Award Date

August 2024

Degree Type

Dissertation

Degree Name

Doctor of Philosophy (PhD)

Department

Computer Science

First Committee Member

Mingon Kang

Second Committee Member

Fatma Nasoz

Third Committee Member

Kazem Taghva

Fourth Committee Member

Laxmi Gewali

Fifth Committee Member

Mira Han

Number of Pages

100

Abstract

Automatic histopathological Whole Slide Image (WSI) analysis has been highlighted along with the advancements in microscopic imaging techniques, but manual examination and diagnosis of WSIs are time-consuming and tiresome. Recently, deep convolutional neural networks have succeeded in histopathological image analysis. Especially, Convolutional Neural Networks CNN models such as Inception and DenseNet have achieved effective performance. However, automatic histopathological WSI analysis still has significant drawbacks such as considering deep learning as black-box models, predicting disease independently on a small part of images (patch images) extracted from WSIs, limitations in predicting a single slide-based score for a patient, and capturing disease-specific morphology patterns (e.g., protein rearrangements and subtype morphology) from primary screening WSI images’ protein rearrangements. To address these gaps, I have developed three interpretable and evidential deep learning models: Deep-Hipo, HipoMap, and Deep-PATHO. My proposed model explains disease specific morphology patterns which were aligned with domain experts. In Deep-Hipo, I designed multi-scale receptive fields to simultaneously capture local information (20x patch) and global information (5x). Deep-Hipo achieved significant performance over state-of-the-art models by considering patch dependencies. The Histopathology representation Map (HipoMap) is a novel and generalized slide-score prediction framework for any CNN-based patch-wise pretraining models. HipoMap generates a slide-based prediction framework by generating one representation map for a WSI. My research shows that HipoMap can be extended to many applications such as cancer classification, survival prediction, survival analysis, and sub-type classification. Deep-PATHO is a novel deep-learning architecture that synchronizes morphology between local (High magnification) and global (Low magnification). Deep-PATHO has achieved significant performance in identifying complex morphological patterns of ALK rearrangements in WSI images.

Keywords

Convolutional Neural Network; Deep Learning; Health Informatics; Interpretation; Weakly Supervised

Disciplines

Bioinformatics | Computer Sciences

Degree Grantor

University of Nevada, Las Vegas

Language

English

Rights

IN COPYRIGHT. For more information about this rights statement, please visit http://rightsstatements.org/vocab/InC/1.0/

Available for download on Friday, August 15, 2025


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