Early Ultrasonic Monitoring of Brain Growth and Later Neurodevelopmental Outcome in Very Preterm Infants

Participants

This study combined data of 2 comparable prospective observational cohort studies performed between 2010 and 2017 at the NICU of the Erasmus MC Sophia Children’s Hospital, Rotterdam, the Netherlands. All preterm infants born between 24 and 30 weeks’ gestational age (GA) and admitted to the NICU within 48 hours after birth were eligible for participation in Study A (Submarine study) or Study B (BOND study) (Online Supplemental Data).^12,13 Infants with severe congenital or chromosomal abnormalities, perinatal asphyxia (cord blood/first postnatal pH, <7.0 and APGAR score at 5 minutes, <5), and congenital TORCH infection (toxoplasmosis, other agents, rubella, cytomegalovirus, and herpes simplex) were excluded. Parental informed consent was obtained for all participants. Both studies were approved by the medical ethics committee of the Erasmus MC Sophia Children’s Hospital, University Medical Center, Rotterdam.

Maternal, obstetric, and neonatal characteristics were collected prospectively from the electronic medical record. Ethnicity was classified as non-Western if one or both parents were born in a non-Western country, and parental education level was based on both parents.¹⁴ Brain injury was diagnosed on CUS and included subependymal and intraventricular hemorrhage (grade 1–2+), cerebellar hemorrhage, stroke, and/or periventricular leukomalacia. Postnatal age was defined as days after birth with the day of birth as day 1.¹⁵

Markers of Brain Growth

CUS was routinely performed according to local clinical protocol by the attending neonatologist or an experienced researcher. The local protocol included CUS on postnatal age days 1, 2, 3, and 7, followed by weekly measurements until transfer from the NICU to a level II hospital. A MyLab 70 scanner (Esaote) with a convex neonatal probe (7.5 MHz) was used. Off-line measurements of CC length and CCF length on a standard midsagittal plane were performed using MyLab software (Esaote) by one of the researchers. As described previously in detail, CCF length (centimeters) was measured from the genu of the corpus callosum (outer border) to the fastigium, and CC length (centimeters), from genu to the splenium (outer-outer border) (Online Supplemental Data).⁹

Head circumference (centimeters) was measured during the NICU stay as part of standard care using a tape measure. Growth z scores were based on the Fenton Growth Charts from birth until discharge or 50 weeks’ GA and on the World Health Organization growth charts thereafter.¹⁶

For this study, we used measurements of CCF length, CC length, and HC assessed at the following times: 1) birth (postnatal age, days 1–3); 2) around 29 weeks’ GA (28–30 weeks); and 3) at NICU transfer to a level II hospital (limited to 30–36 weeks’ GA). Growth rate (millimeters/week) of CCF length, CC length, and HC was calculated between birth and NICU transfer. To increase homogeneity in timing and the length of the growth periods, we only calculated growth rate when the first CUS was performed in the first week of life and the period between 2 measurements covered at least 14 days.

In study B, CUS and HC measurements were also performed at the routine outpatient clinic visit at a median of 6.9 weeks’ CA (interquartile range [IQR], 6.1–8.3 weeks), further referred to as the 2 months’ visit. In these infants, the growth rate of each marker was also calculated between birth and 2 months.

Neurodevelopmental Outcome

As part of the national neonatal follow-up program, all children were routinely invited to the outpatient clinic at 2 years’ CA for physical and neurologic examinations by a neonatologist or pediatric neurologist. Trained physiotherapists and psychologists performed extensive testing of psychomotor and cognitive development using fine-motor and gross motor (summarized in a total motor score) and cognitive tests of the Bayley Scales of Infant and Toddler Development, 3rd edition (Bayley-III, Dutch edition), expressed as standard scores adjusted for CA at the moment of testing.¹⁷ Following Dutch guidelines, the Lexi list was used to evaluate expressive language development. This validated questionnaire is completed by parents to quantify the child’s vocabulary with scores adjusted for CA at assessment and sex.¹⁸ For each child, parents were asked to complete the Child Behavior Checklist 1.5–5 years (CBCL 1.5–5), which is an internationally validated questionnaire examining behavioral and emotional problems.¹⁹ For this study, we used the CBCL Total Problems scale expressed in T-scores adjusted for CA at assessment and sex. Assessors and parents were unaware of CC or CCF length measurements.

Statistical Analysis

Because the presence and severity of brain injury in the neonatal period can influence both brain growth and neurodevelopmental outcome disproportionately,²⁰ we mainly focused on the large group of infants without any brain injury on neonatal CUS. To explore the value of the brain growth markers in the presence of brain injury, we performed additional exploratory analyses in the smaller and more heterogeneous group with any extent of neonatal brain injury on CUS. Relative risks for adverse outcomes were calculated comparing infants with and without brain injury.

First, we used nonparametric statistical tests for nonresponse analyses. Second, we used linear regression models to study the associations between length (at birth, 29 weeks’ GA, NICU transfer, and 2 months’ CA) and growth rate (between birth and NICU transfer and between birth and 2 months) of the CCF, CC, and HC and the 4 neurodevelopmental outcomes (motor, cognitive, language, and behavior) at 2 years’ CA in both groups. In the basic models, we adjusted for GA or CA at CUS assessment. The adjusted models were additionally corrected for sex, GA at birth, birth weight z score, and parental education on the basis of relevance reported in the literature.^5,21 These 4 covariates were tested and confirmed to show either a statistical association with at least 1 of the 2 ultrasonic brain markers at 2 months and cognitive outcome or a change in the effect size of >10% after addition of the covariate to the basic model. Given the number of participants and variables in our models and to limit type I or II error, we only performed analyses when at least 40 measurements were available per analysis. For comparability of effect sizes, associations are reported by steps resembling the average IQR of each marker. We observed no significant interactions between any of the brain markers and sex.

Third, we evaluated the added clinical value of the brain markers in predicting neurodevelopmental outcome in infants without brain injury, compared with prediction based on neonatal risk factors and head circumference only. As baseline, a “basic neonatal” regression model was used for prediction of cognitive outcome. This model was recently created in a preterm population overlapping this cohort.²² This model included sex, GA at birth, combined parental education level, grade of bronchopulmonary dysplasia (no/mild/severe), treated patent ductus arteriosus (medically and surgically), brain injury, and the duration of the hospital admission. Because this analysis was performed in the group of infants without any brain injury, we did not include “brain injury” as a covariate in the basic neonatal model of the current study. Using linear hierarchical regression models and explained variances (R²), we compared the basic neonatal model (both with and without HC) with models that additionally included any CUS markers associated with neurodevelopmental outcomes.

P values (2-tailed) < .05 were considered statistically significant. We calculated 95% confidence intervals for all effect estimates. Correction for multiple testing was not deemed necessary given the step-based and exploratory character of the analyses. Data were analyzed using SPSS Statistics, Version 25.0 (IBM) and R statistical and computing software (http://www.r-project.org/).