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

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

doi:10.1109/tmi.2020.2974844

Cited by 77 publications

(87 citation statements)

References 36 publications

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“…were obtained from 4-8 motion corrupted T2 MRI stacks using the deformable slice-to-volume reconstruction method. [13][14][15] Scan length did not exceed 1 hour.…”

Section: Key Messagementioning

confidence: 94%

“…The following scanning parameters were used: TR = 25 991 ms, TE = 80 ms, slice thickness of 2.5 mm, slice overlap of 1.25 × 1.25 × 1.25 mm on 1.5T, and 1.21 × 1.21 × 1.5 or 1.25 × 1.25 × 2.5 mm on 3T, with a flip angle = 90°. Three-dimensional (3D) MR images of the fetal thoraxwere obtained from 4-8 motion corrupted T2 MRI stacks using the deformable slice-to-volume reconstruction method [13][14][15]. Scan length did not exceed 1 hour.…”

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confidence: 99%

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Antenatal thymus volumes in fetuses that delivered <32 weeks' gestation: An MRI pilot study

Story

Zhang

Uus

et al. 2020

Acta Obstet Gynecol Scand

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“…were obtained from 4-8 motion corrupted T2 MRI stacks using the deformable slice-to-volume reconstruction method. [13][14][15] Scan length did not exceed 1 hour.…”

Section: Key Messagementioning

confidence: 94%

mentioning

confidence: 99%

Antenatal thymus volumes in fetuses that delivered <32 weeks' gestation: An MRI pilot study

Story

Zhang

Uus

et al. 2020

Acta Obstet Gynecol Scand

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“…For reconstruction of the foetal spine, internal organs and placenta, the SVR methods mentioned above cannot resolve the issue of difficult registrations due to non-rigid motion, resulting in degradation of image quality within the reconstructed volume. Therefore, a method was developed that uses non-rigid image registration and SVR (deformable SVR) which shows great promise for reconstruction high resolution images of the spine and surrounding organs in spina bifida [ 51 ]. Patch-to-volume reconstruction is also able to reconstruct a large field of view of non-rigidly deforming structures, using a parallelised patchwork optimisation (patch to volume reconstruction is used instead of SVR), SR, and automatic outlier rejection.…”

Section: Techniques Improving the Anatomical Resolution And Utility Of Foetal Mrimentioning

confidence: 99%

“…In spina bifida imaging, foetal MRI is greatly limited by the lower spatial resolution for the assessment of the level of the lesion and to depict the myelon. Recent works demonstrated that isotropic reconstructions of the entire foetal body including the spine are possible [ 51 ], which could be used to tackle this problem. Faster image acquisition would also improve the clinical utility of foetal MRI, for example, by using compressed sensing technique [ 54 ].…”

Section: Techniques Improving the Anatomical Resolution And Utility Of Foetal Mrimentioning

confidence: 99%

Emerging magnetic resonance imaging techniques in open spina bifida in utero

et al. 2021

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Magnetic resonance imaging (MRI) has become an essential diagnostic modality for congenital disorders of the central nervous system. Recent advancements have transformed foetal MRI into a clinically feasible tool, and in an effort to find predictors of clinical outcomes in spinal dysraphism, foetal MRI began to unveil its potential. The purpose of our review is to introduce MRI techniques to experts with diverse backgrounds, who are involved in the management of spina bifida. We introduce advanced foetal MRI postprocessing potentially improving the diagnostic work-up. Importantly, we discuss how postprocessing can lead to a more efficient utilisation of foetal or neonatal MRI data to depict relevant anatomical characteristics. We provide a critical perspective on how structural, diffusion and metabolic MRI are utilised in an endeavour to shed light on the correlates of impaired development. We found that the literature is consistent about the value of MRI in providing morphological cues about hydrocephalus development, hindbrain herniation or outcomes related to shunting and motor functioning. MRI techniques, such as foetal diffusion MRI or diffusion tractography, are still far from clinical use; however, postnatal studies using these methods revealed findings that may reflect early neural correlates of upstream neuronal damage in spinal dysraphism.

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“…However, this could be expanded with further post-processing steps. These include placental 3D reconstruction, eg from orthogonal slice stacks or multiple dynamics as has been recently proposed for T2* data for the brain (41) and the placenta (28) or inter-slice motion correction techniques (42) to improve the 3D continuity of the data thus enabling 3D patch-based segmentation and/or placental flattening techniques (16, 43), resulting in representations in a common coordinate system.…”

Section: Discussionmentioning

confidence: 99%

APPLAUSE: Automatic Prediction of PLAcental health via U-net Segmentation and statistical Evaluation

Pietsch

Bardanzellu

et al. 2020

Preprint

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Purpose: Artificial-intelligence population-based automated quantification of placental maturation and health from a rapid functional Magnetic Resonance scan. The placenta plays a crucial role for any successful human pregnancy. Deviations from the normal dynamic maturation throughout gestation are closely linked to major pregnancy complications. Antenatal assessment in-vivo using T2* relaxometry has shown great promise to inform management and possible interventions but clinical translation is hampered by time consuming manual segmentation and analysis techniques based on comparison against normative curves over gestation. Methods: This study proposes a fully automatic pipeline to predict the biological age and health of the placenta based on a rapid (sub-30 second) T2* scan in two steps: Automatic segmentation using a U-Net and a Gaussian Process regression model to characterize placental maturation and health. These are trained and evaluated on 110 3T MRI placental data sets including 20 high-risk pregnancies diagnosed with pre-eclampsia and/or fetal growth restriction. Results: Automatic segmentation achieves comparable performance to human experts (mean DICE coefficients automatic-manual 0.76, Pearson Correlation Coefficient 0.986 for mean T2* within the masks). The placental health prediction achieves an excellent ability to differentiate early cases of placental insufficiency before 32 weeks. High abnormality scores correlate with low birth weight, premature birth and histopathological findings. Retrospective application on a different cohort imaged at 1.5T illustrates the ability for direct clinical translation. Conclusion: The presented automatic pipeline facilitates a fast, robust and reliable prediction of placental maturation. It yields human-interpretable and verifiable intermediate results and quantifies uncertainties on the cohort-level and for individual predictions. The proposed machine-learning pipeline runs in close to real-time and, deployed in clinical settings, has the potential to become a cornerstone of diagnosis and intervention of placental insufficiency.

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

Cited by 77 publications

References 36 publications

Antenatal thymus volumes in fetuses that delivered <32 weeks' gestation: An MRI pilot study

Antenatal thymus volumes in fetuses that delivered <32 weeks' gestation: An MRI pilot study

Emerging magnetic resonance imaging techniques in open spina bifida in utero

APPLAUSE: Automatic Prediction of PLAcental health via U-net Segmentation and statistical Evaluation

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