Diffusion Histology Imaging Combining Diffusion Basis Spectrum Imaging (DBSI) and Machine Learning Improves Detection and Classification of Glioblastoma Pathology

Ye, Zezhong; Price, Richard L.; Liu, Xiran; Lin, Joshua; Yang, Qingsong; Sun, Peng; Wu, Anthony T.; Wang, Liang; Han, Rowland H.; Song, Chunyu; Yang, Ruimeng; Gary, Sam E.; Mao, Diane D.; Wallendorf, Michael; Campian, Jian; Li, Jr-Shin; Dahiya, Sonika; Kim, Albert H.

doi:10.1158/1078-0432.ccr-20-0736

Cited by 22 publications

(16 citation statements)

References 46 publications

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“…Another study discovered a radiomic subtype of GBM with poor prognosis which might respond better to immunotherapy [ 79 ]. These findings might help answer critical clinical concerns, including determining the difference between TP and PsP or radiation necrosis [ 80 ]. Given the importance of tumor microenvironment, this is an emerging field in radiomics, and many studies are currently underway.…”

Section: What Radiomics Offers: a Computational Perspectivementioning

confidence: 99%

Applications of Radiomics and Radiogenomics in High-Grade Gliomas in the Era of Precision Medicine

Kazerooni

Bagley

Akbari

et al. 2021

Cancers

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Machine learning (ML) integrated with medical imaging has introduced new perspectives in precision diagnostics of high-grade gliomas, through radiomics and radiogenomics. This has raised hopes for characterizing noninvasive and in vivo biomarkers for prediction of patient survival, tumor recurrence, and genomics and therefore encouraging treatments tailored to individualized needs. Characterization of tumor infiltration based on pre-operative multi-parametric magnetic resonance imaging (MP-MRI) scans may allow prediction of the loci of future tumor recurrence and thereby aid in planning the course of treatment for the patients, such as optimizing the extent of resection and the dose and target area of radiation. Imaging signatures of tumor genomics can help in identifying the patients who benefit from certain targeted therapies. Specifying molecular properties of gliomas and prediction of their changes over time and with treatment would allow optimization of treatment. In this article, we provide neuro-oncology, neuropathology, and computational perspectives on the promise of radiomics and radiogenomics for allowing personalized treatments of patients with gliomas and discuss the challenges and limitations of these methods in multi-institutional clinical trials and suggestions to mitigate the issues and the future directions.

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Section: What Radiomics Offers: a Computational Perspectivementioning

confidence: 99%

Applications of Radiomics and Radiogenomics in High-Grade Gliomas in the Era of Precision Medicine

Kazerooni

Bagley

Akbari

et al. 2021

Cancers

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“…Two-dimensional (2D) thin plate spline (TPS) registration was performed using MIPAV Version 10.0.0 (NIH, Bethda, MD) as described previously (28) to co-register ex vivo MR images with histology images. We first ensure the plane of histology section of the prostate specimens matched closely with the slice plane of the corresponding T2W images.…”

Section: Co-registration Between Ex Vivo Mri and Histology Imagesmentioning

confidence: 99%

“…We previously developed diffusion basis spectrum imaging (DBSI), which utilizes a data-driven multiple-tensor modeling approach to deconvolute cellular and structural profiles within an image voxel (24). DBSI-derived structural metrics distinguish and quantify various pathologies in an array of central nervous system (CNS) disorders (25)(26)(27)(28)(29). In this study, we examine whether DBSI-derived metrics reflect structural and cellular changes associated with PCa.…”

Section: Introductionmentioning

confidence: 99%

Deep neural network analysis employing diffusion basis spectrum imaging metrics as classifiers improves prostate cancer detection and grading

Yang

et al. 2021

Preprint

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Structural and cellular complexity of prostatic histopathology limits the accuracy of noninvasive detection and grading of prostate cancer (PCa). We addressed this limitation by employing a novel diffusion basis spectrum imaging (DBSI) to derive structurally-specific diffusion fingerprints reflecting various underlying prostatic structural and cellular components. We further developed diffusion histology imaging (DHI) by combining DBSI-derived structural fingerprints with a deep neural network (DNN) algorithm to more accurately classify different histopathological features and predict tumor grade in PCa. We examined 243 patients suspected with PCa using in vivo DBSI. The in vivo DBSI-derived diffusion metrics detected coexisting prostatic pathologies distinguishing inflammation, PCa, and benign prostatic hyperplasia. DHI distinguished PCa from benign peripheral and transition zone tissues with over 95% sensitivity and specificity. DHI also demonstrated over 90% sensitivity and specificity for Gleason score noninvasively. We present DHI as a novel diagnostic tool capable of noninvasive detection and grading of PCa.

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“…grading and sub-typing) and for high-grade cases histopathology examination is often required [6]. In histopathology, gliomas are classified based on the morphological features of the glial cells including increased cellularity, vascular proliferation, necrosis, and infiltration into normal brain parenchyma [11,17]. Oncologists examine patients' medical history, radiology scans, pathology slides and reports to provide suitable medical care for a person diagnosed with cancer.…”

Section: Introductionmentioning

confidence: 99%

Glioma Classification Using Multimodal Radiology and Histology Data

Hamidinekoo

Pieciak

Afzali

et al. 2021

Brainlesion: Glioma, Multiple Sclerosis, Stroke and Traumatic Brain Injuries

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Gliomas are brain tumours with a high mortality rate. There are various grades and sub-types of this tumour, and the treatment procedure varies accordingly. Clinicians and oncologists diagnose and categorise these tumours based on visual inspection of radiology and histology data. However, this process can be time-consuming and subjective. The computer-assisted methods can help clinicians to make better and faster decisions. In this paper, we propose a pipeline for automatic classification of gliomas into three sub-types: oligodendroglioma, astrocytoma, and glioblastoma, using both radiology and histopathology images. The proposed approach implements distinct classification models for radiographic and histologic modalities and combines them through an ensemble method. The classification algorithm initially carries out tile-level (for histology) and slice-level (for radiology) classification via a deep learning method, then tile/slice-level latent features are combined for a wholeslide and whole-volume sub-type prediction. The classification algorithm was evaluated using the data set provided in the CPM-RadPath 2020 challenge. The proposed pipeline achieved the F1-Score of 0.886, Cohen's Kappa score of 0.811 and Balance accuracy of 0.860. The ability of the proposed model for end-to-end learning of diverse features enables it to give a comparable prediction of glioma tumour sub-types.

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Diffusion Histology Imaging Combining Diffusion Basis Spectrum Imaging (DBSI) and Machine Learning Improves Detection and Classification of Glioblastoma Pathology

Cited by 22 publications

References 46 publications

Applications of Radiomics and Radiogenomics in High-Grade Gliomas in the Era of Precision Medicine

Applications of Radiomics and Radiogenomics in High-Grade Gliomas in the Era of Precision Medicine

Deep neural network analysis employing diffusion basis spectrum imaging metrics as classifiers improves prostate cancer detection and grading

Glioma Classification Using Multimodal Radiology and Histology Data

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