Your search keyword '"Egloff, Alexia"' showing total 13 results

1. Executive Function in Preschool Children with Congenital Heart Disease and Controls: The Role of a Cognitively Stimulating Home Environment

Author

Chew, Andrew T.M., Bonthrone, Alexandra F., Alford, Arezoo, Kelly, Christopher, Pushparajah, Kuberan, Egloff, Alexia, Hajnal, Joseph V., Simpson, John, Rutherford, Mary, Edwards, A. David, Nosarti, Chiara, and Counsell, Serena J.

Published

2024

2. Structural Covariance Networks in the Fetal Brain Reveal Altered Neurodevelopment for Specific Subtypes of Congenital Heart Disease.

Author

Wilson, Siân, Cromb, Daniel, Bonthrone, Alexandra F., Uus, Alena, Price, Anthony, Egloff, Alexia, Van Poppel, Milou P. M., Steinweg, Johannes K., Pushparajah, Kuberan, Simpson, John, Lloyd, David F. A., Razavi, Reza, O'Muircheartaigh, Jonathan, Edwards, A. David, Hajnal, Joseph V., Rutherford, Mary, and Counsell, Serena J.

Published

2024

3. Total and Regional Brain Volumes in Fetuses With Congenital Heart Disease.

Author

Cromb, Daniel, Uus, Alena, Van Poppel, Milou P.M., Steinweg, Johannes K., Bonthrone, Alexandra F., Maggioni, Alessandra, Cawley, Paul, Egloff, Alexia, Kyriakopolous, Vanessa, Matthew, Jacqueline, Price, Anthony, Pushparajah, Kuberan, Simpson, John, Razavi, Reza, DePrez, Maria, Edwards, David, Hajnal, Jo, Rutherford, Mary, Lloyd, David F.A., and Counsell, Serena J.

Subjects

CONGENITAL heart disease, CONVOLUTIONAL neural networks, FETAL brain, FETUS, GRAY matter (Nerve tissue)

Abstract

Background: Congenital heart disease (CHD) is common and is associated with impaired early brain development and neurodevelopmental outcomes, yet the exact mechanisms underlying these associations are unclear. Purpose: To utilize MRI data from a cohort of fetuses with CHD as well as typically developing fetuses to test the hypothesis that expected cerebral substrate delivery is associated with total and regional fetal brain volumes. Study Type: Retrospective case–control study. Population: Three hundred eighty fetuses (188 male), comprising 45 healthy controls and 335 with isolated CHD, scanned between 29 and 37 weeks gestation. Fetuses with CHD were assigned into one of four groups based on expected cerebral substrate delivery. Field Strength/Sequence: T2‐weighted single‐shot fast‐spin‐echo sequences and a balanced steady‐state free precession gradient echo sequence were obtained on a 1.5 T scanner. Assessment: Images were motion‐corrected and reconstructed using an automated slice‐to‐volume registration reconstruction technique, before undergoing segmentation using an automated pipeline and convolutional neural network that had undergone semi‐supervised training. Differences in total, regional brain (cortical gray matter, white matter, deep gray matter, cerebellum, and brainstem) and brain:body volumes were compared between groups. Statistical Tests: ANOVA was used to test for differences in brain volumes between groups, after accounting for sex and gestational age at scan. PFDR‐values <0.05 were considered statistically significant. Results: Total and regional brain volumes were smaller in fetuses where cerebral substrate delivery is reduced. No significant differences were observed in total or regional brain volumes between control fetuses and fetuses with CHD but normal cerebral substrate delivery (all PFDR > 0.12). Severely reduced cerebral substrate delivery is associated with lower brain:body volume ratios. Data Conclusion: Total and regional brain volumes are smaller in fetuses with CHD where there is a reduction in cerebral substrate delivery, but not in those where cerebral substrate delivery is expected to be normal. Evidence Level: 3 Technical Efficacy: Stage 3 [ABSTRACT FROM AUTHOR]

Published

2024

4. Structural covariance networks in the fetal brain reveal altered neurodevelopment for specific subtypes of congenital heart disease

Author

Wilson, Siân, primary, Cromb, Daniel, additional, Bonthrone, Alexandra F., additional, Uus, Alena, additional, Price, Anthony, additional, Egloff, Alexia, additional, Van Poppe, Milou P.M, additional, Steinweg, Johannes K, additional, Pushparajah, Kuberan, additional, Simpson, John, additional, Lloyd, David FA, additional, Razavi, Reza, additional, O’Muircheartaigh, Jonathan, additional, Edwards, A. David, additional, Hajnal, Joseph V., additional, Rutherford, Mary, additional, and Counsell, Serena J., additional

Published

2024

5. High resolution and contrast 7 tesla MR brain imaging of the neonate

Author

Bridgen, Philippa, primary, Tomi-Tricot, Raphael, additional, Uus, Alena, additional, Cromb, Daniel, additional, Quirke, Megan, additional, Almalbis, Jennifer, additional, Bonse, Beya, additional, De la Fuente Botella, Miguel, additional, Maggioni, Alessandra, additional, Cio, Pierluigi Di, additional, Cawley, Paul, additional, Casella, Chiara, additional, Dokumaci, Ayse Sila, additional, Thomson, Alice R., additional, Willers Moore, Jucha, additional, Bridglal, Devi, additional, Saravia, Joao, additional, Finck, Thomas, additional, Price, Anthony N., additional, Pickles, Elisabeth, additional, Cordero-Grande, Lucilio, additional, Egloff, Alexia, additional, O’Muircheartaigh, Jonathan, additional, Counsell, Serena J., additional, Giles, Sharon L., additional, Deprez, Maria, additional, De Vita, Enrico, additional, Rutherford, Mary A., additional, Edwards, A. David, additional, Hajnal, Joseph V., additional, Malik, Shaihan J., additional, and Arichi, Tomoki, additional

Published

2024

6. Fetal Cardiac MRI in Clinical Practice: Report of over 350 Fetal CMR Scans in a Large Tertiary Fetal and Paediatric Cardiology Centre

Author

Lim, Zhia Ning, primary, Woodgate, Tomas, additional, Paul, Julia, additional, Poppel, Milou van, additional, Steinweg, Johannes, additional, Skelton, Emily, additional, Sharland, Gurleen, additional, Miller, Owen, additional, Egloff, Alexia, additional, Rutherford, Mary, additional, Zidere, Vita, additional, Vigneswaran, Trisha, additional, Simpson, John, additional, Pushparajah, Kuberan, additional, and Lloyd, David, additional

Published

2024

7. Correlation of Fetal Lung Area with MRI Derived Pulmonary Volume

Author

Avena-Zampieri, Carla Lily, primary, Dassios, Theodore, additional, Milan, Anna, additional, Santos, Rui, additional, Kyriakopoulou, Vanessa, additional, Cromb, Daniel, additional, Hall, Megan, additional, Egloff, Alexia, additional, McGovern, Matthew, additional, Uus, Alena, additional, Hutter, Jana, additional, Payette, Kelly, additional, Rutherford, Mary, additional, Greenough, Anne, additional, and Story, Lisa, additional

Published

2024

8. Adrenal volumes in fetuses delivering prior to 32 weeks' gestation: An MRI pilot study.

Author

Hall, Megan, Hutter, Jana, Uus, Alena, du Crest, Elise, Egloff, Alexia, Suff, Natalie, Al Adnani, Mudher, Seed, Paul T., Gibbons, Deena, Deprez, Maria, Tribe, Rachel M., Shennan, Andrew, Rutherford, Mary, and Story, Lisa

Subjects

CHORIOAMNIONITIS, PREMATURE labor, PREMATURE rupture of fetal membranes, PREGNANCY, MAGNETIC resonance imaging, ADRENAL glands

Abstract

Introduction: Spontaneous preterm birth prior to 32 weeks' gestation accounts for 1% of all deliveries and is associated with high rates of morbidity and mortality. A total of 70% are associated with chorioamnionitis which increases the incidence of morbidity, but for which there is no noninvasive antenatal test. Fetal adrenal glands produce cortisol and dehydroepiandosterone‐sulphate which upregulate prior to spontaneous preterm birth. Ultrasound suggests that adrenal volumes may increase prior to preterm birth, but studies are limited. This study aimed to: (i) demonstrate reproducibility of magnetic resonance imaging (MRI) derived adrenal volumetry; (ii) derive normal ranges of total adrenal volumes, and adrenal: body volume for normal; (iii) compare with those who have spontaneous very preterm birth; and (iv) correlate with histopathological chorioamnionitis. Material and methods: Patients at high risk of preterm birth prior to 32 weeks were prospectively recruited, and included if they did deliver prior to 32 weeks; a control group who delivered an uncomplicated pregnancy at term was also recruited. T2 weighted images of the entire uterus were obtained, and a deformable slice‐to‐volume method was used to reconstruct the fetal abdomen. Adrenal and body volumes were obtained via manual segmentation, and adrenal: body volume ratios generated. Normal ranges were created using control data. Differences between groups were investigated accounting for the effect of gestation by use of regression analysis. Placental histopathology was reviewed for pregnancies delivering preterm. Results: A total of 56 controls and 26 cases were included in the analysis. Volumetry was consistent between observers. Adrenal volumes were not higher in the case group (p = 0.2); adrenal: body volume ratios were higher (p = 0.011), persisting in the presence of chorioamnionitis (p = 0.017). A cluster of three pairs of adrenal glands below the fifth centile were noted among the cases all of whom had a protracted period at risk of preterm birth prior to MRI. Conclusions: Adrenal: body volume ratios are significantly larger in fetuses who go on to deliver preterm than those delivering at term. Adrenal volumes were not significantly larger, we hypothesize that this could be due to an adrenal atrophy in fetuses with fulminating chorioamnionitis. A straightforward relationship of adrenal size being increased prior to preterm birth should not be assumed. [ABSTRACT FROM AUTHOR]

Published

2024

9. Widespread, depth‐dependent cortical microstructure alterations in pediatric focal epilepsy.

Author

Casella, Chiara, Vecchiato, Katy, Cromb, Daniel, Guo, Yourong, Winkler, Anderson M., Hughes, Emer, Dillon, Louise, Green, Elaine, Colford, Kathleen, Egloff, Alexia, Siddiqui, Ata, Price, Anthony, Grande, Lucilio Cordero, Wood, Tobias C., Malik, Shaihan, Teixeira, Rui Pedro A. G., Carmichael, David W., and O'Muircheartaigh, Jonathan

Subjects

PARTIAL epilepsy, FOCAL cortical dysplasia, MAGNETIC resonance imaging, MICROSTRUCTURE

Abstract

Objective: Tissue abnormalities in focal epilepsy may extend beyond the presumed focus. The underlying pathophysiology of these broader changes is unclear, and it is not known whether they result from ongoing disease processes or treatment‐related side effects, or whether they emerge earlier. Few studies have focused on the period of onset for most focal epilepsies, childhood. Fewer still have utilized quantitative magnetic resonance imaging (MRI), which may provide a more sensitive and interpretable measure of tissue microstructural change. Here, we aimed to determine common spatial modes of changes in cortical architecture in children with heterogeneous drug‐resistant focal epilepsy and, secondarily, whether changes were related to disease severity. Methods: To assess cortical microstructure, quantitative T1 and T2 relaxometry (qT1 and qT2) was measured in 43 children with drug‐resistant focal epilepsy (age range = 4–18 years) and 46 typically developing children (age range = 2–18 years). We assessed depth‐dependent qT1 and qT2 values across the neocortex, as well as their gradient of change across cortical depths. We also determined whether global changes seen in group analyses were driven by focal pathologies in individual patients. Finally, as a proof‐of‐concept, we trained a classifier using qT1 and qT2 gradient maps from patients with radiologically defined abnormalities (MRI positive) and healthy controls, and tested whether this could classify patients without reported radiological abnormalities (MRI negative). Results: We uncovered depth‐dependent qT1 and qT2 increases in widespread cortical areas in patients, likely representing microstructural alterations in myelin or gliosis. Changes did not correlate with disease severity measures, suggesting they may represent antecedent neurobiological alterations. Using a classifier trained with MRI‐positive patients and controls, sensitivity was 71.4% at 89.4% specificity on held‐out MRI‐negative patients. Significance: These findings suggest the presence of a potential imaging endophenotype of focal epilepsy, detectable irrespective of radiologically identified abnormalities. [ABSTRACT FROM AUTHOR]

Published

2024

10. CMR 2-49 - Fetal Cardiac MRI in Clinical Practice: Report of over 350 Fetal CMR Scans in a Large Tertiary Fetal and Paediatric Cardiology Centre

Author

Lim, Zhia Ning, Woodgate, Tomas, Paul, Julia, Poppel, Milou van, Steinweg, Johannes, Skelton, Emily, Sharland, Gurleen, Miller, Owen, Egloff, Alexia, Rutherford, Mary, Zidere, Vita, Vigneswaran, Trisha, Simpson, John, Pushparajah, Kuberan, and Lloyd, David

Published

2024

11. Chapter 48 - Doppler Sonography of the Brain in Children

Author

Bulas, Dorothy and Egloff, Alexia M.

Published

2024

12. CONTRIBUTORS

Author

Acharya, Patricia T., Adler, Ronald S., Aguado, Allison, Alexander, Lauren Freeman, Asch, Elizabeth, Atwell, Thomas D., Auckland, Amanda K., Aziz, Muhammad U., Benson, Carol B., Bluth, Edward I., Bulas, Dorothy, Burgan, Constantine M., Burns, Peter N., Buros, Christopher M., Carnahan, Molly B., Castro-Aragon, Ilse, Charboneau, J. William, Chitayat, David, Choi, William, Coleman, Beverly G., Cunnane, Mary E., Doubilet, Peter M., Drose, Julia A., Dunn-Albanese, Lisa R., Egloff, Alexia M., Estroff, Judy A., Fananapazir, Ghaneh, Fowlkes, J. Brian, Frates, Mary C., Gabriel, Helena, Gaetke-Udager, Kara, Ghai, Sangeet, Ghandehari, Hournaz, Glanc, Phyllis, Holland, Christy K., Horrow, Mindy M., Hwang, Misun, John, Susan D., Johnson, Stephen I., Kajal, Dilkash, Kalor, Ashley N., Keunen, Johannes, Khalili, Korosh, Kline-Fath, Beth M., Kumaev, Boris Bulat, Leschied, Jessica, Levine, Deborah, Li, Yi, Lockhart, Mark E., Medellin, Alexandra, Nguyen, HaiThuy N., O’Brien, Barbara, O'Hara, Sara M., Oliver, Edward R., Paltiel, Harriet J., Patel, Maitray D., Phillips, Catherine H., Phillips, Jordana, Potretzke, Theodora A., Rabinowitz, Deborah, Radhakrishnan, Rupa, LaVonne Robbin, Michelle, Rumack, Carol M., Sanchez-Jacob, Ramon, Savicke, Alison M., Chandulal Shah, Chetan, Sharbidre, Kedar Gopal, Shipp, Thomas D., Squires, Judy H., Tessler, Franklin N., Toi, Ants, Troxclair, Laurie, Tublin, Mitchell E., Umphrey, Heidi R., Wall, Darci J., Weber, Therese M., Wei, Pei-Kang, Wilson, Stephanie R., Winter, Thomas, III, Xue, Christine L., Yablon, Corrie M., Yu, Hojun, Zahid, Mohd, and Zhang, Da

Published

2024

13. Correlation of fetal lung area with MRI derived pulmonary volume.

Author

Avena-Zampieri, Carla L., Dassios, Theodore, Milan, Anna, Santos, Rui, Kyriakopoulou, Vanessa, Cromb, Daniel, Hall, Megan, Egloff, Alexia, McGovern, Matthew, Uus, Alena, Hutter, Jana, Payette, Kelly, Rutherford, Mary, Greenough, Anne, and Story, Lisa

Subjects

*LUNGS, *FETAL MRI, *PREMATURE infants, *MAGNETIC resonance imaging, *PEARSON correlation (Statistics), *LUNG volume

Abstract

Neonatal chest-Xray (CXR)s are commonly performed as a first line investigation for the evaluation of respiratory complications. Although lung area derived from CXRs correlates well with functional assessments of the neonatal lung, it is not currently utilised in clinical practice, partly due to the lack of reference ranges for CXR-derived lung area in healthy neonates. Advanced MR techniques now enable direct evaluation of both fetal pulmonary volume and area. This study therefore aims to generate reference ranges for pulmonary volume and area in uncomplicated pregnancies, evaluate the correlation between prenatal pulmonary volume and area, as well as to assess the agreement between antenatal MRI-derived and neonatal CXR-derived pulmonary area in a cohort of fetuses that delivered shortly after the antenatal MRI investigation. Fetal MRI datasets were retrospectively analysed from uncomplicated term pregnancies and a preterm cohort that delivered within 72 h of the fetal MRI. All examinations included T2 weighted single-shot turbo spin echo images in multiple planes. In-house pipelines were applied to correct for fetal motion using deformable slice-to-volume reconstruction. An MRI-derived lung area was manually segmented from the average intensity projection (AIP) images generated. Postnatal lung area in the preterm cohort was measured from neonatal CXRs within 24 h of delivery. Pearson correlation coefficient was used to correlate MRI-derived lung volume and area. A two-way absolute agreement was performed between the MRI-derived AIP lung area and CXR-derived lung area. Datasets from 180 controls and 10 preterm fetuses were suitable for analysis. Mean gestational age at MRI was 28.6 ± 4.2 weeks for controls and 28.7 ± 2.7 weeks for preterm neonates. MRI-derived lung area correlated strongly with lung volumes (p < 0.001). MRI-derived lung area had good agreement with the neonatal CXR-derived lung area in the preterm cohort [both lungs = 0.982]. MRI-derived pulmonary area correlates well with absolute pulmonary volume and there is good correlation between MRI-derived pulmonary area and postnatal CXR-derived lung area when delivery occurs within a few days of the MRI examination. This may indicate that fetal MRI derived lung area may prove to be useful reference ranges for pulmonary areas derived from CXRs obtained in the perinatal period. • Refrence ranges were derived from segmentation of fetal lung areas on AIP-MRI images and correlates with CXR-derived data in preterm infants • Fetal MRI-derived lung area correlated well with fetal MR pulmonary volume and postnatal CXR-lung area. This may prove to be a useful reference range for pulmonary areas derived from CXRs obtained in the perinatal period. • The findings suggest that fetal MRI measurements can serve as useful reference points for assessing lung area in high-risk neonatal CXRs. [ABSTRACT FROM AUTHOR]

Published

2024