Multimodal image fusion via deep generative models

Recently, it has become progressively more evident that classic diagnostic labels are unable to accurately and reliably describe the complexity and variability of several clinical phenotypes. This is particularly true for a broad range of neuropsychiatric illnesses such as depression and anxiety disorders or behavioural phenotypes such as aggression and antisocial personality. Patient heterogeneity can be better described and conceptualized by grouping individuals into novel categories, which are based on empirically-derived sections of intersecting continua that span both across and beyond traditional categorical borders. In this context, neuroimaging data carry a wealth of spatiotemporally resolved information about each patient’s brain. However, they are usually heavily collapsed a priori through procedures which are not learned as part of model training, and consequently not optimized for the downstream prediction task. This is due to the fact that every individual participant usually comes with multiple whole-brain 3D imaging modalities often accompanied by a deep genotypic and phenotypic characterization, hence posing formidable computational challenges. In this paper we design and validate a deep learning architecture based on generative models rooted in a modular approach and separable convolutional blocks (which result in a 20-fold decrease in parameter utilization) in order to a) fuse multiple 3D neuroimaging modalities on a voxel-wise level, b) efficiently convert them into informative latent embeddings through heavy dimensionality reduction, c) maintain excellent generalizability and minimal information loss. As proof of concept, we test our architecture on the well characterized Human Connectome Project database (n=974 healthy subjects), demonstrating that our latent embeddings can be clustered into easily separable subject strata which, in turn, map to extremely different phenotypical information (including organic, neuropsychological, personality variables) which was not included in the embedding creation process. The ability to extract meaningful and separable phenotypic information from brain images alone can aid in creating multi-dimensional biomarkers able to chart spatio-temporal trajectories which may correspond to different pathophysiological mechanisms unidentifiable to traditional data analysis approaches. In turn, this may be of aid in predicting disease evolution as well as drug response, hence supporting mechanistic disease understanding and also empowering clinical trials.

[1]  Antonio J. Plaza,et al.  Image Segmentation Using Deep Learning: A Survey , 2020, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[2]  S. Rose,et al.  Predicting motor outcome in preterm infants from very early brain diffusion MRI using a deep learning convolutional neural network (CNN) model , 2020, NeuroImage.

[3]  Nannan Li,et al.  MRI Cross-Modality Image-to-Image Translation , 2020, Scientific Reports.

[4]  B. S. Manjunath,et al.  Improving Patch-Based Convolutional Neural Networks for MRI Brain Tumor Segmentation by Leveraging Location Information , 2020, Frontiers in Neuroscience.

[5]  Michel Thiebaut de Schotten,et al.  Biomarker-guided clustering of Alzheimer's disease clinical syndromes , 2019, Neurobiology of Aging.

[6]  Christian F Beckmann,et al.  Inter-individual differences in human brain structure and morphology link to variation in demographics and behavior , 2019, eLife.

[7]  Mohamed El Halaby,et al.  The Application of Unsupervised Clustering Methods to Alzheimer’s Disease , 2019, Front. Comput. Neurosci..

[8]  Pietro Liò,et al.  A parameter-efficient deep learning approach to predict conversion from mild cognitive impairment to Alzheimer's disease , 2018, NeuroImage.

[9]  Fei Wang,et al.  Data-Driven Subtyping of Parkinson’s Disease Using Longitudinal Clinical Records: A Cohort Study , 2019, Scientific Reports.

[10]  Malay Kishore Dutta,et al.  Optimized High Resolution 3D Dense-U-Net Network for Brain and Spine Segmentation , 2019, Applied Sciences.

[11]  Arvid Lundervold,et al.  An overview of deep learning in medical imaging focusing on MRI , 2018, Zeitschrift fur medizinische Physik.

[12]  Conrad S. Tucker,et al.  An unsupervised machine learning method for discovering patient clusters based on genetic signatures , 2018, J. Biomed. Informatics.

[13]  Vijay Vasudevan,et al.  Learning Transferable Architectures for Scalable Image Recognition , 2017, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[14]  Xinghua Lu,et al.  Unsupervised deep learning reveals prognostically relevant subtypes of glioblastoma , 2017, BMC Bioinformatics.

[15]  Bo Chen,et al.  MobileNets: Efficient Convolutional Neural Networks for Mobile Vision Applications , 2017, ArXiv.

[16]  D. Ikeda,et al.  Unsupervised Clustering of Quantitative Image Phenotypes Reveals Breast Cancer Subtypes with Distinct Prognoses and Molecular Pathways , 2017, Clinical Cancer Research.

[17]  Cam-CAN Group,et al.  The Cambridge Centre for Ageing and Neuroscience (Cam-CAN) data repository: Structural and functional MRI, MEG, and cognitive data from a cross-sectional adult lifespan sample , 2017, NeuroImage.

[18]  Giovanni Montana,et al.  Predicting brain age with deep learning from raw imaging data results in a reliable and heritable biomarker , 2016, NeuroImage.

[19]  François Chollet,et al.  Xception: Deep Learning with Depthwise Separable Convolutions , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[20]  Eric E. Smith,et al.  Multiple comorbid neuropathologies in the setting of Alzheimer's disease neuropathology and implications for drug development , 2016, Alzheimer's & dementia.

[21]  Christopher Joseph Pal,et al.  Brain tumor segmentation with Deep Neural Networks , 2015, Medical Image Anal..

[22]  Keith A. Johnson,et al.  A/T/N: An unbiased descriptive classification scheme for Alzheimer disease biomarkers , 2016, Neurology.

[23]  Jian Sun,et al.  Deep Residual Learning for Image Recognition , 2015, 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[24]  Geoffrey E. Hinton,et al.  Deep Learning , 2015, Nature.

[25]  Thomas Brox,et al.  U-Net: Convolutional Networks for Biomedical Image Segmentation , 2015, MICCAI.

[26]  P. Elliott,et al.  UK Biobank: An Open Access Resource for Identifying the Causes of a Wide Range of Complex Diseases of Middle and Old Age , 2015, PLoS medicine.

[27]  Sergey Ioffe,et al.  Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift , 2015, ICML.

[28]  Jimmy Ba,et al.  Adam: A Method for Stochastic Optimization , 2014, ICLR.

[29]  Nitish Srivastava,et al.  Dropout: a simple way to prevent neural networks from overfitting , 2014, J. Mach. Learn. Res..

[30]  Xin Wang,et al.  Dissecting cancer heterogeneity--an unsupervised classification approach. , 2013, The international journal of biochemistry & cell biology.

[31]  Steen Moeller,et al.  Advances in diffusion MRI acquisition and processing in the Human Connectome Project , 2013, NeuroImage.

[32]  Essa Yacoub,et al.  The WU-Minn Human Connectome Project: An overview , 2013, NeuroImage.

[33]  Mark Jenkinson,et al.  The minimal preprocessing pipelines for the Human Connectome Project , 2013, NeuroImage.

[34]  Benson Mwangi,et al.  A Review of Feature Reduction Techniques in Neuroimaging , 2013, Neuroinformatics.

[35]  T. Lasko,et al.  Computational Phenotype Discovery Using Unsupervised Feature Learning over Noisy, Sparse, and Irregular Clinical Data , 2013, PloS one.

[36]  R. Deriche,et al.  Design of multishell sampling schemes with uniform coverage in diffusion MRI , 2013, Magnetic resonance in medicine.

[37]  Daniel C. Alexander,et al.  NODDI: Practical in vivo neurite orientation dispersion and density imaging of the human brain , 2012, NeuroImage.

[38]  A. Singleton,et al.  The Parkinson Progression Marker Initiative (PPMI) , 2011, Progress in Neurobiology.

[39]  Maurizio Marchese,et al.  Text Clustering with Seeds Affinity Propagation , 2011, IEEE Transactions on Knowledge and Data Engineering.

[40]  H. Shill,et al.  Heterogeneous neuropathological findings in Parkinson’s disease with mild cognitive impairment , 2010, Acta Neuropathologica.

[41]  Shoshana J. Wodak,et al.  Markov clustering versus affinity propagation for the partitioning of protein interaction graphs , 2009, BMC Bioinformatics.

[42]  Delbert Dueck,et al.  Clustering by Passing Messages Between Data Points , 2007, Science.

[43]  C. Jack,et al.  Ways toward an early diagnosis in Alzheimer’s disease: The Alzheimer’s Disease Neuroimaging Initiative (ADNI) , 2005, Alzheimer's & Dementia.

[44]  David Sheskin,et al.  The Kruskal-Wallis One-way Analysis of Variance by Ranks , 2003 .

[45]  Y. Benjamini,et al.  Controlling the false discovery rate: a practical and powerful approach to multiple testing , 1995 .

[46]  P. Rousseeuw Silhouettes: a graphical aid to the interpretation and validation of cluster analysis , 1987 .