Confirmation of neonatal screening: reference intervals and evaluation of methodological changes in TSH measurement

Analysis of Serum Free Thyroxine Concentrations in Healthy Term Neonates Underlines Need for Local and Laboratory-Specific Reference Interval: A Systematic Review and Meta-Analysis of Individual Participant Data

Background: Initial evaluation of the hypothalamus-pituitary-thyroid axis is done by measuring serum free thyroxine (fT4) and thyrotropin concentrations. For correct interpretation of these measurements, reliable age-specific reference intervals (RIs) are fundamental. Since neonatal fT4 RIs conforming to the Clinical and Laboratory Standards Institute guidelines are not available for all assays, we set out to create literature-based uniform age-specific neonatal fT4 RIs that may be used for every assay. Methods: For meta-analysis of individual participant fT4 concentrations, we systematically searched MEDLINE and Embase (search date December 6, 2023; PROSPERO registration CRD42016041871). We searched for studies reporting fT4 concentrations in healthy term newborns aged 2-27 days, born to mothers without thyroid disease in iodine-sufficient regions. Authors were invited to supply data. Due to standardization differences between assays, data could not be combined for meta-analysis directly, and we attempted to normalize the data using two distinct methods. Results: We obtained 4206 fT4 concentrations from 20 studies that used 13 different assays from 6 manufacturers. First, we set out to normalize fT4 data using the mean and standard deviation of (assay-specific) adult RIs. fT4 concentrations were transformed into Z-scores, assuming a normal distribution. Using a linear mixed-effects model (LMM), we still found a significant difference between fT4 concentration across studies (p < 0.001), after this normalization. As a second approach, we normalized the fT4 concentrations using data from a method/assay comparison study. We used the relationship between the Cobas assay and the other assays as a reference point to convert all values to Cobas values. However, this method also failed to produce consistent results, with significant differences between the normalized data (LMM p < 0.001). Conclusions: We conclude that our attempts at normalizing fT4 assay results were unsuccessful. Confounders related to our unsuccessful analysis may be assay related and/or biological. These findings have significant implications for patient care, since relying on RIs from literature may result in erroneous interpretation of results. Therefore, we strongly recommend to establish local RIs for accurate interpretation of serum fT4 concentrations in neonates.

Age-Specific Reference Intervals for Plasma Free Thyroxine and Thyrotropin in Term Neonates During the First Two Weeks of Life

Background: Congenital hypothyroidism (CH) is a common and preventable cause of mental retardation, which is detected in many neonatal screening programs. Upon suspicion of CH, plasma free thyroxine (fT4) and thyrotropin (TSH) concentrations are measured. CH can be of thyroidal or central origin (CH-T and CH-C, respectively). While CH-T diagnosis is based on an elevated TSH with a low fT4, CH-C diagnosis is based on a low fT4 without a clearly elevated TSH. Currently, reliable neonatal reference intervals (RIs) for plasma fT4 and TSH are lacking. Age-specific RIs would greatly improve the diagnostic process for CH, especially for CH-C. Our aim was to establish neonatal RIs for plasma fT4 and TSH in term neonates at day 3-7 (t = 1) and day 13-15 (t = 2). The study was particularly designed to provide a reliable fT4 lower limit of the RI to facilitate the diagnosis of CH-C. In the Netherlands, neonates are screened at day 3-7 of life. After a screening result suggestive for CH-C, pediatric consultation takes place on average at day 14. Thus, the time points were chosen accordingly. Methods: Venous blood was collected from 120 healthy neonates at each time point (94 participants provided blood samples at two time points; 52 participants provided a sample at t = 1 or t = 2). fT4 and TSH were measured using an immunoassay (Cobas; Roche Diagnostics). RIs were calculated using the 95% confidence interval for normally distributed data and the nonparametric percentile method if data were not normally distributed. Results: From 146 participants (49% female), ≥1 measurement was available. Ninety-five percent RIs for fT4 were 20.5-37.1 pmol/L (day 3-7) and 15.3-26.5 pmol/L (day 13-15). Ninety-five percent RIs for TSH were 1.0-8.4 mU/L (day 3-7) and 1.4-8.6 mU/L (day 13-15). Conclusions: Our results indicate an fT4 lower limit of the RI of 20.5 pmol/L at day 3-7 and 15.3 pmol/L at day 13-15. These lower limits are considerably higher than this assay's lower limit of the adult RI for fT4. In case CH is suspected, we recommend measuring fT4 and TSH using an assay with an established neonatal RI, taking into account the child's age in days.

Childhood Thyroid Function Reference Ranges and Determinants: A Literature Overview and a Prospective Cohort Study

BACKGROUND

Reported cutoffs for childhood thyrotropin (TSH) and free thyroxine (fT4) reference ranges vary widely, and knowledge on the determinants of childhood thyroid function is sparse. This study aimed to summarize the existing studies on thyroid function reference ranges in children. Furthermore, the objective was to investigate the determinants of childhood TSH and fT4 concentration in a population based-prospective cohort.

METHODS

First, to identify studies on childhood thyroid reference ranges, The National Library of Medicine's PubMed, Embase, Ovid Medline, Web of Science, and Google Scholar databases were systematically searched. Second, in a non-selected sample of 4273 children (median age 6.0 years, range 4.9-9.1 years) from the cohort, the associations of age, sex, anthropometric characteristics, ethnicity, maternal education, and time and season at venipuncture were studied with TSH and fT4 concentrations. The study also investigated to what extent between-individual variations in the determinants of TSH and fT4 could influence the calculation of reference ranges.

RESULTS

Published reference ranges for TSH and fT4 differ per age range and within age ranges (cutoffs low TSH: 0.13 to >1 mIU/L; high TSH: 2.36 to >10 mIU/L; low fT4: 7.0 to >10 pmol/L; high fT4: 15.5 to >30 pmol/L). In the present cohort, weight, sex, and ethnicity were determinants of TSH (p ≤ 0.03) and fT4 concentrations (p ≤ 0.01), and height and time at venipuncture were determinants of TSH only (p < 0.0001). The between-individual variation depending on clinical determinants for TSH ranged between 0.64 and 0.96 mIU/L (total population 0.87 mIU/L) for the lower limit and 4.30 and 5.62 mIU/L (total population 5.20 mIU/L) for the upper limit, whereas for fT4, the lower limit ranged between 13.6 and 14.2 pmol/L (total population 13.8 pmol/L) and the upper limit ranged between 20.2 and 23.0 pmol/L (total population 20.8 pmol/L).

CONCLUSIONS

Considerable differences exist in the reported reference ranges for childhood TSH and fT4 across and within age ranges and assays. The present cohort shows only a minimal association between TSH and fT4, suggesting that the hypothalamus-pituitary-thyroid axis remains unaffected by thyroid interfering factors. Various determinants of TSH and fT4 in children were identified, which accounted for a considerable variation of reference range cutoffs.