Your search keyword '"pathology imaging"' showing total 9 results

1. Graph Deep Learning for Pathology Imaging and Heterogeneous Medical Data

Author

Wang, Zichen

Subjects

Biomedical engineering, Medical imaging, Computer science, Graph Deep Learning, Graph Neural Network, Heterogeneous Medical Data, Pathology Imaging

Abstract

Graphs are a universal language for describing systems composed of interacting elements. In biomedicine, graph-structured data are pervasive, ranging from molecular and cellular interaction networks to healthcare knowledge graphs. Graph neural networks (GNNs) have initiated a new paradigm for graph representation learning. Moreover, the Transformer model, conceptually a specialized form of GNN, has been pushing the boundaries in the most impactful domains of machine learning over the past half-decade. These domains range from language modeling and computer vision to computational biology. However, the complex nature of biomedical data poses significant technical challenges for graph learning, including heterogeneity, multi-scale interactions, and limited data annotations. This dissertation attempts to address these obstacles across various biomedical applications, including pathology image analysis and heterogeneous data integration. We first introduce a bipartite graph convolutional network for drug repurposing through heterogeneous information fusion. Additionally, we present a temporal graph learning method that leverages heterogeneous electronic health record (EHR) to improve depression prediction. We further advance graph deep learning techniques for histopathology image analysis across multiple magnification levels, including patient-level survival prediction and tissue-level tumor microenvironment modeling. Lastly, inspired by recent advances in vector-quantized image modeling and Generative Pretrained Transformer (GPT), we propose a self-supervised learning framework tailored for computational pathology. Our approach explores pretraining and fine-tuning strategies to improve generalizable pathology image representation learning, thus facilitating the development of data-efficient deep learning models for various clinical workflows. Together, these methods demonstrate the versatility and effectiveness of graph deep learning in addressing complex biomedical challenges, paving the way for real-world applications in disease modeling, diagnosis, and treatment optimization.

Published

2024

2. High‐Quality Artery Monitoring and Pathology Imaging Achieved by High‐Performance Synchronous Electrical and Optical Output of Near‐Infrared Organic Photodetector.

Author

He, Zeyu, Du, Xiaoyang, Zheng, Caijun, Yu, Xin, Lin, Hui, and Tao, Silu

Subjects

*PHOTODETECTORS, *HEART beat, *TECHNOLOGICAL innovations, *LARGE intestine, *ARTERIES

Abstract

Near‐infrared organic photodetectors (NIR‐OPDs) are significant technologies in emerging biomedicine applications for uniquely wearable, noninvasive, low‐cost advantages. However, biosignals are weak and changing rapidly so practical biodetection and bioimaging are still challenging for NIR‐OPDs. Herein, high‐performance NIR‐OPDs with synchronous optical output are realized by recombining anode‐injected electrons with photogenerated holes on emitters. Owing to high detection performance of 4.5 × 1012 Jones detectivity and 120 kHz −3 dB bandwidth, five arteries are monitored by transmission‐type method and cardiac cycle is analyzed. Importantly, the synchronous optical output is direct emission demonstrating outstanding photon conversion efficiency approaching 20% and luminance signal‐to‐noise ratio over 8000. Consequently, pathology imaging is directly developed without complex readout circuits and arrays from which squamous metaplasia of cervix and carcinoma of large intestine are observed clearly. The NIR‐OPD demonstrates strategies for high‐performance synchronous electrical/optical output and directly imaging. Biomedicine applications implemented here are high level, representing important steps for NIR‐OPDs toward providing clues for clinical diagnosis. [ABSTRACT FROM AUTHOR]

Published

2023

3. Three-Dimensional Data Analytics for Pathology Imaging

Author

Liang, Yanhui, Kong, Jun, Zhu, Yangyang, Wang, Fusheng, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Wang, Fusheng, editor, Luo, Gang, editor, Weng, Chunhua, editor, Khan, Arijit, editor, Mitra, Prasenjit, editor, and Yu, Cong, editor

Published

2016

4. Pathology Imaging

Author

Shekhar, Shashi, editor, Xiong, Hui, editor, and Zhou, Xun, editor

Published

2017

5. A high-performance spatial database based approach for pathology imaging algorithm evaluation.

Author

Fusheng Wang, Jun Kong, Jingjing Gao, Lee A. D. Cooper, Tahsin Kurc, Zhengwen Zhou, Adler, David, Vergara-Niedermayr, Cristobal, Katigbak, Bryan, Brat, Daniel J., and Saltz, Joel H.

Subjects

*ALGORITHMS, *PATHOLOGY, *SQL, *DATABASE management, *IMAGE analysis

Abstract

Background: Algorithm evaluation provides a means to characterize variability across image analysis algorithms, validate algorithms by comparison with human annotations, combine results from multiple algorithms for performance improvement, and facilitate algorithm sensitivity studies. The sizes of images and image analysis results in pathology image analysis pose significant challenges in algorithm evaluation. We present an efficient parallel spatial database approach to model, normalize, manage, and query large volumes of analytical image result data. This provides an efficient platform for algorithm evaluation. Our experiments with a set of brain tumor images demonstrate the application, scalability, and effectiveness of the platform. Context: The paper describes an approach and platform for evaluation of pathology image analysis algorithms. The platform facilitates algorithm evaluation through a high-performance database built on the Pathology Analytic Imaging Standards (PAIS) data model. Aims: (1) Develop a framework to support algorithm evaluation by modeling and managing analytical results and human annotations from pathology images; (2) Create a robust data normalization tool for converting, validating, and fixing spatial data from algorithm or human annotations; (3) Develop a set of queries to support data sampling and result comparisons; (4) Achieve high performance computation capacity via a parallel data management infrastructure, parallel data loading and spatial indexing optimizations in this infrastructure. Materials and Methods: We have considered two scenarios for algorithm evaluation: (1) algorithm comparison where multiple result sets from different methods are compared and consolidated; and (2) algorithm validation where algorithm results are compared with human annotations. We have developed a spatial normalization toolkit to validate and normalize spatial boundaries produced by image analysis algorithms or human annotations. The validated data were formatted based on the PAIS data model and loaded into a spatial database. To support efficient data loading, we have implemented a parallel data loading tool that takes advantage of multi-core CPUs to accelerate data injection. The spatial database manages both geometric shapes and image features or classifications, and enables spatial sampling, result comparison, and result aggregation through expressive structured query language (SQL) queries with spatial extensions. To provide scalable and efficient query support, we have employed a shared nothing parallel database architecture, which distributes data homogenously across multiple database partitions to take advantage of parallel computation power and implements spatial indexing to achieve high I/O throughput. Results: Our work proposes a high performance, parallel spatial database platform for algorithm validation and comparison. This platform was evaluated by storing, managing, and comparing analysis results from a set of brain tumor whole slide images. The tools we develop are open source and available to download. Conclusions: Pathology image algorithm validation and comparison are essential to iterative algorithm development and refinement. One critical component is the support for queries involving spatial predicates and comparisons. In our work, we develop an efficient data model and parallel database approach to model, normalize, manage and query large volumes of analytical image result data. Our experiments demonstrate that the data partitioning strategy and the grid-based indexing result in good data distribution across database nodes and reduce I/O overhead in spatial join queries through parallel retrieval of relevant data and quick subsetting of datasets. The set of tools in the framework provide a full pipeline to normalize, load, manage and query analytical results for algorithm evaluation. [ABSTRACT FROM AUTHOR]

Published

2013

6. Experimental and Analysis of Electromagnetic Characterization of Biological and Non-Biological Materials in Microwave, Millimeter-wave, and Terahertz Frequency Bands

Author

Vohra, Nagma

Subjects

Breast Cancer, Free-Space millimeter-wave measurements, Material Characterization, Microwave and millimeter-wave measurements, Pathology imaging, Terahertz Imaging and Spectroscopy, Bioimaging and Biomedical Optics, Biomedical, Biomedical Devices and Instrumentation, Cancer Biology, Electrical and Electronics, Electromagnetics and Photonics, Medical Pathology

Abstract

The goal of this research is to characterize the electromagnetic properties of biological and non-biological materials at terahertz (THz), millimeter-wave, and microwave frequency bands. The biological specimens are measured using the THz imaging and spectroscopy system, whereas the non-biological materials are measured using the microwave and millimeter-wave free-space system. These facilities are located in the Engineering Research Center at the University of Arkansas. The THz imaging system (TPS 3000) uses a Ti-Sapphire laser directed on the photoconductive antennas to generate a THz time domain pulse. Upon using the Fourier Transform, the spectrum of the pulsed THz signal includes frequencies from 0.1 THz to 4 THz. On the other hand, the free space system uses a PNA network analyzer to produce a signal at frequencies ranging from 10 MHz to 110 GHz. For the biological specimens, the research focused on imaging the freshly excised breast tumors to detect the cancer on the margins using THz radiation. The tumor margin assessment depends on the THz contrast between cancer, collagen, and fat tissues in the tumor. Three models of breast tumors are investigated in this research: humans, mice (xenograft and transgenic), and Sprague Dawley rats. The results showed good differentiation between the cancerous and non-cancerous tissues in all three models. In addition, an excellent distinction was observed between cancer, collagen, and fat in the formalin-fixed paraffin-embedded (FFPE) block tissue with ~ 90-95% correlation with the pathology images. Furthermore, the FFPE ductal carcinoma in situ (DCIS) tumors are investigated, also using the THz imaging. The THz images of the DCIS samples are compared with those of the FFPE invasive ductal carcinoma (IDC) specimens. The results demonstrated that THz electric field reflection from the IDC were higher than that from the collagen, DCIS, and then the fat tissue region. Furthermore, a pilot study is conducted to investigate the effect of optical clearance (e.g., glycerol solution) on THz images of freshly excised tumors. The results showed that the glycerol reduced the absorption coefficients of pre-treated tissues compared with those of untreated tissues. For the non-biological materials, the research focuses on characterizing highly conductive non-magnetic radar absorbing materials (RAM) for the automotive industry. The ingredients of material components in the RAM samples are unrevealed under a non-disclosure agreement (NDA). The material characterization involves the extraction of the complex relative permittivity utilizing the transmission measurement data obtained at the K-band (18 GHz to 26.5 GHz) and the W-band (75 GHz to 110 GHz). The measurements are obtained using the free-space conical horn antenna system. A transmission line based extraction model is implemented, and the results are validated with the experimental measurements of the S-parameters. The maximum error reported between the measured and the calculated S-parameters was less than 1 dB. In conclusion, the THz imaging of breast cancer tumors presents a potential margin assessment of other solid tumors, and the microwave, millimeter-wave, and THz spectroscopy of materials demonstrate a potential application in the fifth and sixth generations of wireless communications.

Published

2021

7. A high-performance spatial database based approach for pathology imaging algorithm evaluation

Author

Tahsin Kurc, Cristobal Vergara-Niedermayr, Fusheng Wang, Jun Kong, David William Adler, Jingjing Gao, Lee Cooper, Bryan Katigbak, Zhengwen Zhou, Joel H. Saltz, and Daniel J. Brat

Subjects

SQL, Pathology, medicine.medical_specialty, Computer science, Data management, Health Informatics, lcsh:Computer applications to medicine. Medical informatics, computer.software_genre, Pathology and Forensic Medicine, Algorithm validation, Shared nothing architecture, lcsh:Pathology, medicine, pathology imaging, spatial database, Spatial analysis, computer.programming_language, parallel database, business.industry, Parallel database, Spatial database, Computer Science Applications, Spatial query, Scalability, lcsh:R858-859.7, Data mining, business, computer, lcsh:RB1-214, Research Article

Abstract

Background: Algorithm evaluation provides a means to characterize variability across image analysis algorithms, validate algorithms by comparison with human annotations, combine results from multiple algorithms for performance improvement, and facilitate algorithm sensitivity studies. The sizes of images and image analysis results in pathology image analysis pose significant challenges in algorithm evaluation. We present an efficient parallel spatial database approach to model, normalize, manage, and query large volumes of analytical image result data. This provides an efficient platform for algorithm evaluation. Our experiments with a set of brain tumor images demonstrate the application, scalability, and effectiveness of the platform. Context: The paper describes an approach and platform for evaluation of pathology image analysis algorithms. The platform facilitates algorithm evaluation through a high-performance database built on the Pathology Analytic Imaging Standards (PAIS) data model. Aims: (1) Develop a framework to support algorithm evaluation by modeling and managing analytical results and human annotations from pathology images; (2) Create a robust data normalization tool for converting, validating, and fixing spatial data from algorithm or human annotations; (3) Develop a set of queries to support data sampling and result comparisons; (4) Achieve high performance computation capacity via a parallel data management infrastructure, parallel data loading and spatial indexing optimizations in this infrastructure. Materials and Methods: We have considered two scenarios for algorithm evaluation: (1) algorithm comparison where multiple result sets from different methods are compared and consolidated; and (2) algorithm validation where algorithm results are compared with human annotations. We have developed a spatial normalization toolkit to validate and normalize spatial boundaries produced by image analysis algorithms or human annotations. The validated data were formatted based on the PAIS data model and loaded into a spatial database. To support efficient data loading, we have implemented a parallel data loading tool that takes advantage of multi-core CPUs to accelerate data injection. The spatial database manages both geometric shapes and image features or classifications, and enables spatial sampling, result comparison, and result aggregation through expressive structured query language (SQL) queries with spatial extensions. To provide scalable and efficient query support, we have employed a shared nothing parallel database architecture, which distributes data homogenously across multiple database partitions to take advantage of parallel computation power and implements spatial indexing to achieve high I/O throughput. Results: Our work proposes a high performance, parallel spatial database platform for algorithm validation and comparison. This platform was evaluated by storing, managing, and comparing analysis results from a set of brain tumor whole slide images. The tools we develop are open source and available to download. Conclusions: Pathology image algorithm validation and comparison are essential to iterative algorithm development and refinement. One critical component is the support for queries involving spatial predicates and comparisons. In our work, we develop an efficient data model and parallel database approach to model, normalize, manage and query large volumes of analytical image result data. Our experiments demonstrate that the data partitioning strategy and the grid-based indexing result in good data distribution across database nodes and reduce I/O overhead in spatial join queries through parallel retrieval of relevant data and quick subsetting of datasets. The set of tools in the framework provide a full pipeline to normalize, load, manage and query analytical results for algorithm evaluation.

Published

2012

8. A high-performance spatial database based approach for pathology imaging algorithm evaluation.

Author

Wang F, Kong J, Gao J, Cooper LA, Kurc T, Zhou Z, Adler D, Vergara-Niedermayr C, Katigbak B, Brat DJ, and Saltz JH

Abstract

Background: Algorithm evaluation provides a means to characterize variability across image analysis algorithms, validate algorithms by comparison with human annotations, combine results from multiple algorithms for performance improvement, and facilitate algorithm sensitivity studies. The sizes of images and image analysis results in pathology image analysis pose significant challenges in algorithm evaluation. We present an efficient parallel spatial database approach to model, normalize, manage, and query large volumes of analytical image result data. This provides an efficient platform for algorithm evaluation. Our experiments with a set of brain tumor images demonstrate the application, scalability, and effectiveness of the platform., Context: The paper describes an approach and platform for evaluation of pathology image analysis algorithms. The platform facilitates algorithm evaluation through a high-performance database built on the Pathology Analytic Imaging Standards (PAIS) data model., Aims: (1) Develop a framework to support algorithm evaluation by modeling and managing analytical results and human annotations from pathology images; (2) Create a robust data normalization tool for converting, validating, and fixing spatial data from algorithm or human annotations; (3) Develop a set of queries to support data sampling and result comparisons; (4) Achieve high performance computation capacity via a parallel data management infrastructure, parallel data loading and spatial indexing optimizations in this infrastructure., Materials and Methods: WE HAVE CONSIDERED TWO SCENARIOS FOR ALGORITHM EVALUATION: (1) algorithm comparison where multiple result sets from different methods are compared and consolidated; and (2) algorithm validation where algorithm results are compared with human annotations. We have developed a spatial normalization toolkit to validate and normalize spatial boundaries produced by image analysis algorithms or human annotations. The validated data were formatted based on the PAIS data model and loaded into a spatial database. To support efficient data loading, we have implemented a parallel data loading tool that takes advantage of multi-core CPUs to accelerate data injection. The spatial database manages both geometric shapes and image features or classifications, and enables spatial sampling, result comparison, and result aggregation through expressive structured query language (SQL) queries with spatial extensions. To provide scalable and efficient query support, we have employed a shared nothing parallel database architecture, which distributes data homogenously across multiple database partitions to take advantage of parallel computation power and implements spatial indexing to achieve high I/O throughput., Results: Our work proposes a high performance, parallel spatial database platform for algorithm validation and comparison. This platform was evaluated by storing, managing, and comparing analysis results from a set of brain tumor whole slide images. The tools we develop are open source and available to download., Conclusions: Pathology image algorithm validation and comparison are essential to iterative algorithm development and refinement. One critical component is the support for queries involving spatial predicates and comparisons. In our work, we develop an efficient data model and parallel database approach to model, normalize, manage and query large volumes of analytical image result data. Our experiments demonstrate that the data partitioning strategy and the grid-based indexing result in good data distribution across database nodes and reduce I/O overhead in spatial join queries through parallel retrieval of relevant data and quick subsetting of datasets. The set of tools in the framework provide a full pipeline to normalize, load, manage and query analytical results for algorithm evaluation.

Published

2013

9. Towards Building a High Performance Spatial Query System for Large Scale Medical Imaging Data.

Author

Aji A, Wang F, and Saltz JH

Abstract

Support of high performance queries on large volumes of scientific spatial data is becoming increasingly important in many applications. This growth is driven by not only geospatial problems in numerous fields, but also emerging scientific applications that are increasingly data- and compute-intensive. For example, digital pathology imaging has become an emerging field during the past decade, where examination of high resolution images of human tissue specimens enables more effective diagnosis, prediction and treatment of diseases. Systematic analysis of large-scale pathology images generates tremendous amounts of spatially derived quantifications of micro-anatomic objects, such as nuclei, blood vessels, and tissue regions. Analytical pathology imaging provides high potential to support image based computer aided diagnosis. One major requirement for this is effective querying of such enormous amount of data with fast response, which is faced with two major challenges: the "big data" challenge and the high computation complexity. In this paper, we present our work towards building a high performance spatial query system for querying massive spatial data on MapReduce. Our framework takes an on demand index building approach for processing spatial queries and a partition-merge approach for building parallel spatial query pipelines, which fits nicely with the computing model of MapReduce. We demonstrate our framework on supporting multi-way spatial joins for algorithm evaluation and nearest neighbor queries for microanatomic objects. To reduce query response time, we propose cost based query optimization to mitigate the effect of data skew. Our experiments show that the framework can efficiently support complex analytical spatial queries on MapReduce.

Published

2012