Predictive and diagnostic measures for kernicterus spectrum disorder: a prospective cohort study.

BACKGROUND: Kernicterus spectrum disorder (KSD) resulting from neonatal hyperbilirubinemia remains a common cause of cerebral palsy worldwide. This 12-month prospective cohort study followed neonates with hyperbilirubinemia to determine which clinical measures best predict KSD. METHODS: The study enrolled neonates ≥35 weeks gestation with total serum bilirubin (TSB) ≥ 20 mg/dl admitted to Aminu Kano Hospital, Nigeria. Clinical measures included brain MRI, TSB, modified bilirubin-induced neurologic dysfunction (BIND-M), Barry-Albright Dystonia scale (BAD), auditory brainstem response (ABR), and the modified KSD toolkit. MRI signal alteration of the globus pallidus was scored using the Hyperbilirubinemia Imaging Rating Tool (HIRT). RESULTS: Of 25 neonates enrolled, 13/25 completed 12-month follow-up and six developed KSD. Neonatal BIND-M ≥ 3 was 100% sensitive and 83% specific for KSD. Neonatal ABR was 83% specific and sensitive for KSD. Neonatal HIRT score of 2 was 67% sensitive and 75% specific for KSD; this increased to 100% specificity and sensitivity at 12 months. BAD ≥ 2 was 100% specific for KSD at 3-12 months, with 50-100% sensitivity. CONCLUSIONS: Neonatal MRIs do not reliably predict KSD. BIND-M is an excellent screening tool for KSD, while the BAD or HIRT score at 3 or 12 months can confirm KSD, allowing for early diagnosis and intervention. IMPACT: The first prospective study of children with acute bilirubin encephalopathy evaluating brain MRI findings over the first year of life. Neonatal MRI is not a reliable predictor of kernicterus spectrum disorders (KSD). Brain MRI at 3 or 12 months can confirm KSD. The modified BIND scale obtained at admission for neonatal hyperbilirubinemia is a valuable screening tool to assess risk for developing KSD. The Barry Albright Dystonia scale and brain MRI can be used to establish a diagnosis of KSD in at-risk infants as early as 3 months.

Examining diagnostic variability among pediatric subspecialists using case examples of infant head injury.

BACKGROUND: Although there is research regarding the diagnosis and timing of abusive head trauma, there remains practice variation among pediatric subspecialists. OBJECTIVES: To examine diagnostic variability among pediatric subspecialists using case examples of infant head injury. Secondary objectives were timing variability among subspecialists, and diagnostic and timing variability among Child Abuse Pediatricians (CAPs). PARTICIPANTS AND SETTING: Pediatric subspecialists were recruited from Child Abuse Pediatrics, Hospital Medicine, Emergency Medicine, Critical Care, and Neurosurgery to complete a research instrument. Participants qualified for the study if they evaluated at least 1 case of possible abusive head trauma during their career. METHODS: This multi-institutional, mixed-methods study used a research instrument with 4 case examples of infant head injury: severe retinal hemorrhages (RH), mass-effect subdural hemorrhage (SDH), SDH membrane formation, and sepsis. The response selected by most CAPs was reference and compared across subspecialties and among CAPs using Chi-square or Fisher's exact tests. A Bonferroni correction (p < 0.01) was used for subspecialty comparisons. RESULTS: There were 288 participants who completed at least 1 case example. Diagnostic variability was observed in all case examples. Significantly fewer Hospital Medicine (34.9 % vs. 57.9 %, p < 0.01), Emergency Medicine (28.0 % vs. 57.9 %, p < 0.0001), and Neurosurgery (24.0 % vs. 57.9 %, p < 0.01) participants selected the reference response for the mass-effect SDH case example. Timing variability was statistically significant for all case examples (p < 0.01). Significantly fewer CAPs aged 44-64 years selected the reference response for timing (p < 0.01) for the severe RH case example. CONCLUSIONS: Additional peer review processes and consensus guidelines for challenging issues in abusive head trauma may be beneficial.

Internal carotid artery position to characterize risk for vessel injury in pediatric intraoral trauma.

OBJECTIVE: The internal carotid artery (ICA) lies in close anatomic proximity to the oropharynx and is at risk for injury in the instance of intraoral trauma. The objectives of this study are to describe the position of the ICA relative to the oropharynx and identify patient risk factors related to its position. METHODS: A total of 100 patients aged 12 months to 7 years 11 months who received computed tomography (CT) of the neck were randomly selected. The position of the ICA was determined by measuring its angular location relative to the center of the oropharynx (ICA angle) and the shortest distance from the oropharyngeal surface (OP-ICA distance). RESULTS: Indication for imaging was controlled for in all reported data. Patient age was related to ICA angles on both the left (F = 8.06; P = 0.01; η2 = 0.08, 95% CI: 0.01-0.19) and right (F = 18.62; P < 0.001; η2 = 0.17, 95% CI: 0.05-0.29). Patient weight also was related to ICA angles on both the left (F = 7.08; P = 0.01; η2 = 0.07, 95% CI: 0.01-0.18) and right (F = 11.86; P < 0.001; η2 = 0.11, 95% CI: 0.02-0.24). Patient age was related to the left OP-ICA distance (F = 7.36; P = 0.01; η2 = 0.07, 95% CI: 0.01-0.19), as was patient weight (F = 4.82; P = 0.03; η2 = 0.05, 95% CI: 0.00-0.15). Across all measurements, no significant relationship was identified between ICA position and other patient variables, including sex and race/ethnicity. CONCLUSION: The ICA of younger patients and those with lower body weight may be located more medially within the neck and closer to the oropharyngeal surface. This vessel position may place these children at greater anatomic susceptibility for ICA injury in the event of intraoral trauma.

Pre-Surgical Planning: Multimodality Imaging to Optimize Outcomes in Pediatric Epilepsy Surgery.

Neuroimaging is an important component of the pre-surgical planning for pediatric epilepsy. High-resolution structural magnetic resonance images are combined with advanced structural and functional imaging techniques to better define the surgical lesion and decrease morbidity postoperatively. The combination of neuroimaging, electroencephalography (EEG), and neuropsychiatric testing in a multidisciplinary epilepsy conference setting is essential for determining a plan for surgical management.