Deep Learning-Based Multiclass Brain Tissue Segmentation in Fetal MRIs

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2023 Jan 21

PMID 36679449

Authors

Xiaona Huang

Yang Liu

Yuhan Li

Keying Qi

Ang Gao

Bowen Zheng

Dong Liang

Xiaojing Long

Affiliations

Soon will be listed here.

Abstract

Fetal brain tissue segmentation is essential for quantifying the presence of congenital disorders in the developing fetus. Manual segmentation of fetal brain tissue is cumbersome and time-consuming, so using an automatic segmentation method can greatly simplify the process. In addition, the fetal brain undergoes a variety of changes throughout pregnancy, such as increased brain volume, neuronal migration, and synaptogenesis. In this case, the contrast between tissues, especially between gray matter and white matter, constantly changes throughout pregnancy, increasing the complexity and difficulty of our segmentation. To reduce the burden of manual refinement of segmentation, we proposed a new deep learning-based segmentation method. Our approach utilized a novel attentional structural block, the contextual transformer block (CoT-Block), which was applied in the backbone network model of the encoder-decoder to guide the learning of dynamic attentional matrices and enhance image feature extraction. Additionally, in the last layer of the decoder, we introduced a hybrid dilated convolution module, which can expand the receptive field and retain detailed spatial information, effectively extracting the global contextual information in fetal brain MRI. We quantitatively evaluated our method according to several performance measures: dice, precision, sensitivity, and specificity. In 80 fetal brain MRI scans with gestational ages ranging from 20 to 35 weeks, we obtained an average Dice similarity coefficient (DSC) of 83.79%, an average Volume Similarity (VS) of 84.84%, and an average Hausdorff95 Distance (HD95) of 35.66 mm. We also used several advanced deep learning segmentation models for comparison under equivalent conditions, and the results showed that our method was superior to other methods and exhibited an excellent segmentation performance.

Citing Articles

Transformers for Neuroimage Segmentation: Scoping Review.

Iratni M, Abdullah A, Aldhaheri M, Elharrouss O, Abd-Alrazaq A, Rustamov Z J Med Internet Res. 2025; 27:e57723.

PMID: 39879621 PMC: 11822320. DOI: 10.2196/57723.

Evaluating Brain Tumor Detection with Deep Learning Convolutional Neural Networks Across Multiple MRI Modalities.

Stathopoulos I, Serio L, Karavasilis E, Kouri M, Velonakis G, Kelekis N J Imaging. 2024; 10(12).

PMID: 39728193 PMC: 11679328. DOI: 10.3390/jimaging10120296.

Volumetric segmentation in the context of posterior fossa-related pathologies: a systematic review.

Kobets A, Alavi S, Ahmad S, Castillo A, Young D, Minuti A Neurosurg Rev. 2024; 47(1):170.

PMID: 38637466 PMC: 11026186. DOI: 10.1007/s10143-024-02366-4.

Artificial Intelligence in Obstetric Anomaly Scan: Heart and Brain.

Enache I, Iovoaica-Ramescu C, Ciobanu S, Berbecaru E, Vochin A, Baluta I Life (Basel). 2024; 14(2).

PMID: 38398675 PMC: 10890185. DOI: 10.3390/life14020166.

Automatic Ventriculomegaly Detection in Fetal Brain MRI: A Step-by-Step Deep Learning Model for Novel 2D-3D Linear Measurements.

Vahedifard F, Ai H, Supanich M, Marathu K, Liu X, Kocak M Diagnostics (Basel). 2023; 13(14).

PMID: 37510099 PMC: 10378043. DOI: 10.3390/diagnostics13142355.

References

Hansch A, Schwier M, Gass T, Morgas T, Haas B, Dicken V . Evaluation of deep learning methods for parotid gland segmentation from CT images. J Med Imaging (Bellingham). 2018; 6(1):011005. PMC: 6165912. DOI: 10.1117/1.JMI.6.1.011005. View

Payette K, De Dumast P, Kebiri H, Ezhov I, Paetzold J, Shit S . An automatic multi-tissue human fetal brain segmentation benchmark using the Fetal Tissue Annotation Dataset. Sci Data. 2021; 8(1):167. PMC: 8260784. DOI: 10.1038/s41597-021-00946-3. View

Kuklisova-Murgasova M, Quaghebeur G, Rutherford M, Hajnal J, Schnabel J . Reconstruction of fetal brain MRI with intensity matching and complete outlier removal. Med Image Anal. 2012; 16(8):1550-64. PMC: 4067058. DOI: 10.1016/j.media.2012.07.004. View

Licht D, Wang J, Silvestre D, Nicolson S, Montenegro L, Wernovsky G . Preoperative cerebral blood flow is diminished in neonates with severe congenital heart defects. J Thorac Cardiovasc Surg. 2004; 128(6):841-9. DOI: 10.1016/j.jtcvs.2004.07.022. View

Li Y, Yao T, Pan Y, Mei T . Contextual Transformer Networks for Visual Recognition. IEEE Trans Pattern Anal Mach Intell. 2022; 45(2):1489-1500. DOI: 10.1109/TPAMI.2022.3164083. View

Habas P, Kim K, Corbett-Detig J, Rousseau F, Glenn O, Barkovich A . A spatiotemporal atlas of MR intensity, tissue probability and shape of the fetal brain with application to segmentation. Neuroimage. 2010; 53(2):460-70. PMC: 2930902. DOI: 10.1016/j.neuroimage.2010.06.054. View

Khalili N, Lessmann N, Turk E, Claessens N, de Heus R, Kolk T . Automatic brain tissue segmentation in fetal MRI using convolutional neural networks. Magn Reson Imaging. 2019; 64:77-89. DOI: 10.1016/j.mri.2019.05.020. View

Dou H, Karimi D, Rollins C, Ortinau C, Vasung L, Velasco-Annis C . A Deep Attentive Convolutional Neural Network for Automatic Cortical Plate Segmentation in Fetal MRI. IEEE Trans Med Imaging. 2020; 40(4):1123-1133. PMC: 8016740. DOI: 10.1109/TMI.2020.3046579. View

Tourbier S, Bresson X, Hagmann P, Thiran J, Meuli R, Cuadra M . An efficient total variation algorithm for super-resolution in fetal brain MRI with adaptive regularization. Neuroimage. 2015; 118:584-97. DOI: 10.1016/j.neuroimage.2015.06.018. View

10.

Kinoshita Y, Okudera T, Tsuru E, Yokota A . Volumetric analysis of the germinal matrix and lateral ventricles performed using MR images of postmortem fetuses. AJNR Am J Neuroradiol. 2001; 22(2):382-8. PMC: 7973932. View

11.

Huang Q, Sun J, Ding H, Wang X, Wang G . Robust liver vessel extraction using 3D U-Net with variant dice loss function. Comput Biol Med. 2018; 101:153-162. DOI: 10.1016/j.compbiomed.2018.08.018. View

12.

Wright R, Kyriakopoulou V, Ledig C, Rutherford M, Hajnal J, Rueckert D . Automatic quantification of normal cortical folding patterns from fetal brain MRI. Neuroimage. 2014; 91:21-32. DOI: 10.1016/j.neuroimage.2014.01.034. View

13.

Gholipour A, Akhondi-Asl A, Estroff J, Warfield S . Multi-atlas multi-shape segmentation of fetal brain MRI for volumetric and morphometric analysis of ventriculomegaly. Neuroimage. 2012; 60(3):1819-31. PMC: 3329183. DOI: 10.1016/j.neuroimage.2012.01.128. View

14.

An L, Zhang P, Adeli E, Wang Y, Ma G, Shi F . Multi-Level Canonical Correlation Analysis for Standard-Dose PET Image Estimation. IEEE Trans Image Process. 2016; 25(7):3303-3315. PMC: 5106345. DOI: 10.1109/TIP.2016.2567072. View

15.

Habas P, Kim K, Rousseau F, Glenn O, Barkovich A, Studholme C . Atlas-based segmentation of developing tissues in the human brain with quantitative validation in young fetuses. Hum Brain Mapp. 2010; 31(9):1348-58. PMC: 3306251. DOI: 10.1002/hbm.20935. View

16.

Gu Z, Cheng J, Fu H, Zhou K, Hao H, Zhao Y . CE-Net: Context Encoder Network for 2D Medical Image Segmentation. IEEE Trans Med Imaging. 2019; 38(10):2281-2292. DOI: 10.1109/TMI.2019.2903562. View

17.

Prayer D, Kasprian G, Krampl E, Ulm B, Witzani L, Prayer L . MRI of normal fetal brain development. Eur J Radiol. 2006; 57(2):199-216. DOI: 10.1016/j.ejrad.2005.11.020. View

18.

Lachmann R, Chaoui R, Moratalla J, Picciarelli G, Nicolaides K . Posterior brain in fetuses with open spina bifida at 11 to 13 weeks. Prenat Diagn. 2010; 31(1):103-6. DOI: 10.1002/pd.2632. View

19.

Ghi T, Pilu G, Falco P, Segata M, Carletti A, Cocchi G . Prenatal diagnosis of open and closed spina bifida. Ultrasound Obstet Gynecol. 2006; 28(7):899-903. DOI: 10.1002/uog.3865. View