Your search keyword '"Probabilistic WMI map"' showing total 2 results

1. White matter injury in term neonates with congenital heart diseases: Topology & comparison with preterm newborns

Author

Guo, Ting, Chau, Vann, Peyvandi, Shabnam, Latal, Beatrice, McQuillen, Patrick S, Knirsch, Walter, Synnes, Anne, Feldmann, Maria, Naef, Nadja, Chakravarty, M Mallar, De Petrillo, Alessandra, Duerden, Emma G, Barkovich, A James, and Miller, Steven P

Subjects

Paediatrics, Biomedical and Clinical Sciences, Cardiovascular Medicine and Haematology, Perinatal Period - Conditions Originating in Perinatal Period, Pediatric, Heart Disease, Congenital Heart Disease, Congenital Structural Anomalies, Rare Diseases, Cardiovascular, Preterm, Low Birth Weight and Health of the Newborn, Biomedical Imaging, Reproductive health and childbirth, Brain, Brain Injuries, Female, Heart Defects, Congenital, Humans, Infant, Newborn, Infant, Premature, Magnetic Resonance Imaging, Male, White Matter, Congenital heart disease, White matter injury, Topology, Probabilistic WMI map, Term CHD neonates, Preterm neonates, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biomedical and clinical sciences, Health sciences

Abstract

BackgroundNeonates with congenital heart disease (CHD) are at high risk of punctate white matter injury (WMI) and impaired brain development. We hypothesized that WMI in CHD neonates occurs in a characteristic distribution that shares topology with preterm WMI and that lower birth gestational age (GA) is associated with larger WMI volume.Objective(1) To quantitatively assess the volume and location of WMI in CHD neonates across three centres. (2) To compare the volume and spatial distribution of WMI between term CHD neonates and preterm neonates using lesion mapping.MethodsIn 216 term born CHD neonates from three prospective cohorts (mean birth GA: 39 weeks), WMI was identified in 86 neonates (UBC: 29; UCSF: 43; UCZ: 14) on pre- and/or post-operative T1 weighted MRI. WMI was manually segmented and volumes were calculated. A standard brain template was generated. Probabilistic WMI maps (total, pre- and post-operative) were developed in this common space. Using these maps, WMI in the term CHD neonates was compared with that in preterm neonates: 58 at early-in-life (mean postmenstrual age at scan 32.2 weeks); 41 at term-equivalent age (mean postmenstrual age at scan 40.1 weeks).ResultsThe total WMI volumes of CHD neonates across centres did not differ (p = 0.068): UBC (median = 84.6 mm3, IQR = 26-174.7 mm3); UCSF (median = 104 mm3, IQR = 44-243 mm3); UCZ (median = 121 mm3, IQR = 68-200.8 mm3). The spatial distribution of WMI in CHD neonates showed strong concordance across centres with predilection for anterior and posterior rather than central lesions. Predominance of anterior lesions was apparent on the post-operative WMI map relative to the pre-operative map. Lower GA at birth predicted an increasing volume of WMI across the full cohort (41.1 mm3 increase of WMI per week decrease in gestational age; 95% CI 11.5-70.8; p = 0.007), when accounting for centre and heart lesion. While WMI in term CHD and preterm neonates occurs most commonly in the intermediate zone/outer subventricular zone there is a paucity of central lesions in the CHD neonates relative to preterms.ConclusionsWMI in term neonates with CHD occurs in a characteristic topology. The spatial distribution of WMI in term neonates with CHD reflects the expected maturation of pre-oligodendrocytes such that the central regions are less vulnerable than in the preterm neonates.

Published

2019

2. White matter injury in term neonates with congenital heart diseases: Topology & comparison with preterm newborns

Author

Patrick S. McQuillen, Vann Chau, Anne Synnes, M. Mallar Chakravarty, A. James Barkovich, Walter Knirsch, Emma G. Duerden, Steven P. Miller, Maria Feldmann, Alessandra De Petrillo, Beatrice Latal, Ting Guo, Nadja Naef, Shabnam Peyvandi, University of Zurich, and Miller, Steven P

Subjects

Male, Neurology, Heart disease, Cardiovascular, Low Birth Weight and Health of the Newborn, Medical and Health Sciences, Topology, Congenital, 0302 clinical medicine, Infant Mortality, Medicine, Heart Defects, Pediatric, 05 social sciences, Brain, Gestational age, Preterm neonates, Magnetic Resonance Imaging, White Matter, Cohort, Female, Term CHD neonates, Patient Safety, medicine.symptom, Infant, Premature, Heart Defects, Congenital, 2805 Cognitive Neuroscience, medicine.medical_specialty, Concordance, Cognitive Neuroscience, 610 Medicine & health, Article, 050105 experimental psychology, Lesion, 03 medical and health sciences, Probabilistic WMI map, Preterm, Clinical Research, Humans, White matter injury (WMI), 0501 psychology and cognitive sciences, 10220 Clinic for Surgery, Premature, Congenital heart disease, Neurology & Neurosurgery, White matter injury, business.industry, Psychology and Cognitive Sciences, Congenital heart disease (CHD), Neurosciences, Infant, Newborn, White Matter Injury, Postmenstrual Age, Infant, Perinatal Period - Conditions Originating in Perinatal Period, Newborn, medicine.disease, 10036 Medical Clinic, Brain Injuries, 2808 Neurology, business, 030217 neurology & neurosurgery

Abstract

Background Neonates with congenital heart disease (CHD) are at high risk of punctate white matter injury (WMI) and impaired brain development. We hypothesized that WMI in CHD neonates occurs in a characteristic distribution that shares topology with preterm WMI and that lower birth gestational age (GA) is associated with larger WMI volume. Objective (1) To quantitatively assess the volume and location of WMI in CHD neonates across three centres. (2) To compare the volume and spatial distribution of WMI between term CHD neonates and preterm neonates using lesion mapping. Methods In 216 term born CHD neonates from three prospective cohorts (mean birth GA: 39 weeks), WMI was identified in 86 neonates (UBC: 29; UCSF: 43; UCZ: 14) on pre- and/or post-operative T1 weighted MRI. WMI was manually segmented and volumes were calculated. A standard brain template was generated. Probabilistic WMI maps (total, pre- and post-operative) were developed in this common space. Using these maps, WMI in the term CHD neonates was compared with that in preterm neonates: 58 at early-in-life (mean postmenstrual age at scan 32.2 weeks); 41 at term-equivalent age (mean postmenstrual age at scan 40.1 weeks). Results The total WMI volumes of CHD neonates across centres did not differ (p = 0.068): UBC (median = 84.6 mm3, IQR = 26–174.7 mm3); UCSF (median = 104 mm3, IQR = 44–243 mm3); UCZ (median = 121 mm3, IQR = 68–200.8 mm3). The spatial distribution of WMI in CHD neonates showed strong concordance across centres with predilection for anterior and posterior rather than central lesions. Predominance of anterior lesions was apparent on the post-operative WMI map relative to the pre-operative map. Lower GA at birth predicted an increasing volume of WMI across the full cohort (41.1 mm3 increase of WMI per week decrease in gestational age; 95% CI 11.5–70.8; p = 0.007), when accounting for centre and heart lesion. While WMI in term CHD and preterm neonates occurs most commonly in the intermediate zone/outer subventricular zone there is a paucity of central lesions in the CHD neonates relative to preterms. Conclusions WMI in term neonates with CHD occurs in a characteristic topology. The spatial distribution of WMI in term neonates with CHD reflects the expected maturation of pre-oligodendrocytes such that the central regions are less vulnerable than in the preterm neonates.

Published

2019