3D Volume Reconstruction and Biometric Analysis of Fetal Brain from MR Images
June 2009
Pages 188 - 197
Abstract
Magnetic resonance imaging (MRI) is becoming increasingly popular as a second-level technique, performed after ultrasonography (US) scanning, for detecting morphologic brain abnormalities. For this reason, several medical researchers in the past few years have investigated the field of fetal brain diagnosis from MR images, both to create models of the normal fetal brain development and to define diagnostic rules, based on biometric analysis; all these studies require the segmentation of cerebral structures from MRI slices, where their sections are clearly visible. A problem of this approach is due to the fact that fetuses often move during the sequence acquisition, so that it is difficult to obtain a slice where the structures of interest are properly represented. Moreover, in the clinical routine segmentation is performed manually, introducing a high inter and intra-observer variability that greatly decreases the accuracy and significance of the result. To solve these problems in this paper we propose an algorithm that builds a 3D representation of the fetal brain; from this representation the desired section of the cerebral structures can be extracted. Next, we describe our preliminary studies to automatically segment ventricles and internal liquors (from slices where they are entirely visible), and to extract biometric measures describing their shape. In spite of the poor resolution of fetal brain MR images, encouraging preliminary results have been obtained.
References
[1]
Campadelli, P., Casiraghi, E.: Liver Segmentation from CT Scans: a Survey and a New Algorithm. Artificial Intelligence in Medicine (to appear, 2008).
[2]
Arbib, M.A., Uchiyama, T.: Color image segmentation using competitive learning. IEEE Transactions on Pattern Analisys and Machine Intelligence 16(12), 1197-1206 (1994).
[3]
Chong, B.W., et al.: A magnetic resonance template for normal neuronal migration in the fetus. Neurosurgery 39(1), 110-116 (1996).
[4]
Claude, I., et al.: Fetal Brain MRI: Segmentation and Biometric Analysis of the Posterior Fossa. IEEE Transactions on Biomedical Engineering 51(4), 617-626 (2004).
[5]
Cuddihy, S.L., et al.: Cerebellar vermis diameter at cranial sonography for assessing gestational age in low-birth-weight infants. Pediatratric Radiology 29(8), 589-594 (1999).
[6]
Ghidini, A., et al.: Dilated subarachnoid cisterna ambiens: A potential sonographic sign predicting cerebellar hypoplasia. Journal of Ultrasound in Medicine 15, 413-415 (1996).
[7]
Gholipour, A., et al.: Brain Functional Localization: A Survey of Image Registration Techniques. IEEE Transactions on Medical Imaging 26(4), 427-451 (2007).
[8]
Han, X., Fischl, B.: Atlas Renormalization for Improved Brain MR Image Segmentation Across Scanner Platforms. IEEE Transactions on Medical Imaging 26(4), 479-486 (2007).
[9]
Huang, H., et al.: White and gray matter development in human fetal, newborn and pediatric brains. Neuroimage 33(1), 27-38 (2006).
[10]
Johnston, B., et al.: Segmentation of Multide Sclerosis Lesions in Intensity Corrected Multi-spectral MRI. IEEE Transactions on Medical Imaging 15(2), 152-169 (1996).
[11]
RayBaud, C., et al.: MR imaging of fetal brain malformation. Child's Nervous System 19, 455-470 (2003).
[12]
Sanders, M., et al.: Gestational age assessment in preterm neonates weighing less than 1500 grams. Pediatratrics 88, 542-546 (1991).
[13]
Schwarz, D., et al.: A Deformable Registration Method for Automated Morphometry of MRI Brain Images in Neuropsychiatric Research. IEEE Transactions on Medical Imaging 26(4), 452-461 (2007).
[14]
Schierlitz, L., et al.: Three-dimensional magnetic resonance imaging of fetal brains. The Lancet 357, 1177-1178 (2001).
[15]
Triulzi, F., et al.: Magnetic resonance imaging of fetal cerebellar development. The Cerebellum 5(3), 199-205 (2005).
[16]
Vovk, U., et al.: A Review of Methods for Correction of Intensity Inhomogeneity in MRI. IEEE Transactions on Medical Imaging 26(3), 405-421 (2007).
[17]
Xia, Y., et al.: Automatic Segmentation of the Caudate Nucleus From Human Brain MR Images. IEEE Transactions on Medical Imaging 26(4), 509-517 (2007).
[18]
Yu, P., et al.: Cortical Surface Shape Analysis Based on Spherical Wavelets. IEEE Transactions on Medical Imaging 26(4), 154-169 (2007).
- 3D Volume Reconstruction and Biometric Analysis of Fetal Brain from MR Images
Recommendations
Template method to improve brain segmentation from inhomogeneous brain magnetic resonance images at high fields
ISBI'10: Proceedings of the 2010 IEEE international conference on Biomedical imaging: from nano to MacroMagnetic resonance imaging of the brain at high fields (e.g. 3T) provides high resolution and high signal to noise ratio images suitable for a wide range of clinical applications. However, radiofrequency (or B1) inhomogeneity increases with the magnetic ...
Automated segmentation of brain MR images
A simple, robust and efficient image segmentation algorithm for classifying brain tissues from dual echo Magnetic Resonance (MR) images is presented. The algorithm consists of a sequence of adaptive histogram analysis, morphological operations and ...
Brain MRI image segmentation based on learning local variational Gaussian mixture models
Measuring the distribution of major brain tissues, including the gray matter, white matter and cerebrospinal fluid (CSF), using magnetic resonance imaging (MRI) has attracted extensive research efforts. Many brain MRI image segmentation methods in the ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
June 2009
292 pages
ISBN:9783642025037
Publisher
Springer-Verlag
Berlin, Heidelberg
Publication History
Published: 23 June 2009
Author Tags
Qualifiers
- Chapter
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 0Total Downloads
- Downloads (Last 12 months)0
- Downloads (Last 6 weeks)0
Reflects downloads up to 14 Dec 2024