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14 results on '"Nanis, Max"'

1. The Cure: Design and Evaluation of a Crowdsourcing Game for Gene Selection for Breast Cancer Survival Prediction

Author

Good, Benjamin M, Loguercio, Salvatore, Griffith, Obi L, Nanis, Max, Wu, Chunlei, and Su, Andrew I

Subjects
Information technology, T58.5-58.64, Public aspects of medicine, RA1-1270
Abstract

BackgroundMolecular signatures for predicting breast cancer prognosis could greatly improve care through personalization of treatment. Computational analyses of genome-wide expression datasets have identified such signatures, but these signatures leave much to be desired in terms of accuracy, reproducibility, and biological interpretability. Methods that take advantage of structured prior knowledge (eg, protein interaction networks) show promise in helping to define better signatures, but most knowledge remains unstructured. Crowdsourcing via scientific discovery games is an emerging methodology that has the potential to tap into human intelligence at scales and in modes unheard of before. ObjectiveThe main objective of this study was to test the hypothesis that knowledge linking expression patterns of specific genes to breast cancer outcomes could be captured from players of an open, Web-based game. We envisioned capturing knowledge both from the player’s prior experience and from their ability to interpret text related to candidate genes presented to them in the context of the game. MethodsWe developed and evaluated an online game called The Cure that captured information from players regarding genes for use as predictors of breast cancer survival. Information gathered from game play was aggregated using a voting approach, and used to create rankings of genes. The top genes from these rankings were evaluated using annotation enrichment analysis, comparison to prior predictor gene sets, and by using them to train and test machine learning systems for predicting 10 year survival. ResultsBetween its launch in September 2012 and September 2013, The Cure attracted more than 1000 registered players, who collectively played nearly 10,000 games. Gene sets assembled through aggregation of the collected data showed significant enrichment for genes known to be related to key concepts such as cancer, disease progression, and recurrence. In terms of the predictive accuracy of models trained using this information, these gene sets provided comparable performance to gene sets generated using other methods, including those used in commercial tests. The Cure is available on the Internet. ConclusionsThe principal contribution of this work is to show that crowdsourcing games can be developed as a means to address problems involving domain knowledge. While most prior work on scientific discovery games and crowdsourcing in general takes as a premise that contributors have little or no expertise, here we demonstrated a crowdsourcing system that succeeded in capturing expert knowledge.

Published
2014
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2. Microtask crowdsourcing for disease mention annotation in PubMed abstracts

Author

Good, Benjamin M, Nanis, Max, and Su, Andrew I.

Subjects
Computer Science - Computation and Language, 9208, H.5.3, I.2.7
Abstract

Identifying concepts and relationships in biomedical text enables knowledge to be applied in computational analyses. Many biological natural language process (BioNLP) projects attempt to address this challenge, but the state of the art in BioNLP still leaves much room for improvement. Progress in BioNLP research depends on large, annotated corpora for evaluating information extraction systems and training machine learning models. Traditionally, such corpora are created by small numbers of expert annotators often working over extended periods of time. Recent studies have shown that workers on microtask crowdsourcing platforms such as Amazon's Mechanical Turk (AMT) can, in aggregate, generate high-quality annotations of biomedical text. Here, we investigated the use of the AMT in capturing disease mentions in PubMed abstracts. We used the NCBI Disease corpus as a gold standard for refining and benchmarking our crowdsourcing protocol. After several iterations, we arrived at a protocol that reproduced the annotations of the 593 documents in the training set of this gold standard with an overall F measure of 0.872 (precision 0.862, recall 0.883). The output can also be tuned to optimize for precision (max = 0.984 when recall = 0.269) or recall (max = 0.980 when precision = 0.436). Each document was examined by 15 workers, and their annotations were merged based on a simple voting method. In total 145 workers combined to complete all 593 documents in the span of 1 week at a cost of $.06 per abstract per worker. The quality of the annotations, as judged with the F measure, increases with the number of workers assigned to each task such that the system can be tuned to balance cost against quality. These results demonstrate that microtask crowdsourcing can be a valuable tool for generating well-annotated corpora in BioNLP., Comment: Preprint of an article submitted for consideration in the Pacific Symposium on Biocomputing copyright 2015; World Scientific Publishing Co., Singapore, 2015; http://psb.stanford.edu/. Data produced for this analysis are available at http://figshare.com/articles/Disease_Mention_Annotation_with_Mechanical_Turk/1126402

Published
2014

3. Applying Citizen Science to Gene, Drug, Disease Relationship Extraction from Biomedical Abstracts

Author

Tsueng, Ginger, Nanis, Max, Fouquier, Jennifer T., Mayers, Michael, Good, Benjamin M., and Su, Andrew I

Subjects
0303 health sciences, Process (engineering), Computer science, computer.software_genre, Data science, Relationship extraction, Task (project management), 03 medical and health sciences, Information extraction, 0302 clinical medicine, Named-entity recognition, Citizen science, Drug-disease, 030212 general & internal medicine, computer, 030304 developmental biology
Abstract

Biomedical literature is growing at a rate that outpaces our ability to harness the knowledge contained therein. In order to mine valuable inferences from the large volume of literature, many researchers have turned to information extraction algorithms to harvest information in biomedical texts. Information extraction is usually accomplished via a combination of manual expert curation and computational methods. Advances in computational methods usually depends on the generation of gold standards by a limited number of expert curators. This process can be time consuming and represents an area of biomedical research that is ripe for exploration with citizen science. Citizen scientists have been previously found to be willing and capable of performing named entity recognition of disease mentions in biomedical abstracts, but it was uncertain whether or not the same could be said of relationship extraction. Relationship extraction requires training on identifying named entities as well as a deeper understanding of how different entity types can relate to one another. Here, we used the web-based application Mark2Cure (https://mark2cure.org) to demonstrate that citizen scientists can perform relationship extraction and confirm the importance of accurate named entity recognition on this task. We also discuss opportunities for future improvement of this system, as well as the potential synergies between citizen science, manual biocuration, and natural language processing.

Published
2019

4. Mark2Cure Relationship Extraction AKBC poster

Author

Tsueng, Ginger, Nanis, Max, Fouquier, Jennifer, Mayers, Michael, Good, Benjamin, and Su, Andrew

Subjects
ComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATION, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING
Abstract

Poster for a paper on relationship extraction by citizen scientists accepted to AKBC2019. Paper preprint available on biorxiv (see reference). Data and code can be found in the preprint.

Published
2019
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7. Applying citizen science to gene, drug and disease relationship extraction from biomedical abstracts.

Author

Tsueng, Ginger, Nanis, Max, Fouquier, Jennifer T, Mayers, Michael, Good, Benjamin M, and Su, Andrew I

Subjects
*INTERNET servers, *CITIZEN science, *DATA mining, *NATURAL language processing, *WEB-based user interfaces, *SOURCE code
Abstract

Motivation Biomedical literature is growing at a rate that outpaces our ability to harness the knowledge contained therein. To mine valuable inferences from the large volume of literature, many researchers use information extraction algorithms to harvest information in biomedical texts. Information extraction is usually accomplished via a combination of manual expert curation and computational methods. Advances in computational methods usually depend on the time-consuming generation of gold standards by a limited number of expert curators. Citizen science is public participation in scientific research. We previously found that citizen scientists are willing and capable of performing named entity recognition of disease mentions in biomedical abstracts, but did not know if this was true with relationship extraction (RE). Results In this article, we introduce the Relationship Extraction Module of the web-based application Mark2Cure (M2C) and demonstrate that citizen scientists can perform RE. We confirm the importance of accurate named entity recognition on user performance of RE and identify design issues that impacted data quality. We find that the data generated by citizen scientists can be used to identify relationship types not currently available in the M2C Relationship Extraction Module. We compare the citizen science-generated data with algorithm-mined data and identify ways in which the two approaches may complement one another. We also discuss opportunities for future improvement of this system, as well as the potential synergies between citizen science, manual biocuration and natural language processing. Availability and implementation Mark2Cure platform: https://mark2cure.org ; Mark2Cure source code: https://github.com/sulab/mark2cure ; and data and analysis code for this article: https://github.com/gtsueng/M2C%5frel%5fnb. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published
2020
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8. The Cure: Making a game of gene selection for breast cancer survival prediction

Author

Good, Benjamin M., Loguercio, Salvatore, Griffith, Obi L., Nanis, Max, Wu, Chunlei, and Su, Andrew I.

Subjects
Genomics (q-bio.GN), ComputingMethodologies_PATTERNRECOGNITION, FOS: Biological sciences, Quantitative Biology - Genomics, Quantitative Biology - Quantitative Methods, Quantitative Methods (q-bio.QM)
Abstract

Motivation: Molecular signatures for predicting breast cancer prognosis could greatly improve care through personalization of treatment. Computational analyses of genome-wide expression datasets have identified such signatures, but these signatures leave much to be desired in terms of accuracy, reproducibility and biological interpretability. Methods that take advantage of structured prior knowledge (e.g. protein interaction networks) show promise in helping to define better signatures but most knowledge remains unstructured. Crowdsourcing via scientific discovery games is an emerging methodology that has the potential to tap into human intelligence at scales and in modes previously unheard of. Here, we developed and evaluated a game called The Cure on the task of gene selection for breast cancer survival prediction. Our central hypothesis was that knowledge linking expression patterns of specific genes to breast cancer outcomes could be captured from game players. We envisioned capturing knowledge both from the players prior experience and from their ability to interpret text related to candidate genes presented to them in the context of the game. Results: Between its launch in Sept. 2012 and Sept. 2013, The Cure attracted more than 1,000 registered players who collectively played nearly 10,000 games. Gene sets assembled through aggregation of the collected data clearly demonstrated the accumulation of relevant expert knowledge. In terms of predictive accuracy, these gene sets provided comparable performance to gene sets generated using other methods including those used in commercial tests. The Cure is available at http://genegames.org/cure/

Published
2014
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9. RASLseqTools: open-source methods for designing and analyzing RNA-mediated oligonucleotide Annealing, Selection, and, Ligation sequencing (RASL-seq) experiments

Author

Scott, Erick R., primary, Larman, H. Benjamin, additional, Torkamani, Ali, additional, Schork, Nicholas J., additional, Wineinger, Nathan, additional, Nanis, Max, additional, Thompson, Ryan C., additional, Beheshti Zavareh, Reza B., additional, Lairson, Luke L., additional, Schultz, Peter G., additional, and Su, Andrew I., additional

Published
2016
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13. Socialbots

Author

Hwang, Tim, primary, Pearce, Ian, additional, and Nanis, Max, additional

Published
2012
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14. Microtask crowdsourcing for disease mention annotation in PubMed abstracts.

Author

Good BM, Nanis M, Wu C, and Su AI

Subjects
Abstracting and Indexing, Adult, Benchmarking, Computational Biology economics, Costs and Cost Analysis, Crowdsourcing economics, Data Curation economics, Data Curation methods, Disease, Female, Humans, Male, Middle Aged, Natural Language Processing, Supervised Machine Learning, Unified Medical Language System, Young Adult, Computational Biology methods, Crowdsourcing methods, PubMed
Abstract

Identifying concepts and relationships in biomedical text enables knowledge to be applied in computational analyses. Many biological natural language processing (BioNLP) projects attempt to address this challenge, but the state of the art still leaves much room for improvement. Progress in BioNLP research depends on large, annotated corpora for evaluating information extraction systems and training machine learning models. Traditionally, such corpora are created by small numbers of expert annotators often working over extended periods of time. Recent studies have shown that workers on microtask crowdsourcing platforms such as Amazon's Mechanical Turk (AMT) can, in aggregate, generate high-quality annotations of biomedical text. Here, we investigated the use of the AMT in capturing disease mentions in PubMed abstracts. We used the NCBI Disease corpus as a gold standard for refining and benchmarking our crowdsourcing protocol. After several iterations, we arrived at a protocol that reproduced the annotations of the 593 documents in the 'training set' of this gold standard with an overall F measure of 0.872 (precision 0.862, recall 0.883). The output can also be tuned to optimize for precision (max = 0.984 when recall = 0.269) or recall (max = 0.980 when precision = 0.436). Each document was completed by 15 workers, and their annotations were merged based on a simple voting method. In total 145 workers combined to complete all 593 documents in the span of 9 days at a cost of $.066 per abstract per worker. The quality of the annotations, as judged with the F measure, increases with the number of workers assigned to each task; however minimal performance gains were observed beyond 8 workers per task. These results add further evidence that microtask crowdsourcing can be a valuable tool for generating well-annotated corpora in BioNLP. Data produced for this analysis are available at http://figshare.com/articles/Disease_Mention_Annotation_with_Mechanical_Turk/1126402.

Published
2015

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