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Logo of nihpaAbout Author manuscriptsSubmit a manuscriptNIH Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
Pediatrics. Author manuscript; available in PMC Nov 22, 2010.
Published in final edited form as:
PMCID: PMC2989661
NIHMSID: NIHMS246922

Neonatal Cranial Ultrasound Lesions and Developmental Delays at 2 Years of Age Among Extremely Low Gestational Age Children

T. Michael O’Shea, MD, MPH,a Karl C. K. Kuban, MD, SMEpi,b Elizabeth N. Allred, MS,c,d Nigel Paneth, MD, MPH,e Marcello Pagano, PhD,d Olaf Dammann, MD,f Lisa Bostic, OTR/L,g Kara Brooklier, PhD,h Samantha Butler, PhD,i Donald J. Goldstein, PhD,a Gail Hounshell, PhD,a Cecelia Keller, PT, MHA,f Susan McQuiston, PhD,j Alice Miller, PT, MS,k Steve Pasternak, PhD,l Susan Plesha-Troyke, OT,m Joan Price, EdS,n Elaine Romano, MSN,o Katherine M. Solomon, PhD,h Amanda Jacobson, PT,g Sjirk Westra, MD,p and Alan Leviton, MD, MSc, for the Extremely Low Gestational Age Newborns Study Investigators

Abstract

BACKGROUND

Studies of the relationship between ultrasound images from preterm newborns and developmental delay most often are based on small samples defined by birth weight and exclude infants not testable with standardized assessments.

METHODS

We evaluated associations between ultrasound-defined lesions of the brain and developmental delays at 24 months’ corrected age in 1017 children born before the 28th postmenstrual week. Brain ultrasound scans were read for concordance on 4 lesions: intraventricular hemorrhage, moderate/severe ventriculomegaly, white matter echodense/hyperechoic lesions, and white matter echodense/hypoechoic lesions and 2 diagnoses–periventricular leukomalacia and periventricular hemorrhagic infarction. Certified examiners, who were not aware of the infants’ ultrasound findings, administered the Bayley Scales of Infant Development-Second Edition. Children with an impairment (eg., blindness) that precluded testing with the Bayley Scales and those for whom >2 test items were omitted were classified using the Vineland Adaptive Behavior Scales Motor Skills Domain instead of the Psychomotor Development Index and the Adaptive Behavior Composite instead of the Mental Development Index.

RESULTS

Fully 26% of all of the children had delayed mental development (ie, Mental Development Index < 70), and 31% had delayed psychomotor development (ie, Psychomotor Development Index < 70). Ultrasound abnormalities were more strongly associated with low Psychomotor Development Index than with low Mental Development Index. Children without cranial ultrasound abnormality had the lowest probability (23% and 26%) of delayed mental or psychomotor development. Moderate/severe ventriculomegaly was associated with a more than fourfold increase in the risk of psychomotor delay and an almost threefold increase in the risk of mental delay. Echolucency was the next best predictor of delayed mental and psychomotor development. The probability of low scores varied with the number of zones involved and with the location of echolucency. At particularly high risk were infants with bilateral cerebellar hemorrhage, co-occurring ventriculomegaly and echolucency bilateral echolucency, or echolucency located posteriorly.

CONCLUSIONS

Focal white matter damage, as characterized by echolucent/hypoechoic lesion, and diffuse damage, as suggested by late ventriculomegaly, are associated with delayed mental and psychomotor development.

Keywords: prematurity, cognitive development, intraventricular hemorrhage, periventricular leukomalacia, neonatal follow-up, Bayley Scales of Infant Development

Cranial ultrasonography is widely used to identify neonates at increased risk for neurodevelopmental impairment.13 Attempts to summarize studies of the predictive value of cranial ultrasound abnormalities are made difficult by inconsistent approaches to classifying abnormalities.4 However, in low birth weight58 and preterm newborns,913 cranial ultrasound abnormalities indicative of white matter damage4 are the strongest predictors of cerebral palsy and developmental delay. The purpose of this study was to describe relationships between cranial ultrasound abnormalities and delayed development at 2 years of age in a large cohort of extremely premature infants. Elsewhere we report on relationships between ultrasound abnormalities and cerebral palsy.14

METHODS

The Extremely Low Gestational Age Newborns Study

The Extremely Low Gestational Age Newborns (ELGAN) study was designed to identify characteristics and exposures that increase the risk of structural and functional neurologic disorders in extremely low gestational age newborns. During the years 2002–2004, women delivering before 28 weeks’ gestation at 1 of 14 participating institutions in 11 cities in 5 states were asked to enroll in the study. At each site, the study protocol was approved by an institutional review board.

Mothers were approached for consent before or shortly after delivery, depending on clinical circumstance and institutional preference. A total of 1249 mothers of 1506 infants consented. Approximately 260 women were missed or did not agree to participate.

Cranial Ultrasound Scans

Routine scans were performed by technicians at all of the hospitals using digitized high-frequency transducers (7.5 and 10.0 MHz). Ultrasound studies always included 6 standard paracoronal views and 5 parasagittal views through the anterior fontanel.15

Of 1506 infants enrolled, 1445 had ≥1 set of protocol ultrasound scans, and 895 had all 3 of the sets. Protocol 1 scans were obtained between the first and fourth day (n = 1123); protocol 2 scans, between the fifth and 14th day (n = 1302); and protocol 3 scans, between the 15th day and the 40th week postmenstrual age (n = 1268). In this article we refer to protocol 1 and 2 scans as “early” and protocol 3 scans as “late.”

Previously we have described efforts taken in the ELGAN study to enhance the reliability of ultrasound readings.16 Before patient enrollment, sonologists created a manual and data collection form and conducted reliability training exercises. During the study, each set of scans was first read by 1 study sonologist at the institution of the infant’s birth. Digital images were then sent to a sonologist at another study institution for a second reading. When the 2 readers differed in their recognition of intraventricular hemorrhage (IVH), ventriculomegaly, echodensity, and echolucency, films were sent to a third (tie-breaking) reader who did not know what the initial readers reported.

Definitions of Ultrasound Abnormalities

Germinal matrix hemorrhage (GMH) was defined as blood localized to the subependymal region and IVH as blood within the ventricles. IVH excluded hemorrhage localized to the subependymal region. Ventriculomegaly, categorized as mild, moderate, and severe, was defined visually with a template on the data collection form.16 Our emphasis was on moderate/severe ventriculomegaly, which was diagnosed if a lateral ventricle was at least moderately enlarged in any of 4 sections (frontal horn, body, and occipital horn).

Developmental Assessment at 24 Months

Families were invited to bring their child for developmental assessment close to the time when he or she would attain 24 months’ corrected age. This assessment included the Bayley Scales of Infant Development-Second Edition (BSID-II), a neurologic examination, and, when necessary, an interview of the parent using the Vineland Adaptive Behavior Scales.17 Fully 77% were assessed within the range of 23.5 to 27.9 months; of the others, approximately half were assessed before 23.5 months and approximately half after 27.9 months. In this article, the terms “delayed mental development” and “delayed psychomotor development” refer, respectively, to a Mental Developmental Index (MDI) of <70 and Psychomotor Developmental Index (PDI) of <70.18

Bayley Scales of Infant Development-Second Edition

Certified examiners administered and scored the BSID-II.18 All of the examiners had previous experience with the BSID-II and attended a 1-day workshop at which the published guidelines for test administration and videotaped examinations were viewed and discussed. Examiners were aware of infants’ enrollment in the ELGAN study but were not informed of any specifics of the child’s medical history. Before testing, examiners were told the child’s corrected age; after testing they were told the birth date so that unadjusted BSID-II scores could be assigned.

When a child’s impairment(s) precluded administration of the BSID-II or >2 items were omitted or judged to be “unscoreable,” the child was classified as not testable on that scale. Children considered nontestable with the BSID-II were assessed with the Vineland Adaptive Behavior Scales (VABS). Those with VABS Adaptive Behavior Composite (ABC) <70 were combined with infants with an MDI of <70; those with ABC ≥70 were combined with infants whose MDI was ≥70. Among infants nontestable with the BSID-II motor scale, those with a VABS motor skills domain score <70 were combined with infants whose PDI was <70; those with a score ≥70 were combined with infants with a PDI of ≥70.

Data Analysis

For each ultrasound lesion, we computed the proportion of children who had an MDI or PDI of <70. To describe the strength of association between ultrasound lesions and developmental delay, we calculated risk ratios (RRs) and 95% confidence intervals (CIs) and adjusted for gestational age, antenatal glucocorticoid exposure, and medical care insurance at the time of the examination (private versus public), a surrogate for socioeconomic status.

RESULTS

Figure 1 depicts the study sample. Of the 257 deaths, 235 deaths occurred in the NICU. Comparing the 1017 infants who survived to 24 months’ adjusted age and were assessed for mental and motor development with the 181 infants who survived but did not undergo a complete developmental assessment, the latter had mothers who were younger, less well educated, less likely to be married, less likely to support themselves via their own employment, and more likely to have Medicaid or other public insurance, but the 2 groups did not differ with regard to gender, plurality, gestational age, birth weight, birth weight z score, Score for Neonatal Acute Physiology II, or the frequency of ultrasound lesions.

FIGURE 1
Description of the study sample. HUS indicates cranial ultrasound.

Infants Not Testable With the BSID-II

The VABS ABC was obtained for 26 of 33 children who were nontestable with the BSID-II mental scale, and 23 had ABC <70. The VABS motor skills domain score was obtained for 32 of 38 children nontestable with the BSID-II motor scale, and 27 had a motor skills domain <70. Based on either the BSID-II or the VABS, 26% of study infants (n = 269) had delayed mental development, and 31% (n = 314) had delayed psychomotor development.

Overview

Among children whose scans showed IVH, only 32% had no other ultrasound abnormality (Table 1). Fully 42% had ventriculomegaly, 43% had a white matter echodensity, and 20% had a white matter echolucency. Thus, the findings presented here should be seen as conveying overlapping information. Among the 716 study children who had no ultrasound abnormality, 23% had delayed mental development, and 26% had delayed psychomotor development. Ultrasound abnormalities were more strongly associated with delayed psychomotor development than delayed mental development. The finding of ventriculomegaly and the diagnosis of periventricular hemorrhagic infarction (PVHI) were associated with a doubling of the risk of delayed mental development; other abnormalities were associated with more modest increases in risk. Ventriculomegaly, echolucency, and diagnoses of cystic periventricular leukomalacia (PVL) or PVHI were associated with the highest risks (57%–60%) of delayed psychomotor development. Depending on the presence of other ultrasound abnormalities, between 80% and 100% of children who had both ventriculomegaly and echolucency had delayed psychomotor development.

TABLE 1
Percentage of Children Who Had the Ultrasound Lesion Listed on the Left Who Had BSID-II Scores of <70

Hemorrhage

Unilateral GMH predicted delayed mental development as well as bilateral GMH, and better than unilateral IVH (Table 2). Generally, blood in the germinal matrix or any ventricle predicted delayed psychomotor development better than it predicted delayed mental development. Children who had bilateral cerebellar hemorrhages were at highest risk of developmental delays.

TABLE 2
Percentage of Infants Whose Scan Had a Hemorrhage (Probable or Definite) in the Location Listed on the Left, Who Had BSID-II Scores of <70

Early and Late Moderate/Severe Ventriculomegaly

Almost all of the children with ventriculomegaly had diffuse ventriculomegaly (Table 3). Consequently, enlargement of a particular area of the ventricle did not convey appreciably more predictive information about MDI or PDI scores than any other area. Except in the case of unilateral ventriculomegaly as a predictor of an MDI of <70, risks of developmental delays were higher among children with late, as compared with early, ventriculomegaly. However, rates of these delays were similar for children with bilateral, as compared with unilateral, ventriculomegaly.

TABLE 3
Percentage of Infants Whose Scan Had Ventriculomegaly (Moderate or Severe) Identified Either on the First or Second Study (Early Scan) or on the Third Study (Late Scan) Unilaterally or Bilaterally, Who Had BSID-II Scores of <70

Laterality of Echodense and Echolucent Lesions

Unilateral echodensity did as well as bilateral echodensity and unilateral echolucency in predicting developmental delays but not as well as bilateral echolucency (Table 4). Among infants with unilateral echodensity, those with right-sided echodensity more often had delayed mental development, whereas, among infants with unilateral echolucency, those with left-sided echolucency more often had delayed psychomotor development.

TABLE 4
Percentage of Infants With Echodensity or Echolucency Who Had BSID-II Scores of <70

Extent of Echodensity and Echolucency Lesions

The risks of delayed mental or psychomotor developments increased as the numbers of zones with unilateral echodensity increased; similarly, the risk of delayed mental development increased as the number of zones with bilateral echolucency increased (data not shown). No trends were apparent for the relationship between the number of zones of bilateral echodensity or unilateral echolucency and delayed development.

Location of Echodensity and Echolucency Lesions

Risks of delayed mental and psychomotor development were higher when echolucency was found in posterior zones as compared with anterior zones (Table 5 and Fig 2). The 16 children who had an echolucency in the parietal-occipital white matter seen high on the “over-the-top” view were at very high risk of delayed psychomotor (88%) and mental development (75%). Infants with echolucency in the 3 zones located closest to the motor cortex did not have a higher rate of delayed psychomotor development than infants with echolucency confined to other zones. An echolucency in the paraventricular white matter seen on the “trigone” view also conveyed high risks of delayed psychomotor development.

FIGURE 2
Percentage of children whose scan had an echolucency in a particular location and who had an MDI of <70 (black numbers on the left side of the brain) or a PDI of <70 (black numbers on the right side of the brain) on the BSID-II. The letters ...
TABLE 5
Percentage of Infants Whose Scan Had an Echodensity or Echolucency in Any of the Anterior or Posterior Zones Who Had BSID-II Scores of <70

RRs and Test Characteristics

The highest RR for delayed mental development was associated with ventriculomegaly (RR: 2.70 [95% CI: 1.70–4.10]), followed by PVHI (RR: 1.90 [95% CI: 1.05–2.40]). Ventriculomegaly had the highest RR for delayed psychomotor development (RR: 4.40 [95% CI: 2.90–6.90]), followed by PVHI (RR: 3.90 [95% CI: 2.20–7.10]), echolucency (RR: 3.70 [95% CI: 2.30–6.10]), and cystic PVL (RR: 3.60 [95% CI: 2.20–7.10]). The predictive value of an ultrasound with ventriculomegaly or echolucency was 45% to 61%, which corresponds with likelihood ratios of 2.0 to 2.5. Because the sensitivity of these findings was low, the negative likelihood ratio for the absence of ventriculomegaly and echolucency is only slightly <1 (Tables 6 and and77).

TABLE 6
RRs and 95% CIs for a Bayley Scale Scores of <70, Calculated Separately for MDI and PDI Associated With Each Ultrasound Lesion or Diagnosis
TABLE 7
Measures of the Ability of Head Ultrasound Abnormalities Evident Before Discharge From the NICU to Predict an MDI or PDI >2 SDs Below the Expected Mean at 24 Months’ Corrected Age

DISCUSSION

We evaluated the relationship between neonatal cranial ultrasound findings and standardized developmental assessments in extremely low gestational age neonates. As have others, we found that cranial ultrasound abnormalities are more strongly associated with delayed development of skills assessed with the PDI than those assessed with the MDI5,1921 and that ventriculomegaly and echolucency are the ultrasound findings associated most strongly with delayed infant development.9,22 Among ultrasound diagnoses, cystic PVL and PVHI are associated most strongly with developmental delay,5,12,13 although bilateral cerebellar hemorrhage, found in 1% of our cohort, may be comparably predictive of adverse outcome. The lower predictive value of echodensity is to be expected, because the reliability of cranial ultrasound interpretations used in our study was lower for echodensity (κ = 0.3), as compared with IVH, ventriculomegaly, and echolucency (κ > 0.6).16 The frequency of an MDI of <70 described here (26%) is similar to that observed in a cohort born at 23 to 27 weeks,23 and the rate that we observed among infants without ultrasound abnormalities (23%) is similar to that of a cohort with a birth weight of 401 to 1000 g.24

We found evidence that the risk of developmental delay varies with laterality, location, and extent of white matter abnormalities. For example, bilateral echolucency was associated more strongly with delayed development than unilateral echolucency.3,25,26 Unexpected are our findings that unilateral ventriculomegaly is as strongly associated with low PDI as is bilateral ventriculomegaly and that unilateral echodensity is as strongly associated with low BSID-II scores as is bilateral echodensity.

Others have found that ultrasound abnormalities are associated with a twofold to fourfold increase in the risk of low BSID-II scores5 and mental retardation.27 These include the findings of ventriculomegaly and echolucency, which most often are seen after the initial scan9,10,28,29; the diagnosis of PVHI, which often is present on scans performed in the first weeks of life3032; and cystic PVL, which typically is not present until several weeks after birth.9,28,29

In the only study we found that assessed whether the hemispheric side of white matter lesions influences developmental outcome, intelligence quotients were higher and visual motor integration was better at 8 years of age among children born preterm who had right-sided cerebral lesions as compared with those with left-sided lesions.25 In the current study, infants with right-sided echolucency had better scores for PDI, but those with right-sided echodensity had worse scores for MDI. Most likely these right-left differences are because of random variation.

In this study, unilateral ventriculomegaly seen on early ultrasound (ie, the first 14 days) was more predictive of low BSID-II than was bilateral ventriculomegaly. In contrast, fetuses with unilateral33 or bilateral ventriculomegaly34 typically have normal developmental outcome.

The stronger association between cranial ultrasound abnormalities and a PDI of <70, as compared with an MDI of <70, might relate, in part, to the greater contribution of periventricular brain structures, such as corticospinal tracts, to functions assessed with the PDI, such as perceptual-motor integration, sensory integration, and quality of movement.18 On the other hand, substantial white matter is located in associative areas, which influence cognitive abilities, such as those assessed with the MDI (eg, memory, problem-solving skills, and language development). In addition, children who have early imaging evidence of periventricular white matter damage also have reduced cortical volume.35 This has been attributed to damage to myelin-producing cells36 and neurons, which migrate to the cortex through injured white matter.37 Such damage might be more diffuse and widespread with ventriculomegaly and more focal with echolucency.

The importance of the cerebellum in cognitive development is supported by studies correlating cerebellar size and scores on cognitive testing38 and studies of developmental outcome after cerebellar hemorrhage.39,40 After the advent of neonatal intensive care, cerebellar hemorrhage was described in autopsy studies of preterm infants.41 After ultrasound imaging improved, this lesion could be identified in surviving infants.39,40 As have others,42 we found that ~3 of every 4 infants with cerebellar hemorrhage had delayed psychomotor development and that more than half had delayed mental development.

If ultrasound detected all, or most, white matter damage, we would expect the risk of low BSID-II scores to be higher with bilateral, as compared with unilateral, ventriculomegaly and with bilateral, as compared with unilateral, echodensity; but we observed neither. In addition, the risk of low BSID-II scores did not increase in a graded fashion with an increasing extent of unilateral echolucency. Finally, as reported by others,24 we found that approximately one quarter of extremely premature infants with normal ultrasounds have BSID-II scores <70.

The most parsimonious explanation for these findings is that ultrasound detects only a fraction of the total white matter damage. Support for this hypothesis, referred to as the “tip-of-the-iceberg” hypothesis,36 comes from studies correlating ultrasound findings with either MRI43,44 or postmortem examination.45 In addition, ~50% of infants who develop cerebral palsy have ultrasound abnormality.7,46,47 A likely explanation for our finding that echodensity and echolucency were found predominantly in zones located superior to the lateral ventricles and were infrequently seen in zones closest to the temporal lobes and zones closest to the occipital lobes is better visualization of the superior aspects of the brain when using an ultrasound through the anterior fontanelle.

Perhaps the main limitation of this study was our dependence on ultrasound to identify white matter damage. Early MRI does a much better job, especially of detecting diffuse white matter damage.4850 Thus, the study might have misclassified some scans as not showing white matter damage, when, indeed, an MRI would have identified white matter damage.

Strengths of this study include the large sample51 based on gestational age rather than birth weight,52 efforts to minimize interobserver disagreements about ultrasound findings,16 efforts to standardize the administration of the BSID-II and minimize examiners’ knowledge of the infants’ clinical histories, and the high proportion of infants with ultrasounds obtained after the first month of life, when white matter damage may be seen for the first time.9 Finally, to classify study participants who were not testable with the BSID, we used proxy measures of developmental status in an effort to decrease bias (ie, “missing clinical data bias”53).

The most important implication of our study is that clinicians can use ultrasound markers of white matter damage (ventriculomegaly, echodensity, and echolucency4,36,45,54) as predictors of developmental impairment.13,25,27,55 Children with these markers can be targeted for early intervention to improve developmental outcome.56,57 This use of ultrasound is part of the basis for the Practice Parameter for Neuroimaging of the Neonate in 2002,41 which recommends cranial ultrasound screening for infants born before 30 weeks’ gestation, at 7 to 14 days, and again at 36 to 40 weeks. In a study of very preterm infants, the sensitivity of major ultrasound abnormalities (ie, Papile grade III hemorrhage, echodensity, echolucency, and basal ganglia lesions) for prediction of cerebral palsy was 95% and the specificity was 99%.9 The sensitivity and specificity are lower for the prediction of other developmental impairments, particularly nonmotor impairments. In a multicenter study of 2103 infants, the sensitivity, specificity, and likelihood ratio positive for cystic PVL for identifying infants with a PDI of <70 were, respectively, 0.30, 0.80, and 6.00,58 as compared with the values reported here for echolucency (0.14, 0.96, and 3.50). Similar likelihood ratios for the prediction of a PDI of <70 were reported from studies of an index of chronic physiologic instability59 and the Nursery Neurobiological Risk Score.60 Thus, when the clinical goal is prediction of low scores on the BSID-II, other clinical information may be complementary to,59 or even more valuable than,58 cranial ultrasonography. Alternative methods, such as MRI48,49 or more frequent scanning with ultrasound,9 might improve the predictive value of neuroimaging. Nonetheless, the information provided here can be used cautiously to counsel parents and plan for developmental services for infants at high risk.

What’s Known on This Subject

In low birth weight and preterm newborns, cranial ultrasound abnormalities indicative of white matter damage are the strongest predictors of cerebral palsy and developmental delays.

What This Study Adds

The association of cerebral white matter damage and developmental impairments applies to extremely low gestational age newborns. The association is stronger for motor, as compared with mental, development. Cerebellar hemorrhage is strongly associated with delayed mental and motor development.

Acknowledgments

Financial support for this research was provided by National Institute of Neurological Disorders and Stroke grant NS 40069.

We thank Rebecca Helms, PhD (East Carolina University) and Lynn Whitley, PhD (East Carolina University) for completing some of the developmental assessments on which this article was based.

Abbreviations

ELGAN
Extremely Low Gestational Age Newborn
IVH
intraventricular hemorrhage
GMH
germinal matrix hemorrhage
BSID-II
Bayley Scales of Infant Development-Second Edition
MDI
Mental Development Index
PDI
Psychomotor Development Index
VABS
Vineland Adaptive Behavior Scales
ABC
Adaptive Behavior Composite
PVHI
periventricular hemorrhagic infarction
PVL
periventricular leukomalacia
CI
confidence interval
RR
risk ratio

Footnotes

The authors have indicated they have no financial relationships relevant to this article to disclose.

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