A Quantitative Approach to Characterize MR Contrasts with Histology

Immunohistochemistry is widely used as a gold standard to inspect tissues, characterize their structure and detect pathological alterations. As such, the joint analysis of histological images and other imaging modalities (MRI, PET) is of major interest to interpret these physical signals and establish their correspondence with the biological constitution of the tissues. However, it is challenging to provide a meaningful characterization of the signal specificity. In this paper, we propose an integrated method to quantitatively evaluate the discriminative power of imaging modalities. This method was validated using a macaque brain dataset containing: 3 immunohistochemically stained and 1 histochemically stained series, 1 photographic volume and 1 in vivo T2 weighted MRI. First, biological regions of interest (ROIs) were automatically delineated from histological sections stained for markers of interest and mapped on the target non-specific modalities through co-registration. These non-overlapping ROIs were considered ground truth for later classification. Voxels were evenly split in training and testing sets for a logistic regression model. The statistical significance of resulting accuracy scores was evaluated through null distribution simulations. Such an approach could be of major interest to assess relevant biological characteristics from various imaging modalities.

[1]  Daniel Rueckert,et al.  Nonrigid registration using free-form deformations: application to breast MR images , 1999, IEEE Transactions on Medical Imaging.

[2]  Scott E. Fraser,et al.  Mapping transplanted stem cell migration after a stroke: a serial, in vivo magnetic resonance imaging study , 2004, NeuroImage.

[3]  Marc Dhenain,et al.  A combination of atlas-based and voxel-wise approaches to analyze metabolic changes in autoradiographic data from Alzheimer's mice , 2011, NeuroImage.

[4]  Anne-Catherine Bachoud-Lévi,et al.  Motor and cognitive improvements in patients with Huntington's disease after neural transplantation , 2000, The Lancet.

[5]  Marc Peschanski,et al.  Embryonic stem cells neural differentiation qualifies the role of Wnt/β‐Catenin signals in human telencephalic specification and regionalization , 2013, Stem cells.

[6]  R. Woods,et al.  Mapping Histology to Metabolism: Coregistration of Stained Whole-Brain Sections to Premortem PET in Alzheimer's Disease , 1997, NeuroImage.

[7]  Junle Qu,et al.  Transplantation of Induced Pluripotent Stem Cells Improves Functional Recovery in Huntington's Disease Rat Model , 2014, PloS one.

[8]  D Mayerich,et al.  Knife‐edge scanning microscopy for imaging and reconstruction of three‐dimensional anatomical structures of the mouse brain , 2008, Journal of microscopy.

[9]  Grégoire Malandain,et al.  Fusion of autoradiographs with an MR volume using 2-D and 3-D linear transformations , 2004, NeuroImage.

[10]  Wiro J. Niessen,et al.  Quantification of DCE-MRI: A validation of three techniques with 3D-histology , 2012, 2012 9th IEEE International Symposium on Biomedical Imaging (ISBI).

[11]  Gemma C. Garriga,et al.  Permutation Tests for Studying Classifier Performance , 2009, 2009 Ninth IEEE International Conference on Data Mining.

[12]  Sébastien Ourselin,et al.  Reconstructing a 3D structure from serial histological sections , 2001, Image Vis. Comput..

[13]  Nobuko Uchida,et al.  Long-term monitoring of transplanted human neural stem cells in developmental and pathological contexts with MRI , 2007, Proceedings of the National Academy of Sciences.

[14]  A. Schleicher,et al.  Mapping of Histologically Identified Long Fiber Tracts in Human Cerebral Hemispheres to the MRI Volume of a Reference Brain: Position and Spatial Variability of the Optic Radiation , 1999, NeuroImage.

[15]  Christopher A Ross,et al.  Human-induced pluripotent stem cells: potential for neurodegenerative diseases. , 2014, Human molecular genetics.

[16]  H. Seung,et al.  Serial two-photon tomography: an automated method for ex-vivo mouse brain imaging , 2011, Nature Methods.

[17]  Frank Bradke,et al.  Three-dimensional imaging of solvent-cleared organs using 3DISCO , 2012, Nature Protocols.

[18]  Sébastien Ourselin,et al.  Co-registration of Histological, Optical and MR Data of the Human Brain , 2002, MICCAI.

[19]  N. Renier,et al.  iDISCO: A Simple, Rapid Method to Immunolabel Large Tissue Samples for Volume Imaging , 2014, Cell.

[20]  Paul H. E. Tiesinga,et al.  The Scalable Brain Atlas: Instant Web-Based Access to Public Brain Atlases and Related Content , 2013, Neuroinformatics.

[21]  Françoise Condé,et al.  Fetal striatal allografts reverse cognitive deficits in a primate model of Huntington disease , 1998, Nature Medicine.

[22]  Sébastien Ourselin,et al.  Block Matching: A General Framework to Improve Robustness of Rigid Registration of Medical Images , 2000, MICCAI.

[23]  D. Kraitchman,et al.  Stem cell therapy: MRI guidance and monitoring , 2008, Journal of magnetic resonance imaging : JMRI.

[24]  Alan C. Evans,et al.  BigBrain: An Ultrahigh-Resolution 3D Human Brain Model , 2013, Science.

[25]  Hyunjin Park,et al.  Detection of Aggressive Primary Prostate Cancer with 11C-Choline PET/CT Using Multimodality Fusion Techniques , 2009, Journal of Nuclear Medicine.

[26]  E. Susaki,et al.  Whole-Brain Imaging with Single-Cell Resolution Using Chemical Cocktails and Computational Analysis , 2014, Cell.

[27]  N. Ayache,et al.  Three-dimensional reconstruction of stained histological slices and 3D non-linear registration with in-vivo MRI for whole baboon brain , 2007, Journal of Neuroscience Methods.

[28]  Frithjof Kruggel,et al.  Quantitative comparison of high-resolution MRI and myelin-stained histology of the human cerebral cortex , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[29]  David R. Haynor,et al.  PET-CT image registration in the chest using free-form deformations , 2003, IEEE Transactions on Medical Imaging.

[30]  Aaron S. Andalman,et al.  Structural and molecular interrogation of intact biological systems , 2013, Nature.

[31]  Maik Stille,et al.  3D reconstruction of 2D fluorescence histology images and registration with in vivo MR images: Application in a rodent stroke model , 2013, Journal of Neuroscience Methods.

[32]  Stefan Klein,et al.  Supervised in-vivo plaque characterization incorporating class label uncertainty , 2012, 2012 9th IEEE International Symposium on Biomedical Imaging (ISBI).

[33]  Maged Goubran,et al.  Magnetic resonance imaging and histology correlation in the neocortex in temporal lobe epilepsy , 2015, Annals of neurology.

[34]  Allan R. Jones,et al.  A mesoscale connectome of the mouse brain , 2014, Nature.

[35]  Emmanuel Luc Barbier,et al.  Microvascular MRI and Unsupervised Clustering Yields Histology-Resembling Images in Two Rat Models of Glioma , 2014, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[36]  Philippe Hantraye,et al.  Reactive Astrocytes Overexpress TSPO and Are Detected by TSPO Positron Emission Tomography Imaging , 2012, The Journal of Neuroscience.

[37]  O. Lindvall,et al.  Stem cells for the treatment of neurological disorders , 2006, Nature.

[38]  Polina Golland,et al.  Permutation Tests for Classification: Towards Statistical Significance in Image-Based Studies , 2003, IPMI.