Your search keyword '"Soner Koc"' showing total 12 results

1. Artificial intelligence assisted patient blood and urine droplet pattern analysis for non-invasive and accurate diagnosis of bladder cancer

Author

Ramiz Demir, Soner Koc, Deniz Gulfem Ozturk, Sukriye Bilir, Halil İbrahim Ozata, Rhodri Williams, John Christy, Yunus Akkoc, İlker Tinay, Cigdem Gunduz-Demir, and Devrim Gozuacik

Subjects

Medicine, Science

Abstract

Abstract Bladder cancer is one of the most common cancer types in the urinary system. Yet, current bladder cancer diagnosis and follow-up techniques are time-consuming, expensive, and invasive. In the clinical practice, the gold standard for diagnosis remains invasive biopsy followed by histopathological analysis. In recent years, costly diagnostic tests involving the use of bladder cancer biomarkers have been developed, however these tests have high false-positive and false-negative rates limiting their reliability. Hence, there is an urgent need for the development of cost-effective, and non-invasive novel diagnosis methods. To address this gap, here we propose a quick, cheap, and reliable diagnostic method. Our approach relies on an artificial intelligence (AI) model to analyze droplet patterns of blood and urine samples obtained from patients and comparing them to cancer-free control subjects. The AI-assisted model in this study uses a deep neural network, a ResNet network, pre-trained on ImageNet datasets. Recognition and classification of complex patterns formed by dried urine or blood droplets under different conditions resulted in cancer diagnosis with a high specificity and sensitivity. Our approach can be systematically applied across droplets, enabling comparisons to reveal shared spatial behaviors and underlying morphological patterns. Our results support the fact that AI-based models have a great potential for non-invasive and accurate diagnosis of malignancies, including bladder cancer.

Published

2024

2. BCO App: tools for generating BioCompute Objects from next-generation sequencing workflows and computations [version 1; peer review: 2 approved]

Author

Nan Xiao, Soner Koc, David Roberson, Phillip Brooks, Manisha Ray, and Dennis Dean

Subjects

Medicine, Science

Abstract

The BioCompute Object (BCO) standard is an IEEE standard (IEEE 2791-2020) designed to facilitate the communication of next-generation sequencing data analysis with applications across academia, government agencies, and industry. For example, the Food and Drug Administration (FDA) supports the standard for regulatory submissions and includes the standard in their Data Standards Catalog for the submission of HTS data. We created the BCO App to facilitate BCO generation in a range of computational environments and, in part, to participate in the Advanced Track of the precisionFDA BioCompute Object App-a-thon. The application facilitates the generation of BCOs from both workflow metadata provided as plaintext and from workflow contents written in the Common Workflow Language. The application can also access and ingest task execution results from the Cancer Genomics Cloud (CGC), an NCI funded computational platform. Creating a BCO from a CGC task significantly reduces the time required to generate a BCO on the CGC by auto-populating workflow information fields from CGC workflow and task execution results. The BCO App supports exporting BCOs as JSON or PDF files and publishing BCOs to both the CGC platform and to GitHub repositories.

Published

2020

3. Bioinformatics tools developed to support BioCompute Objects.

Author

Janisha A. Patel, Dennis A. Dean, Charles Hadley King, Nan Xiao 0002, Soner Koc, Ekaterina Minina, Anton Golikov, Phillip Brooks, Robel Y. Kahsay, Rahi Navelkar, Manisha Ray, Dave Roberson, Chris Armstrong, Raja Mazumder, and Jonathon Keeney

Published

2021

4. Comprehensive characterization of 536 patient-derived xenograft models prioritizes candidatesfor targeted treatment

Author

Li Chen, Jacqueline Mudd, Michael Ittmann, Carol J. Bult, Amanda R. Kirane, Jelena Randjelovic, Stephen Scott, Yige Wu, Li Ding, Vashisht G. Yennu-Nanda, Jing Wang, Christopher D. Lanier, Maihi Fujita, Emilio Cortes-Sanchez, Sienna Rocha, Susan G. Hilsenbeck, Kian-Huat Lim, Fernanda Martins Rodrigues, Jill Rubinstein, Nicholas Mitsiades, Haiyin Lin, Jayamanna Wickramasinghe, Andrew Butterfield, Bryan E. Welm, Alana L. Welm, Jose P. Zevallos, Jason Held, Nicole B. Coggins, Song Cao, Yuanxin Xi, Brenda C. Timmons, Paul Lott, David Menter, Shunqiang Li, Tina Primeau, Fei Yang, Andrea Wang-Gillam, Ramaswamy Govindan, Dali Li, Brandi Davis-Dusenbery, Sara Seepo, Michael C. Wendl, Jeffrey Grover, Brian S. White, Clifford G. Tepper, Peter N. Robinson, Michael A. Davies, Zhengtao Chu, Michael W. Lloyd, Hua Sun, Xiaoshan Zhang, Tamara Stankovic, Dylan Fingerman, Anuj Srivastava, Luis G. Carvajal-Carmona, Don L. Gibbons, Lijun Yao, Rebecca Aft, Hongyong Zhang, Ismail Meraz, John DiGiovanna, Scott Kopetz, Ling Zhao, Guadalupe Polanco-Echeverry, Feng Chen, Jeremy Hoog, Matthew A. Wyczalkowski, George Xu, John D. Minna, Yi Xu, Julie Belmar, Xiaowei Xu, Luc Girard, Dennis A. Dean, Tijana Borovski, Chong-xian Pan, Cynthia X. Ma, Alexa Morales Arana, Yize Li, Turcin Saridogan, Steven B. Neuhauser, Sandra Scherer, Vicki Chin, Rose Tipton, David R. Gandara, Sherri R. Davies, Argun Akcakanat, Rajesh Patidar, Julie K. Schwarz, Soner Koc, Gao Boning, Michael Kim, Bryce P. Kirby, Yvonne A. Evrard, Hyunsil Park, Christian Frech, Chia-Kuei Mo, Ran Zhang, Brian A. Van Tine, Jonathan W. Reiss, Min Xiao, Xing Yi Woo, Tiffany Le, Ana Estrada, Xiaofeng Zheng, Jeffrey A. Moscow, Mourad Majidi, Nadezhda V. Terekhanova, Katherine Fuh, Erkan Yuca, Timothy A. Yap, Jianhua Zhang, Matthew J. Ellis, Shannon Westin, James H. Doroshow, Vito W. Rebecca, Moon S. Chen, Coya Tapia, Reyka G Jayasinghe, Jack A. Roth, Jithesh Augustine, Ryan C. Fields, Michae T. Tetzlaff, Michael T. Lewis, Kurt W. Evans, Ralph W. deVere White, Brian J. Sanderson, May Cho, Jeffrey H. Chuang, Tiffany Wallace, Ryan Jeon, Ted Toal, Matthew H. Bailey, Bert W. O'Malley, Katherine L. Nathanson, Qin Liu, Benjamin J. Raphael, Jingqin Luo, Salma Kaochar, Huiqin Chen, Rajasekharan Somasundaram, Daniel Cui Zhou, John F. DiPersio, Andrew V. Kossenkov, Bingliang Fang, Vanessa Jensen, Simone Zaccaria, Alexey Sorokin, Ai-Hong Ma, Sidharth V. Puram, Min Jin Ha, Meenhard Herlyn, R. Jay Mashl, Kelly Gale, Bingbing Dai, Lacey E. Dobrolecki, Chieh-Hsiang Yang, and Funda Meric-Bernstam

Subjects

endocrine system, Science, Druggability, General Physics and Astronomy, Genomics, Computational biology, Biology, Genome, digestive system, General Biochemistry, Genetics and Molecular Biology, Article, Research community, Multiple time, medicine, Cancer genomics, Cancer models, Tumor xenograft, Multidisciplinary, Cancer, General Chemistry, medicine.disease, Pharmacogenomics, Data integration, hormones, hormone substitutes, and hormone antagonists

Abstract

Development of candidate cancer treatments is a resource-intensive process, with the research community continuing to investigate options beyond static genomic characterization. Toward this goal, we have established the genomic landscapes of 536 patient-derived xenograft (PDX) models across 25 cancer types, together with mutation, copy number, fusion, transcriptomic profiles, and NCI-MATCH arms. Compared with human tumors, PDXs typically have higher purity and fit to investigate dynamic driver events and molecular properties via multiple time points from same case PDXs. Here, we report on dynamic genomic landscapes and pharmacogenomic associations, including associations between activating oncogenic events and drugs, correlations between whole-genome duplications and subclone events, and the potential PDX models for NCI-MATCH trials. Lastly, we provide a web portal having comprehensive pan-cancer PDX genomic profiles and source code to facilitate identification of more druggable events and further insights into PDXs’ recapitulation of human tumors., Patient-derived xenograft models (PDX) have been extensively used to study the molecular and clinical features of cancers. Here the authors present a cohort of 536 PDX models from 25 cancers, as well as their genomic and evolutionary profiles and their suitability for clinical trials.

Published

2021

5. Abstract 5407: A pan-cancer PDX histology image repository with genomic and pathological annotations for deep learning analysis

Author

Brian S. White, Xing Yi Woo, Soner Koc, Todd Sheridan, Steven B. Neuhauser, Shidan Wang, Yvonne A. Evrard, John David Landua, R Jay Mashl, Sherri R. Davies, Bingliang Fang, Maria Gabriela Raso, Kurt W. Evans, Matthew H. Bailey, Yeqing Chen, Min Xiao, Jill Rubinstein, Ali Foroughi pour, Lacey Elizabeth Dobrolecki, Maihi Fujita, Junya Fujimoto, Guanghua Xiao, Ryan C. Fields, Jacqueline L. Mudd, Xiaowei Xu, Melinda G. Hollingshead, Shahanawaz Jiwani, PDXNet consortium, Tiffany A. Wallace, Jeffrey A. Moscow, James H. Doroshow, Nicholas Mitsiades, Salma Kaochar, Chong-xian Pan, Moon S. Chen, Luis G. Carvajal-Carmona, Alana L. Welm, Bryan E. Welm, Ramaswamy Govindan, Shunqiang Li, Michael A. Davies, Jack A. Roth, Funda Meric-Bernstam, Yang Xie, Meenhard Herlyn, Li Ding, Michael T. Lewis, Carol J. Bolt, Dennis A. Dean, and Jeffrey H. Chuang

Subjects

Cancer Research, Oncology

Abstract

Patient-derived xenografts (PDXs) model human intra-tumoral heterogeneity in the context of the intact tissue of immunocompromised mice. Histological imaging via hematoxylin and eosin (H&E) staining is performed on PDX samples for routine assessment and, in principle, captures the complex interplay between tumor and stromal cells. Deep learning (DL)-based analysis of large human H&E image repositories has extracted inter-cellular and morphological signals correlated with disease phenotype and therapeutic response. Here, we present an extensive, pan-cancer repository of nearly 1,000 PDX and paired human progenitor H&E images. These images, curated from the PDXNet consortium, are associated with genomic and transcriptomic data, clinical metadata, pathological assessment of cell composition, and, in several cases, detailed pathological annotation of tumor, stroma, and necrotic regions. We demonstrate that DL can be applied to these images to classify tumor regions with an accuracy of 0.87. Further, we show that DL can predict xenograft-transplant lymphoproliferative disorder, the unintended outgrowth of human lymphocytes at the transplantation site, with an accuracy of 0.97. This repository enables PDX-specific investigations of cancer biology through histopathological analysis and contributes important model system data that expand on existing human histology repositories. We expect the PDXNet Image Repository to be valuable for controlled digital pathology analysis, both for the evaluation of technical issues such as stain normalization and for development of novel computational methods based on spatial behaviors within cancer tissues. Citation Format: Brian S. White, Xing Yi Woo, Soner Koc, Todd Sheridan, Steven B. Neuhauser, Shidan Wang, Yvonne A. Evrard, John David Landua, R Jay Mashl, Sherri R. Davies, Bingliang Fang, Maria Gabriela Raso, Kurt W. Evans, Matthew H. Bailey, Yeqing Chen, Min Xiao, Jill Rubinstein, Ali Foroughi pour, Lacey Elizabeth Dobrolecki, Maihi Fujita, Junya Fujimoto, Guanghua Xiao, Ryan C. Fields, Jacqueline L. Mudd, Xiaowei Xu, Melinda G. Hollingshead, Shahanawaz Jiwani, PDXNet consortium, Tiffany A. Wallace, Jeffrey A. Moscow, James H. Doroshow, Nicholas Mitsiades, Salma Kaochar, Chong-xian Pan, Moon S. Chen, Luis G. Carvajal-Carmona, Alana L. Welm, Bryan E. Welm, Ramaswamy Govindan, Shunqiang Li, Michael A. Davies, Jack A. Roth, Funda Meric-Bernstam, Yang Xie, Meenhard Herlyn, Li Ding, Michael T. Lewis, Carol J. Bolt, Dennis A. Dean, Jeffrey H. Chuang. A pan-cancer PDX histology image repository with genomic and pathological annotations for deep learning analysis. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5407.

Published

2023

6. PDXNet portal: patient-derived Xenograft model, data, workflow and tool discovery

Author

Soner, Koc, Michael W, Lloyd, Jeffrey W, Grover, Nan, Xiao, Sara, Seepo, Sai Lakshmi, Subramanian, Manisha, Ray, Christian, Frech, John, DiGiovanna, Phillip, Webster, Steven, Neuhauser, Anuj, Srivastava, Xing Yi, Woo, Brian J, Sanderson, Brian, White, Paul, Lott, Lacey E, Dobrolecki, Heidi, Dowst, Yvonne A, Evrard, Tiffany A, Wallace, Jeffrey A, Moscow, James H, Doroshow, Nicholas, Mitsiades, Salma, Kaochar, Chong-Xian, Pan, Moon S, Chen, Luis, Carvajal-Carmona, Alana L, Welm, Bryan E, Welm, Michael T, Lewis, Ramaswamy, Govindan, Li, Ding, Shunqiang, Li, Meenhard, Herlyn, Michael A, Davies, Jack, Roth, Funda, Meric-Bernstam, Peter N, Robinson, Carol J, Bult, Brandi, Davis-Dusenbery, Dennis A, Dean, and Ai-Hong, Ma

Subjects

General Medicine

Abstract

We created the PDX Network (PDXNet) portal (https://portal.pdxnetwork.org/) to centralize access to the National Cancer Institute-funded PDXNet consortium resources, to facilitate collaboration among researchers and to make these data easily available for research. The portal includes sections for resources, analysis results, metrics for PDXNet activities, data processing protocols and training materials for processing PDX data. Currently, the portal contains PDXNet model information and data resources from 334 new models across 33 cancer types. Tissue samples of these models were deposited in the NCI’s Patient-Derived Model Repository (PDMR) for public access. These models have 2134 associated sequencing files from 873 samples across 308 patients, which are hosted on the Cancer Genomics Cloud powered by Seven Bridges and the NCI Cancer Data Service for long-term storage and access with dbGaP permissions. The portal includes results from freely available, robust, validated and standardized analysis workflows on PDXNet sequencing files and PDMR data (3857 samples from 629 patients across 85 disease types). The PDXNet portal is continuously updated with new data and is of significant utility to the cancer research community as it provides a centralized location for PDXNet resources, which support multi-agent treatment studies, determination of sensitivity and resistance mechanisms, and preclinical trials.

Published

2022

7. PDXNet Portal: Patient-Derived Xenograft model, data, workflow, and tool discovery

Author

Li Ding, Michael Davies, Xing Yi Woo, Jeffrey H. Chuang, Carol J. Bult, Chong-Xian Pan, Brian S. White, Yvonne A. Evrard, Alana L. Welm, Christian Frech, Manisha Ray, Ramaswamy Govindan, Salma Kaochar, John DiGiovanna, Paul Lott, Anuj Srivastava, Luis G. Carvajal-Carmona, Bryan E. Welm, Steven B. Neuhauser, Tiffany A. Wallace, Sai Lakshmi Subramanian, Meenherd Herlyn, Brandi N. Davis-Dusenbery, Phillip Webster, Dennis A. Dean, James H. Doroshow, Nicholas Mitsiades, Soner Koc, Jeffrey W. Grover, Jack A. Roth, Michael T. Lewis, Sara Seepo, Funda Meric-Bernstam, Shunquang Li, Michael Lloyd, Moon S. Chen, Peter N. Robinson, Jeffrey A. Moscow, and Brian J. Sanderson

Subjects

Public access, World Wide Web, Data processing, Service (systems architecture), Workflow, Computer science, business.industry, Genomics, Cloud computing, business, Data resources, Tumor xenograft

Abstract

We created the PDX Network (PDXNet) Portal (https://portal.pdxnetwork.org/) to centralize access to the National Cancer Institute-funded PDXNet consortium resources (i.e., PDX models, sequencing data, treatment response data, and bioinformatics workflows), to facilitate collaboration among researchers, and to make resources easily available for research. The portal includes sections for resources, analysis results, metrics for PDXNet activities, data processing protocols, and training materials for processing PDX data.The initial portal release highlights PDXNet model and data resources, including 334 new models across 33 cancer types. Tissue samples of these models were deposited in the NCI’s Patient-Derived Model Repository (PDMR) for public access. These models have 2,822 associated sequencing files from 873 samples across 307 patients, which are hosted on the Cancer Genomics Cloud powered by Seven Bridges and the NCI Cancer Data Service for long-term storage and access with dbGaP permissions. The portal also includes results from standardized analysis workflows on PDXNet sequencing files and PDMR data (2,594 samples from 463 patients across 78 disease types). These 15 analysis workflows for whole-exome and RNA-Seq data are freely available, robust, validated, and standardized.The model and data lists will grow substantially over the next two years and will be continuously updated as new data are available. PDXNet models support multi-agent treatment studies, determination of sensitivity and resistance mechanisms, and preclinical trials. The PDXNet portal is a centralized location for these data and resources, which we expect to be of significant utility for the cancer research community.

Published

2021

8. Abstract 6393: The Cancer Genomics Cloud enables bioinformatics training in a hybrid educational world

Author

Manisha Ray, Sai Lakshmi Subramanian, David Roberson, Zelia Worman, Dennis A. Dean, Soner Koc, Jack DiGiovanna, and Brandi Davis-Dusenbery

Subjects

Cancer Research, Oncology

Abstract

The Cancer Genomics Cloud (CGC), powered by Seven Bridges, is an NCI-funded platform that streamlines access to large cancer datasets, bioinformatic tools, and cloud computation for cancer researchers. The attributes of the CGC designed to democratize data analysis also make it ideal for training the next generation of data scientists. During the Covid-19 pandemic, it has become clear that remote/virtual learning is of great importance for workforce development, and that reducing barriers to high quality educational resources is critical for many populations. Here we present our best practices for education of bioinformatics using the CGC, taking advantage of both distributed cloud networks and platform features to enhance learning. Our best practices methods are focused on a systematic approach that takes the instructor and students through a typical bioinformatics workflow in their field of research. Briefly, the organizational structure of the CGC, known as “projects,'' contains all aspects of an analysis, including data files, tools, and tool settings. Projects have fine-grained permission settings, which allow the owner to securely share their project for viewing or editing. An instructor can generate an example analysis from start to finish then share an entire project with trainees. Both students and instructors have access to the same data on the cloud, so the teacher can pre-populate the projects with specific files, ensuring the same starting point. All members within the project can communicate, including adding notes directly on the results, allowing students to troubleshoot in real time with the teacher. Instructors can manage costs for the whole class through the CGC’s billing system. The CGC also provides Public Projects for self-guided training, where a researcher can learn by example using the data, tools, and completed tasks within the project, including detailed instructions embedded in markdown language. We have successfully used these methods to train masters students in bioinformatics at Georgetown University for three years, as well as high school students, college students, and current cancer researchers. This approach to virtual learning of bioinformatics can democratize training for the next generation of data scientists. The FAIR practices built into the CGC enables education across all levels of expertise, empowering users to drive cancer research from any stage of their career. Citation Format: Manisha Ray, Sai Lakshmi Subramanian, David Roberson, Zelia Worman, Dennis A. Dean, Soner Koc, Jack DiGiovanna, Brandi Davis-Dusenbery. The Cancer Genomics Cloud enables bioinformatics training in a hybrid educational world [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6393.

Published

2022

9. Abstract 6394: The SB Image Processing Toolkit: Machine learning for cancer research on the CGC

Author

Soner Koc, Jovana Babic, Nevena Nikolic, Ana Stankovic, Daniel Ventre, Manisha Ray, Zelia F. Worman, Sai Lakshmi Subramanian, Dennis A. Dean, Jack DiGiovanna, and Brandi Davis Dusenbery

Subjects

Cancer Research, Oncology

Abstract

Applying machine learning algorithms to analysis of multi-omics datasets has provided a wealth of analysis and interpretations of data not easily achievable by conventional methods. The Cancer Genomics Cloud (CGC), powered by Seven Bridges, offers many helpful features to simplify and streamline the performance of machine learning (ML) tasks on the platform. The CGC platform contains features and tools for all of the steps of a ML project, from data exploration, to model generation, to production, so that all key steps occur on the platform. The Data Cruncher interactive analysis tool enables users to perform data exploration, modeling, training, and visualization using familiar frameworks like Jupyterlab and RStudio. We applied this ML methodology to imaging tools, to create The SB Image Processing Toolkit. Here we demonstrate the use of this toolkit with specific cancer datasets, including training and analysis, with all steps taking place on the cloud. The SB Image Processing Toolkit is a collection of various deep-learning, preprocessing, and utility tools and workflows created with the purpose of performing image class prediction on any type of image data. The toolkit supports a variety of images used in cancer research, such as histopathology and radiology images, and common formats like JPG or PNG. There are nine distinct tools within the toolkit, including methods for quality control, normalization, preprocessing for histopathology or radiology images, classification, and deep learning. Together, these tools create an easy-to-use infrastructure to enable various stages of ML and Image Processing. Most importantly, it was designed to enable users to create and use ML image classifiers on the CGC without any coding experience. All workflows can be searched for and implemented via the Public Apps Gallery on the CGC. Users can import image data, run analysis, and compare results all in one environment. By harnessing the scale and flexibility of cloud computing, the SB Image Processing Toolkit brings massive speed and price improvements compared to manual writing and running model training scripts. In conjunction with the access to data and ease of use, the CGC makes complex machine learning methods accessible to any researcher. Citation Format: Soner Koc, Jovana Babic, Nevena Nikolic, Ana Stankovic, Daniel Ventre, Manisha Ray, Zelia F. Worman, Sai Lakshmi Subramanian, Dennis A. Dean, Jack DiGiovanna, Brandi Davis Dusenbery. The SB Image Processing Toolkit: Machine learning for cancer research on the CGC [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6394.

Published

2022

10. Strengthening the BioCompute Standard by Crowdsourcing on PrecisionFDA

Author

Dennis A. Dean, Elaine Johanson, Janisha A. Patel, Eric F. Donaldson, Soner Koc, Nan Xiao, Purkayastha A, Elaine E. Thompson, Raja Mazumder, Charles Hadley King, Stephens Sh, Sean Watford, and Jonathon Keeney

Subjects

World Wide Web, Class (computer programming), business.industry, Interface (Java), Computer science, Container (abstract data type), Crowdsourcing, business

Abstract

BackgroundThe field of bioinformatics has grown at such a rapid pace that a gap in standardization exists when reporting an analysis. In response, the BioCompute project was created to standardize the type and method of information communicated when describing a bioinformatic analysis. Once the project became established, its goals shifted to broadening awareness and usage of BioCompute, and soliciting feedback from a larger audience. To address these goals, the BioCompute project collaborated with precisionFDA on a crowdsourced challenge that ran from May 2019 to October 2019. This challenge had a beginner track where participants submitted BCOs based on a pipeline of their choosing, and an advanced track where participants submitted applications supporting the creation of a BCO and verification of BCO conformance to specifications.ResultsIn total, there were 28 submissions to the beginner track (including submissions from a bioinformatics master’s class at George Washington University) and three submissions to the advanced track. Three top performers were selected from the beginner track, while a single top performer was selected for the advanced track. In the beginner track, top performers differentiated themselves by submitting BCOs that included more than the minimally compliant content. Advanced track submissions were very impressive. They included a complete web application, a command line tool that produced a static result, and a dockerized container that automatically created the BCO as the tool was run. The ability to harmonize the correct function, a simple user experience, and the aesthetics of the tool interface differentiated the tools.ConclusionsDespite being new to the concept, most beginner track scores were high, indicating that most users understood the fundamental concepts of the BCO specification. Novice bioinformatics students were an ideal cohort for this Challenge because of their lack of familiarity with BioCompute, broad diversity of research interests, and motivation to submit high-quality work. This challenge was successful in introducing the BCO to a wider audience, obtaining feedback from that audience, and resulting in a tool novices may use for BCO creation and conformance. In addition, the BCO specification itself was improved based on feedback illustrating the utility of a “wisdom of the crowd” approach to standards development.

Published

2020

11. Abstract 3017: Advancing PDX research through model, data, and bioinformatics with the PDXNet Portal

Author

Soner Koc, Mike Lloyd, Steven Neuhauser, Javad Noodbakhsh, Anuj Srivastava, Xing Yi Woo, Ryan Jeon, Jeffrey Grover, Sara Seepo, Christian Frech, Jack DiGiovanna, PDXNet Consortium, Yvonne A. Evard, Tiffany Wallace, Jeffrey Moscow, James H. Doroshow, Nicholas Mitsuade, Salma Kaochar, Chong-xian Pan, Moon S. Chen, Luis Carvarjal-Carmona, Alana Welm, Bryan Welm, Michael T. Lewis, Govindan Ramaswamy, Li Ding, Shunquang Li, Meenherd Herlyn, Mike Davies, Jack Roth, Funda Meric-Bernstam, Peter Robinson, Carol J. Bult, Brandi Davis-Dusenbery, Dennis A. Dean, and Jeffrey H. Chuang

Subjects

Cancer Research, Oncology, Computer science, Computational biology

Abstract

We created the PDX Network (PDXNet) Portal to provide an intuitive way for researchers to explore and understand the models, sequencing data, and bioinformatics workflows generated by NCI's PDXNet consortium for research access (https://portal.pdxnetwork.org/). The portal also provides metrics for PDXNet's activities, data processing protocols, and training materials for processing PDX data. The PDXNet Portal highlights model and data resources that include 216 new models across 29 cancer types. The most prevalent cancers represented in the PDX model dataset include invasive breast carcinoma (30.6%), melanoma (18.1%), and adenocarcinoma (14.4%). PDXNet teams have provided 2263 sequencing files from 356 samples across 204 patients, comprising whole exome (82.9%) and RNA seq files (17.1%). The most prevalent cancers represented in the PDXNet sequencing data set include Breast Pleural Effusion (27.2%), Breast Poorly Differentiated (12.5%), and Lung Adenocarcinoma (9.6%). The portal also provides access to 9492 sequencing files across 78 disease types that include 2594 samples across 463 patients uploaded from the NCI Patient-Derived Model Repository. The dataset includes both whole exomes (52.8%) and RNA seq (47.2%) data. The PDMR samples include PDX (82.7%), primary tumor (5.7%), normal germline (5.5), organoid culture (3.2), and Mixed Tumor Culture (2.9). The PDMR dataset also has multiple passages: P0 (21.8%), P1(39.5%), P2 (25.6%), and P3 (8.5%). These models and data resources support ten PDXNet Pilot activities, multiple publications, and international collaborations. PDXNet has also developed a set of 13 robust, validated, and standardized workflows for processing PDXNet whole-exome and RNA seq data. Collectively, these workflows allow for the standardized processing of PDX and complementary human tissues (normal and tumor). Our plan is to continuously update the model and data lists on the PDX portal as resources are generated. We expect that the PDXNet generated models, scheduled to grow to 1000 new models by 2022, will support multi-agent treatment studies, determination of mechanisms of sensitivity and resistance, and pre-clinical trials for example through the COMBO-MATCH program. The robust standard workflows currently processing all PDX sequencing data may also facilitate harmonizing data across studies. Lastly, we expect that the generated sequencing data will support computational approaches for studying cancer evolution and the mechanisms underlying cancer treatments. Citation Format: Soner Koc, Mike Lloyd, Steven Neuhauser, Javad Noodbakhsh, Anuj Srivastava, Xing Yi Woo, Ryan Jeon, Jeffrey Grover, Sara Seepo, Christian Frech, Jack DiGiovanna, PDXNet Consortium, Yvonne A. Evard, Tiffany Wallace, Jeffrey Moscow, James H. Doroshow, Nicholas Mitsuade, Salma Kaochar, Chong-xian Pan, Moon S. Chen, Luis Carvarjal-Carmona, Alana Welm, Bryan Welm, Michael T. Lewis, Govindan Ramaswamy, Li Ding, Shunquang Li, Meenherd Herlyn, Mike Davies, Jack Roth, Funda Meric-Bernstam, Peter Robinson, Carol J. Bult, Brandi Davis-Dusenbery, Dennis A. Dean, Jeffrey H. Chuang. Advancing PDX research through model, data, and bioinformatics with the PDXNet Portal [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 3017.

Published

2021

12. Comparison of functional metacarpal splint and ulnar gutter splint in the treatment of fifth metacarpal neck fractures: a prospective comparative study

Author

Gokhan Kaynak, Huseyin Botanlioglu, Mustafa Caliskan, Bedri Karaismailoglu, Mahmut Kursat Ozsahin, Soner Kocak, Enis Yildirim, Onder Aydingoz, and Mehmet Fatih Guven

Subjects

Fifth metacarpal neck fracture, Metacarpal functional splint, Ulnar gutter splint, Grip strength, Metacarpal shortening, Angulation, Diseases of the musculoskeletal system, RC925-935

Abstract

Abstract Background Fifth metacarpal fractures are the most common fractures of the hand. These fractures are generally treated with conservative methods. The aim of this study was to compare the radiological and clinical outcomes of two conservative treatment methods, functional metacarpal splint(FMS) and ulnar gutter splint(UGS), for the treatment of fifth metacarpal neck fractures. Methods A prospective comparative study was designed to assess the conservative treatment of isolated and closed stable fractures of the fifth metacarpal neck. In total, 58 patients were included in the study and were treated with FMS or UGS after fracture reduction in a consecutive order. Angulation, shortening and functional outcome (QuickDASH scores and grip strengths) were evaluated at the 2nd and 6th months. Results Forty patients returned for follow-up. Twenty-two patients were treated with FMS, and 18 patients were treated with UGS. The average age was 28 years (SD ± 12, range;18–43) in the FMS group and 30 years (SD ± 14, range;18–58) in the UGS group. After reduction, significant correction was achieved in both groups, but the average angulation was lower in the FMS group(16 ± 7) compared with the UGS group (21 ± 8)(p = 0.043). However, this better initial reduction in FMS group(16 ± 7) could not be maintained in the 1st month follow-up (21 ± 5) (p = 0.009). In the FMS group, the improvement in QuickDASH scores between the 2nd and 6th month follow-up was significant (p = 0.003) but not in the UGS group(p = 0.075). When the expected grip strengths were calculated, the FMS group reached the expected strength values at the 2nd month follow-up, whereas the UGS group still exhibited significantly lower grip strength at the 2nd month follow-up(p = 0.008). However, at the end of the 6th month follow-up, both groups exhibited similar reduction, QuickDASH and grip strength values. Conclusions In stable 5th metacarpal neck fractures, FMS is adequate to prevent loss of reduction and yields faster improvement in clinical scores with earlier gain of normal grip strength compared with UGS. However, in the long term, both FMS and UGS methods yield similar radiological and clinical outcomes. Patient comfort and compliance may be better with FMS due to less joint restriction, and these findings should be considered when deciding the treatment method. Trial registration ISRCTN79534571 The date of registration: 01/04/2019 Type of study/level of evidence: Therapeutic, II.

Published

2019