Your search keyword '"Deprez, Maria"' showing total 10 results

1. Towards Automated Multi-regional Lung Parcellation for 0.55-3T 3D T2w Fetal MRI

Author

Uus, Alena U., Zampieri, Carla Avena, Downes, Fenella, Collado, Alexia Egloff, Hall, Megan, Davidson, Joseph, Payette, Kelly, Verdera, Jordina Aviles, Grigorescu, Irina, Hajnal, Joseph V., Deprez, Maria, Aertsen, Michael, Hutter, Jana, Rutherford, Mary A., Deprest, Jan, Story, Lisa, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Link-Sourani, Daphna, editor, Abaci Turk, Esra, editor, Macgowan, Christopher, editor, Hutter, Jana, editor, Melbourne, Andrew, editor, and Licandro, Roxane, editor

Published

2025

2. Craniofacial phenotyping with fetal MRI: a feasibility study of 3D visualisation, segmentation, surface-rendered and physical models

Author

Matthew, Jacqueline, Uus, Alena, De Souza, Leah, Wright, Robert, Fukami-Gartner, Abi, Priego, Gema, Saija, Carlo, Deprez, Maria, Collado, Alexia Egloff, Hutter, Jana, Story, Lisa, Malamateniou, Christina, Rhode, Kawal, Hajnal, Jo, and Rutherford, Mary A.

Published

2024

3. Combined Quantitative T2* Map and Structural T2-Weighted Tissue-Specific Analysis for Fetal Brain MRI: Pilot Automated Pipeline

Author

Uus, Alena U., Hall, Megan, Payette, Kelly, Hajnal, Joseph V., Deprez, Maria, Rutherford, Mary A., Hutter, Jana, Story, Lisa, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Link-Sourani, Daphna, editor, Abaci Turk, Esra, editor, Macgowan, Christopher, editor, Hutter, Jana, editor, Melbourne, Andrew, editor, and Licandro, Roxane, editor

Published

2023

4. An Automated Pipeline for Quantitative T2* Fetal Body MRI and Segmentation at Low Field

Author

Payette, Kelly, Uus, Alena, Aviles Verdera, Jordina, Avena Zampieri, Carla, Hall, Megan, Story, Lisa, Deprez, Maria, Rutherford, Mary A., Hajnal, Joseph V., Ourselin, Sebastien, Tomi-Tricot, Raphael, Hutter, Jana, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Greenspan, Hayit, editor, Madabhushi, Anant, editor, Mousavi, Parvin, editor, Salcudean, Septimiu, editor, Duncan, James, editor, Syeda-Mahmood, Tanveer, editor, and Taylor, Russell, editor

Published

2023

5. 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

6. Deformable Slice-to-Volume Registration for Motion Correction of Fetal Body and Placenta MRI.

Author

Uus, Alena, Zhang, Tong, Jackson, Laurence H., Roberts, Thomas A., Rutherford, Mary A., Hajnal, Joseph V., and Deprez, Maria

Subjects

RECORDING & registration, PLACENTA, MOTION, FETAL MRI, FETAL brain

Abstract

In in-utero MRI, motion correction for fetal body and placenta poses a particular challenge due to the presence of local non-rigid transformations of organs caused by bending and stretching. The existing slice-to-volume registration (SVR) reconstruction methods are widely employed for motion correction of fetal brain that undergoes only rigid transformation. However, for reconstruction of fetal body and placenta, rigid registration cannot resolve the issue of misregistrations due to deformable motion, resulting in degradation of features in the reconstructed volume. We propose a Deformable SVR (DSVR), a novel approach for non-rigid motion correction of fetal MRI based on a hierarchical deformable SVR scheme to allow high resolution reconstruction of the fetal body and placenta. Additionally, a robust scheme for structure-based rejection of outliers minimises the impact of registration errors. The improved performance of DSVR in comparison to SVR and patch-to-volume registration (PVR) methods is quantitatively demonstrated in simulated experiments and 20 fetal MRI datasets from 28–31 weeks gestational age (GA) range with varying degree of motion corruption. In addition, we present qualitative evaluation of 100 fetal body cases from 20–34 weeks GA range. [ABSTRACT FROM AUTHOR]

Published

2020

7. Functional MRI assessment of the lungs in fetuses that deliver very Preterm: An MRI pilot study.

Author

Avena-Zampieri, Carla L., Hutter, Jana, Uus, Alena, Deprez, Maria, Payette, Kelly, Hall, Megan, Bafadhel, Mona, Russell, Richard E.K., Milan, Anna, Rutherford, Mary, Shennan, Andrew, Greenough, Anne, and Story, Lisa

Subjects

*FUNCTIONAL magnetic resonance imaging, *FETAL MRI, *FUNCTIONAL assessment, *LUNG development, *MAGNETIC resonance imaging, *PREMATURE labor

Abstract

• Application of deformable slice-to-volume reconstruction is feasible for MRI characterisation of preterm lung development. • Mean T2* values were lower in the preterm cohort than in controls. • Alterations in pulmonary development associated with preterm birth may commence in the antenatal period. To compare mean pulmonary T2* values and pulmonary volumes in fetuses that subsequently spontaneously delivered before 32 weeks with a control cohort with comparable gestational ages and to assess the value of mean pulmonary T2* as a predictor of preterm birth < 32 weeks' gestation. MRI datasets scanned at similar gestational ages were selected from fetuses who spontaneously delivered < 32 weeks of gestation and a control group who subsequently delivered at term with no complications. All women underwent a fetal MRI on a 3 T MRI imaging system. Sequences included T2-weighted single shot fast spin echo and T2* sequences, using gradient echo single shot echo planar sequencing of the fetal thorax. Motion correction was performed using slice-to-volume reconstruction and T2* maps generated using in-house pipelines. Lungs were manually segmented and volumes and mean T2* values calculated for both lungs combined and left and right lung separately. Linear regression was used to compare values between the preterm and control cohorts accounting for the effects of gestation. Receiver operating curves were generated for mean T2* values and pulmonary volume as predictors of preterm birth < 32 weeks' gestation. Datasets from twenty-eight preterm and 74 control fetuses were suitable for analysis. MRI images were taken at similar fetal gestational ages (preterm cohort (mean ± SD) 24.9 ± 3.3 and control cohort (mean ± SD) 26.5 ± 3.0). Mean gestational age at delivery was 26.4 ± 3.3 for the preterm group and 39.9 ± 1.3 for the control group. Mean pulmonary T2* values remained constant with increasing gestational age while pulmonary volumes increased. Both T2* and pulmonary volumes were lower in the preterm group than in the control group for all parameters (both combined, left, and right lung (p < 0.001 in all cases). Adjusted for gestational age, pulmonary volumes and mean T2* values were good predictors of premature delivery in fetuses < 32 weeks (area under the curve of 0.828 and 0.754 respectively). These findings indicate that mean pulmonary T2* values and volumes were lower in fetuses that subsequently delivered very preterm. This may suggest potentially altered oxygenation and indicate that pulmonary morbidity associated with prematurity has an antenatal antecedent. Future work should explore these results correlating antenatal findings with long term pulmonary outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

8. Fetal body organ T2* relaxometry at low field strength (FOREST).

Author

Payette, Kelly, Uus, Alena U., Aviles Verdera, Jordina, Hall, Megan, Egloff, Alexia, Deprez, Maria, Tomi-Tricot, Raphaël, Hajnal, Joseph V., Rutherford, Mary A., Story, Lisa, and Hutter, Jana

Subjects

*FETAL MRI, *ORGANS (Anatomy), *FETAL imaging, *GESTATIONAL age, *IMAGE processing

Abstract

Fetal Magnetic Resonance Imaging (MRI) at low field strengths is an exciting new field in both clinical and research settings. Clinical low field (0.55T) scanners are beneficial for fetal imaging due to their reduced susceptibility-induced artifacts, increased T2* values, and wider bore (widening access for the increasingly obese pregnant population). However, the lack of standard automated image processing tools such as segmentation and reconstruction hampers wider clinical use. In this study, we present the Fetal body Organ T2* RElaxometry at low field STrength (FOREST) pipeline that analyzes ten major fetal body organs. Dynamic multi-echo multi-gradient sequences were acquired and automatically reoriented to a standard plane, reconstructed into a high-resolution volume using deformable slice-to-volume reconstruction, and then automatically segmented into ten major fetal organs. We extensively validated FOREST using an inter-rater quality analysis. We then present fetal T2* body organ growth curves made from 100 control subjects from a wide gestational age range (17–40 gestational weeks) in order to investigate the relationship of T2* with gestational age. The T2* values for all organs except the stomach and spleen were found to have a relationship with gestational age (p < 0.05). FOREST is robust to fetal motion, and can be used for both normal and fetuses with pathologies. Low field fetal MRI can be used to perform advanced MRI analysis, and is a viable option for clinical scanning. [Display omitted] • Low field fetal MRI is a promising modality for quantitative fetal body MRI. • FOREST allows automated end-to-end T2* relaxometry of 10 fetal body organs. • Fetal T2* changes throughout gestation and can function as a clinical biomarker. [ABSTRACT FROM AUTHOR]

Published

2025

9. Three-dimensional visualisation of the fetal heart using prenatal MRI with motion-corrected slice-volume registration: a prospective, single-centre cohort study.

Author

Lloyd, David F A, Pushparajah, Kuberan, Simpson, John M, van Amerom, Joshua F P, van Poppel, Milou P M, Schulz, Alexander, Kainz, Bernard, Deprez, Maria, Lohezic, Maelene, Allsop, Joanna, Mathur, Sujeev, Bellsham-Revell, Hannah, Vigneswaran, Trisha, Charakida, Marietta, Miller, Owen, Zidere, Vita, Sharland, Gurleen, Rutherford, Mary, Hajnal, Joseph V, and Razavi, Reza

Subjects

*FETAL heart, *IMAGE processing software, *FETAL MRI, *HEART disease diagnosis, *CONGENITAL heart disease, *CONGENITAL heart disease diagnosis, *FETAL heart rate monitoring, *FETAL ultrasonic imaging, *GESTATIONAL age, *DIGITAL image processing, *LONGITUDINAL method, *MAGNETIC resonance imaging, *RESEARCH funding, *THREE-dimensional imaging

Abstract

Background: Two-dimensional (2D) ultrasound echocardiography is the primary technique used to diagnose congenital heart disease before birth. There is, however, a longstanding need for a reliable form of secondary imaging, particularly in cases when more detailed three-dimensional (3D) vascular imaging is required, or when ultrasound windows are of poor diagnostic quality. Fetal MRI, which is well established for other organ systems, is highly susceptible to fetal movement, particularly for 3D imaging. The objective of this study was to investigate the combination of prenatal MRI with novel, motion-corrected 3D image registration software, as an adjunct to fetal echocardiography in the diagnosis of congenital heart disease.Methods: Pregnant women carrying a fetus with known or suspected congenital heart disease were recruited via a tertiary fetal cardiology unit. After initial validation experiments to assess the general reliability of the approach, MRI data were acquired in 85 consecutive fetuses, as overlapping stacks of 2D images. These images were then processed with a bespoke open-source reconstruction algorithm to produce a super-resolution 3D volume of the fetal thorax. These datasets were assessed with measurement comparison with paired 2D ultrasound, structured anatomical assessment of the 2D and 3D data, and contemporaneous, archived clinical fetal MRI reports, which were compared with postnatal findings after delivery.Findings: Between Oct 8, 2015, and June 30, 2017, 101 patients were referred for MRI, of whom 85 were eligible and had fetal MRI. The mean gestational age at the time of MRI was 32 weeks (range 24-36). High-resolution (0·50-0·75 mm isotropic) 3D datasets of the fetal thorax were generated in all 85 cases. Vascular measurements showed good overall agreement with 2D echocardiography in 51 cases with paired data (intra-class correlation coefficient 0·78, 95% CI 0·68-0·84), with fetal vascular structures more effectively visualised with 3D MRI than with uncorrected 2D MRI (657 [97%] of 680 anatomical areas identified vs 358 [53%] of 680 areas; p<0·0001). When a structure of interest was visualised in both 2D and 3D data (n=358), observers gave a higher diagnostic quality score for 3D data in 321 (90%) of cases, with 37 (10%) scores tied with 2D data, and no lower scores than for 2D data (Wilcoxon signed rank test p<0·0001). Additional anatomical features were described in ten cases, of which all were confirmed postnatally.Interpretation: Standard fetal MRI with open-source image processing software is a reliable method of generating high-resolution 3D imaging of the fetal vasculature. The 3D volumes produced show good spatial agreement with ultrasound, and significantly improved visualisation and diagnostic quality compared with source 2D MRI data. This freely available combination requires minimal infrastructure, and provides safe, powerful, and highly complementary imaging of the fetal cardiovascular system.Funding: Wellcome Trust/EPSRC Centre for Medical Engineering, National Institute for Health Research. [ABSTRACT FROM AUTHOR]

Published

2019

10. Automated 3D reconstruction of the fetal thorax in the standard atlas space from motion-corrupted MRI stacks for 21–36 weeks GA range.

Author

Uus, Alena U., Grigorescu, Irina, van Poppel, Milou P.M., Steinweg, Johannes K., Roberts, Thomas A., Rutherford, Mary A., Hajnal, Joseph V., Lloyd, David F.A., Pushparajah, Kuberan, and Deprez, Maria

Subjects

*FETAL echocardiography, *FETAL ultrasonic imaging, *FETAL MRI, *MAGNETIC resonance imaging, *CONGENITAL heart disease, *CONVOLUTIONAL neural networks, *FETAL anatomy

Abstract

• Proposed and implemented automated motion correction pipeline for reconstruction of 3D fetal thorax anatomy from fetal MRI stacks. • The output high-resolution reconstructed 3D images are used for assessment of fine fetal cardiovascular structures. • The automated pipeline was successfully qualitatively evaluated on 100 early (≤ 24 weeks) and late (≥ 30 weeks) GA fetal MRI datasets in term of anatomical interpretability. [Display omitted] Slice-to-volume registration (SVR) methods allow reconstruction of high-resolution 3D images from multiple motion-corrupted stacks. SVR-based pipelines have been increasingly used for motion correction for T2-weighted structural fetal MRI since they allow more informed and detailed diagnosis of brain and body anomalies including congenital heart defects (Lloyd et al., 2019). Recently, fully automated rigid SVR reconstruction of the fetal brain in the atlas space was achieved in Salehi et al. (2019) that used convolutional neural networks (CNNs) for segmentation and pose estimation. However, these CNN-based methods have not yet been applied to the fetal trunk region. Meanwhile, the existing rigid and deformable SVR (DSVR) solutions (Uus et al., 2020) for the fetal trunk region are limited by the requirement of manual input as well the narrow capture range of the classical gradient descent based registration methods that cannot resolve severe fetal motion frequently occurring at the early gestational age (GA). Furthermore, in our experience, the conventional 2D slice-wise CNN-based brain masking solutions are reportedly prone to errors that require manual corrections when applied on a wide range of acquisition protocols or abnormal cases in clinical setting. In this work, we propose a fully automated pipeline for reconstruction of the fetal thorax region for 21–36 weeks GA range T2-weighted MRI datasets. It includes 3D CNN-based intra-uterine localisation of the fetal trunk and landmark-guided pose estimation steps that allow automated DSVR reconstruction in the standard radiological space irrespective of the fetal trunk position or the regional stack coverage. The additional step for generation of the common template space and rejection of outliers provides the means for automated exclusion of stacks affected by low image quality or extreme motion. The pipeline was quantitatively evaluated on a series of experiments including fetal MRI datasets and simulated rotation motion. Furthermore, we performed a qualitative assessment of the image reconstruction quality in terms of the definition of vascular structures on 100 early (median 23.14 weeks) and late (median 31.79 weeks) GA group MRI datasets covering 21 to 36 weeks GA range. [ABSTRACT FROM AUTHOR]

Published

2022