variables such as disordered nutrition and growth may also contribute to reprogramming, leading to subsequent metabolic derangements including MBS, obesity, and cardiovascular disease (4,5,6). For example, term infants with rapid disproportionate weight-for-length (Wt-L) growth between birth and 6 mo have elevated systolic blood pressures (SBP) at 6 mo and 3 y of age (7). Children born PT-VLBW also have evidence of growth derangements after birth and in early childhood (7,8,9). At 1–3 y of age, they exhibit excessive Wt-L z-scores (Wt-LZ), i.e., relative obesity, and elevated SBP and SBP z-scores (SBPZ) (8,9). However, their risk for subsequent MBS and hypertension is unclear.
Though reprogramming may contribute to the long-term metabolic abnormalities, hypertension and cardiovascular risk in PT-VLBW, the pathogenesis is unclear. Alterations in adiposity and thus adipokine synthesis may contribute, but are poorly studied. Adipokines are secreted by adipocytes (10), and increases in fat mass results in dysregulated secretion. This promotes inflammation and development of cardiovascular and metabolic disorders (11). Though there are several adipokines, their association with MBS and cardiovascular risk are best defined for leptin, adiponectin, and resistin (11). In adults, serum leptin levels increase with increasing adiposity, providing a novel biomarker for adiposity. Leptin is proinflammatory and increased serum levels correlate with insulin resistance, arterial stiffness, elevated blood pressure, and increased cardiovascular risk (10,11,12). Leptin, therefore, may play a central role in the association between obesity, MBS, and cardiovascular disease through development of leptin resistance at the hypothalamic–pituitary axis in adults (13,14,15,16). In contrast, serum adiponectin levels are inversely related to adiposity, considered anti-inflammatory, and elevations are associated with lower blood pressure and decreased arterial stiffness (11,12,16,17). Adults with hypertension and obesity exhibit decreased levels of adiponectin. Circulating resistin levels also may be increased in obesity. Thus, adipokines are novel biomarkers of MBS and subsequent cardiovascular disease (11,16,18,19).
Though adipokines are important biomarkers of obesity, MBS, and cardiovascular risk in adults (13,14,20), little is known about their homeostasis in PT-VLBW infants in the first years after birth. It is unclear if the pattern of postnatal growth, changes in adiposity, and presence of elevated SBP correlate with altered serum adipokine levels. Thus, we examined the relationships between postnatal growth, SBP and circulating adipokine levels in PT-VLBW infants at 1, 2, and 3 y of chronological age. We hypothesized that measures of adiposity and elevations in SBP would correlate with increases in serum leptin and resistin levels and decreases in serum adiponectin. The studies were considered descriptive and thus, hypothesis-generating.
Methods
Population
PT-VLBW infants (n = 120) who were born at Parkland Hospital and subsequently received their primary outpatient care in the Low Birth Weight Clinic at Children’s Medical Center of Dallas between 2007 and 2008 were consecutively enrolled after obtaining informed consent. They were entered into a cross-sectional cohort study at 1, 2, or 3 y chronological age (n = 40/cohort). These infants were included in recent studies of blood pressure and renal function (9,21). Exclusion criteria included major congenital anomalies, congenital adrenal hyperplasia, and short bowel syndrome requiring total parenteral nutrition after hospital discharge. The Institutional Review Boards of the University of Texas Southwestern Medical Center at Dallas and Children’s Medical Center of Dallas approved the study.
Measurements
After obtaining consent, we measured Wt, L, subscapular skin-fold thickness (SS) and abdominal circumference (AC) and converted Wt, L, Wt-L proportion and SS to age and gender specific z-scores (WtZ, LZ, Wt-LZ, and SSZ, respectively) using reference data from the World Health Organization Anthro calculator (22,23,24). Adjusted age at the time of measurement was used for this calculation and determined by subtracting weeks born preterm, i.e., (40 completed weeks of gestation at birth)—(chronologic age on the visit date). SBP was measured as previously described (8,9).
Assays
Blood samples (~1.5 ml) collected from each infant at the time of the clinic visit were immediately centrifuged at 10,000 × g and the serum stored at −80 °C until the time of assay. Samples were available for measurement of adipokines in 96% of infants, 36/40 in Group 1, 40/40 in Group 2, and 39/40 in Group 3. At the time of assay, samples were thawed, diluted 1:4 and 1:200 to capture all analytes on their respective standard curves and measured in duplicate. One sample diluted at 1:4 was included in each assay to calculate intra- and interassay variability. Assays included IL-6, TNFα, leptin, adiponectin, and resistin measured by ELISA with Fluorokine MultiAnalyte Profiling kits from R&D Systems (Minneapolis, MN) and using the BioPlex 2200 Analyzer (Bio-Rad Laboratories, Hercules, CA). Intra-assay and interassay coefficients of variability were 11.4% for leptin, 10.5% for adiponectin, and 12.9% for resistin. IL-6 and TNFα were below sensitivity of the assay in all samples.
Statistical Analyses
Data for age groups were compared using one-way ANOVA for continuous variables; χ2 and Fisher’s exact tests were used to compare categorical variables. The effect of gender within cohorts was determined using two-way ANOVA. When the ANOVA was significant (P < 0.05), Dunn’s multiple comparison procedures were used to compare groups. Correlations between serum adipokines and SBP and various growth parameters were determined using linear regression analyses. Data are means ± SD unless otherwise noted.
Results
Infants were enrolled between May and September 2007. The majority were Hispanic, reflecting the demographics of the delivery population at Parkland Hospital during the study period ( Table 1 ). There were no differences in gender distribution between cohorts. The fall in mean BW across cohorts paralleled a fall in mean gestational age at birth. Nineteen percent of infants had a BW ≤ 10th centile corrected for gestational age and were small for gestational age (SGA). Twelve percent had asymmetrical fetal growth restriction with a Ponderal Index ≤ 10th centile; the distribution was similar across cohorts.
Growth
Because of the cohort design and the timing of preset clinic visits, we collected additional growth measurements at 6 mo (n = 120), 12 mo (n = 120), and 24 mo (n = 80) adjusted age, and included them in the growth analyses to better characterize the anthropometric changes occurring in this population compared to published growth data for healthy term infants (22,23,24). There were differences in anthropometric measurements at each age compared to expected ( Figure 1 ). At 6 mo, WtZ and LZ were significantly less than expected, whereas Wt-LZ was greater than expected, suggesting excessive Wt gain relative to length in all study infants. This was also true for all cohorts at 12 mo; however, the difference in WtZ was less while LZ remained quite low, resulting in Wt-LZ greater than expected. At 24 mo, the combined 24 and 33 mo cohorts exhibited a lesser difference in WtZ compared to the reference population, but minimal change in LZ; thus, Wt-LZ continued to be significantly greater. These differences were absent in the 3 y cohort.
Serum Adipokines
Serum levels of IL-6 and TNFα were below sensitivity of the assay in all samples. CRP did not differ between cohorts, 0.06 ± 0.1, 0.05 ± 0.1, and 0.06 ± 0.1 mg/ml at 1, 2, and 3 y (P = 0.9), respectively. Leptin concentrations also did not differ between cohorts ( Table 2 ), were unaffected by gender within and across cohorts, and were unrelated to SBP (P > 0.05). When serum leptin levels were correlated with anthropometric measurements within each cohort, positive correlations with WtZ were observed at 1 and 3 y (P = 0.009, R = 0.43, n = 36 and P < 0.001, R = 0.65, n = 38, respectively), but not at 2 y (P = 0.2, R = 0.20, n = 40). After correcting for gender, this was only significant for males at 1 y, but was significant for both genders at 3 y (P ≤ 0.003). Notably, leptin values were positively correlated (P ≤ 0.01) with the Wt-LZ ( Figure 2a ) and SSZ ( Figure 2b ) at 1 and 3 y, but not at 2 y (P > 0.1, R = 0.2 for both). This was more significant in females vs. males for Wt-LZ and SSZ at 1 and 3 y (P ≤ 0.009 vs. 0.01 to 0.07). We also compared the leptin levels in infants who had been growth restricted at birth, i.e., SGA or low ponderal index, with normally grown infants by two-way ANOVA. There was no significant difference, P > 0.1 for either parameter.
Since serum leptin levels generally correlate with Wt, we adjusted values for Wt at the time of measurement and used the leptin/Wt proportion and concentrations < or ≥ 5 ng/ml (the upper range of normal at this age; 25, 26) to describe the infants with elevated levels. The leptin/Wt values were greater (P ≤ 0.001) in infants with levels ≥ 5 ng/ml in all cohorts ( Figure 3 ). However, as the difference in the WtZ fell with increasing chronological age ( Figure 1 ), the number of infants per cohort with leptin values ≥ 5 ng/ml also was less, decreasing from 10 to 4.
Adiponectin levels differed across age-related cohorts and were 16–20% lower in 3 vs. 1–2 y infants (P = 0.02, ANOVA; Table 2 ). There was no gender effect (P = 0.7), and values were unrelated to all anthropometric measurements, including BW (P > 0.1). There was a weak negative correlation between adiponectin and SBP for the entire study population (P = 0.05, R = −0.19, n = 108), i.e., SBP fell as adiponectin rose.; However, it was highly significant in the 1 y cohort (P = 0.002, R = −0.49, n = 36) and in both males (P = 0.02, R = −0.56, n = 17) and females (P < 0.05, R = −0.47, n = 19) within that cohort.
Resistin levels also were less in 2 vs. 1 y infants and did not differ between 2 and 3 y ( Table 2 ; P < 0.001 ANOVA). Male values were less than females, P = 0.009.
Discussion
Elevated serum leptin levels are associated with adiposity, insulin resistance, and increased cardiovascular risk in adults (3,10,11). PT-VLBW infants are at increased risk of cardiovascular derangements later in life compared to their term counterparts (2,3,25). This may be due to PT birth and/or the manner of feeding and growth after birth. We previously reported that PT-VLBW infants grew disproportionately in the first 2 y after birth and demonstrated an elevated Wt-LZ and other measures of adiposity (9). Though measures of adiposity in older children and adults are associated with alterations in serum adipokines (26,27), this is unclear in PT-VLBW infants. We now report that, although serum leptin concentrations are unrelated to advancing age and gender, they are positively correlated with measures of adiposity, including increasing WtZ, Wt-LZ, abdominal circumference (AC), and SSZ in PT-VLBW infant cohorts at 1–3 y of age. Using a serum leptin value ≥ 5 ng/ml and the leptin/Wt relationship to characterize these infants, each cohort included a significant number with elevated leptin/Wt values (28,29). There was, however, no relationship between serum leptin levels and SBP. In contrast, serum adiponectin levels decreased across cohorts and were negatively related to SBP. Thus, serum leptin may be a biomarker for adiposity in infancy in PT-VLBW infants and could predict subsequent risk for abnormalities of metabolism, obesity, and cardiovascular risk. This, however, requires further study.
Rapid postnatal growth in term born infants is associated with increases in Wt-LZ at 6 mo of age, demonstrating disproportionate growth and evidence of early onset adiposity (7). We (9) observed a similar pattern of growth in PT-VLBW infants at 6 and 12 mo corrected age. However, we do not know the age of onset after birth, due to the lack of accurate length measurements before hospital discharge. This has since been addressed, and in recent unpublished observations, it appears that disproportionate growth with a higher Wt-LZ is evident before hospital discharge or as early as 3–4 mo of age in hospitalized PT-VLBW infants. It is unclear if the presence of early disproportionate growth and relative adiposity contribute to the risk for long-term metabolic derangements and elevated SBP; however, in term infants this predicted an elevated SBP at 3 y of age. Thus, feeding practices in the Neonatal ICU, which generally focus on Wt gain rather than the proportionality of Wt and L growth, should be examined.
Serum leptin concentrations > 5 ng/ml are considered elevated in children up to 10 y of age (28,29). Values ≥ 5 ng/ml were present at 1 y adjusted age in PT-VLBW infants and significantly associated with measures of adiposity, including WtZ, AC, SSZ, and Wt-LZ at 1 and 3 y. It is unclear why these relationships were not significant at 2 y, but similar observations were seen regarding renal function (21). It is possible that the middle cohort represents a transitional period, since WtZ did not differ from the reference population whereas the Wt-LZ continued to significantly exceed it. Nonetheless, the relationship between elevated serum leptin levels and increased Wt occurred early. The converse was also observed, i.e., the occurrence of leptin values ≥ 5 ng/ml decreased with decreasing measures of obesity and/or disproportionate WtFLZ growth at 1 and 3 y adjusted age. Therefore, serum leptin levels ≥ 5 ng/ml in infants and toddlers with an elevated leptin/Wt relationship may be a biologic marker for obesity and leptin resistance in PT-VLBW infants as early as 1 y of age. It is unclear, however, if this represents the onset of leptin resistance in the PT-VLBW population and consequently predicts the subsequent development of MBS in later childhood or the adult. If so, it has important implications in the clinical monitoring of PT-VLBW infants. Subsequent studies should prospectively delineate the relationship between various growth parameters and leptin values while in the Neonatal ICU and continue into infancy and late childhood. If correlated, these growth measurements may be useful predictors of future metabolic abnormalities, thereby suggesting the need for changes in care and nutrition during the postnatal period.
The physiologic processes underlying the metabolic derangements that PT-VLBW infants exhibit in later life are not well studied. Studies of the mechanisms underlying childhood and adolescent hypertension in term-born children have posited that cytokines, including leptin, activate the sympathetic nervous system and lead to elevations in blood pressure (30). In adults, this is associated with arterial wall stiffness (12,17). It is notable that there was no relationship between SBP and leptin levels in the present study, particularly considering our earlier observation of an elevated SBP and SBPZ (9). We (21) reported that, although these PT-VLBW infants demonstrated increasing renal function with advancing age during the first 3 y of life, those with the lowest BW and gestational age had the lowest GFR. Moreover, there was evidence of dysfunctional renal autoregulation, hyperfiltration, and possibly early development of glomerulosclerosis. These findings and those in the current study suggest two possible explanations for the elevated SBP and thus, two populations of PT-VLBW infants, i.e., those at-risk for systolic hypertension with and without MBS. The leptin-mediated mechanism that explains obesity-related hypertension in term-born children, adolescents and adults may occur, but does not account for all cases of hypertension in PT-VLBW children. Infants born < 34 wk of gestation have incomplete nephrogenesis and glomerulogenesis (31,32). Brenner et al. (33) proposed the “nephron number hypothesis”, suggesting that when an adverse perinatal environment modifies nephrogenesis, e.g., poor fetal growth or in the present instance, PT birth, there is a nephron deficit due to incomplete nephrogenesis, resulting in decreased renal function and eventually hypertension with glomerulosclerosis. Therefore, the elevated SBP and later hypertension in PT-VLBW children may reflect intrinsic renal deficits, such as incomplete nephrogenesis, rather than leptin mediation (1). It is also unclear to what extent continued glomerular maturation occurs after birth. Notably, recent case reports of glomerulosclerosis in children and adults who were born < 32 wk gestation suggest incomplete development and maturation (34,35). Hence, the elevated SBP may not reflect altered fetal programming, but rather the adverse effects of incomplete renal development associated with very PT birth, which is independent of the early obesity observed in our studies. Detailed longitudinal studies of body composition, leptin levels, renal function, and SBP in PT-VLBW infants are required to address this.
Adiponectin levels in healthy subjects decrease in association with increases in adiposity, are inversely related to blood pressure, and increase with weight loss (11,12,17). Serum adiponectin levels in PT-VLBW decreased across cohorts with increasing age, during which time measures of obesity also decreased; e.g., values for Wt-LZ in the 3 y cohort did not differ from published norms. This is the opposite of the pattern expected; however, adiponectin levels were inversely related to SBP and mirrored adult correlations. Adiponectin levels decrease in humans and primates with increasing insulin resistance and have a stronger correlation with insulin resistance than adiposity (36,37). Thus, the fall in adiponectin may predict the subsequent development of insulin resistance and MBS. Adiponectin levels also fall in the presence of proinflammatory cytokines (11). Although serum TNFα and IL-6 were unmeasurable and CRP was low and unrelated to any variable examined, other proinflammatory cytokines were not examined. As a result, we cannot determine if an underlying state of chronic inflammation existed in our PT-VLBW infants. If so, the reduced adiponectin levels may be a biomarker for chronic inflammation underlying the elevated SBP in PT-VLBW children without primary renal disease as discussed earlier. This can only be addressed in prospective, longitudinal studies of PT-VLBW infants.
This study has several limitations. The cross-sectional nature does not allow for causal inference or longitudinal comparisons as the measurements were not serial, nor were they obtained in a single cohort. In addition, there may be other biological factors affecting adipokine concentrations apart from adiposity, e.g., sex hormone concentrations and the presence of inflammation (11). Given this, gender findings could have been hormonal in nature rather than a result of adiposity, and proinflammatory illnesses common in children born preterm such as chronic lung disease that were not accounted for could also have impacted adipokine levels. There also could be differences in the PT-VLBW population today that were not present at the time of our study. Finally, the preponderance of Hispanic infants might bias the results in unknown ways, decreasing the generalizability to all PT-VLBW infants. Strengths of the study include the relatively large sample size within each cohort, the multiple anthropometric measurements, and the measurement of adipokines in >95% of study infants.
In conclusion, patterns of early growth in infants born PT-VLBW may place them at risk for the development of adiposity and abnormal serum adipokine levels early in infancy. These levels may portend, contribute to, and/or potentiate subsequent development of MBS. The mechanisms responsible for the elevation in leptin levels are unclear. If serum levels are elevated at hospital discharge, as is the Wt-L proportion, feeding practices and immediate postnatal growth may contribute to abnormalities in the synthesis and function of adipokines. Finally, the elevated SBP observed as early as 1 y of age may represent at least two pathogenic mechanisms that cannot be addressed in the present study. Larger serial, longitudinal studies starting soon after birth and extending into late childhood or adolescence are needed to determine how and when these biomarkers change and what, if any, is their relationship to later development of MBS and hypertension in PT-VLBW infants. The current studies should serve as observational studies that are hypothesis-generating.
Statement of Financial Support
A.F.D. was the recipient of a Marshall Klaus Award from the American Academy of Pediatrics, Section on Perinatal Pediatrics to pursue these studies.
Disclosure
There are no disclosures or conflicts of interest.
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Acknowledgements
This study was supported in part by the George L. MacGregor Professorship held by Rosenfeld. Frankfurt received a Young Investigator Award for the presentation of the leptin data at the 2011 annual meeting of the Pediatric Academic Societies. Thanks to the staff in the Low Birth Weight Clinic for assisting in the conductance of this study.
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Duncan, A., Frankfurt, J., Heyne, R. et al. Biomarkers of adiposity are elevated in preterm very-low-birth-weight infants at 1, 2, and 3 y of age. Pediatr Res 81, 780–786 (2017). https://doi.org/10.1038/pr.2017.11
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DOI: https://doi.org/10.1038/pr.2017.11
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