Your search keyword '"Szolovits, Peter"' showing total 8 results

1. Medical subdomain classification of clinical notes using a machine learning-based natural language processing approach

Author

Wagholikar, Kavishwar B, McCray, Alexa T, Chueh, Henry C, Wagholikar, Kavishwar B., McCray, Alexa T., Chueh, Henry C., Weng, Wei-Hung, Szolovits, Peter, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Weng, Wei-Hung, and Szolovits, Peter

Subjects

020205 medical informatics, Computer science, Clinical Decision-Making, Health Informatics, 02 engineering and technology, Medical Decision Making, Computer-assisted, lcsh:Computer applications to medicine. Medical informatics, computer.software_genre, Machine learning, Medical Records, Machine Learning, 03 medical and health sciences, 0302 clinical medicine, Deep Learning, Classifier (linguistics), 0202 electrical engineering, electronic engineering, information engineering, Feature (machine learning), Distributed Representation, Humans, 030212 general & internal medicine, Interpretability, Natural Language Processing, business.industry, Health Policy, Deep learning, Supervised learning, Unified Medical Language System, Computer Science Applications, Support vector machine, Recurrent neural network, ComputingMethodologies_PATTERNRECOGNITION, lcsh:R858-859.7, Artificial intelligence, business, computer, Natural language processing, Research Article

Abstract

Background The medical subdomain of a clinical note, such as cardiology or neurology, is useful content-derived metadata for developing machine learning downstream applications. To classify the medical subdomain of a note accurately, we have constructed a machine learning-based natural language processing (NLP) pipeline and developed medical subdomain classifiers based on the content of the note. Methods We constructed the pipeline using the clinical NLP system, clinical Text Analysis and Knowledge Extraction System (cTAKES), the Unified Medical Language System (UMLS) Metathesaurus, Semantic Network, and learning algorithms to extract features from two datasets — clinical notes from Integrating Data for Analysis, Anonymization, and Sharing (iDASH) data repository (n = 431) and Massachusetts General Hospital (MGH) (n = 91,237), and built medical subdomain classifiers with different combinations of data representation methods and supervised learning algorithms. We evaluated the performance of classifiers and their portability across the two datasets. Results The convolutional recurrent neural network with neural word embeddings trained-medical subdomain classifier yielded the best performance measurement on iDASH and MGH datasets with area under receiver operating characteristic curve (AUC) of 0.975 and 0.991, and F1 scores of 0.845 and 0.870, respectively. Considering better clinical interpretability, linear support vector machine-trained medical subdomain classifier using hybrid bag-of-words and clinically relevant UMLS concepts as the feature representation, with term frequency-inverse document frequency (tf-idf)-weighting, outperformed other shallow learning classifiers on iDASH and MGH datasets with AUC of 0.957 and 0.964, and F1 scores of 0.932 and 0.934 respectively. We trained classifiers on one dataset, applied to the other dataset and yielded the threshold of F1 score of 0.7 in classifiers for half of the medical subdomains we studied. Conclusion Our study shows that a supervised learning-based NLP approach is useful to develop medical subdomain classifiers. The deep learning algorithm with distributed word representation yields better performance yet shallow learning algorithms with the word and concept representation achieves comparable performance with better clinical interpretability. Portable classifiers may also be used across datasets from different institutions. Keywords: Medical Decision Making; Computer-assisted; Natural Language Processing; Unified Medical Language System; Machine Learning; Deep Learning; Distributed Representation

Published

2017

2. Medical subdomain classification of clinical notes using a machine learning-based natural language processing approach

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Weng, Wei-Hung, Szolovits, Peter, Wagholikar, Kavishwar B, McCray, Alexa T, Chueh, Henry C, Wagholikar, Kavishwar B., McCray, Alexa T., Chueh, Henry C., Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Weng, Wei-Hung, Szolovits, Peter, Wagholikar, Kavishwar B, McCray, Alexa T, Chueh, Henry C, Wagholikar, Kavishwar B., McCray, Alexa T., and Chueh, Henry C.

Abstract

Background The medical subdomain of a clinical note, such as cardiology or neurology, is useful content-derived metadata for developing machine learning downstream applications. To classify the medical subdomain of a note accurately, we have constructed a machine learning-based natural language processing (NLP) pipeline and developed medical subdomain classifiers based on the content of the note. Methods We constructed the pipeline using the clinical NLP system, clinical Text Analysis and Knowledge Extraction System (cTAKES), the Unified Medical Language System (UMLS) Metathesaurus, Semantic Network, and learning algorithms to extract features from two datasets — clinical notes from Integrating Data for Analysis, Anonymization, and Sharing (iDASH) data repository (n = 431) and Massachusetts General Hospital (MGH) (n = 91,237), and built medical subdomain classifiers with different combinations of data representation methods and supervised learning algorithms. We evaluated the performance of classifiers and their portability across the two datasets. Results The convolutional recurrent neural network with neural word embeddings trained-medical subdomain classifier yielded the best performance measurement on iDASH and MGH datasets with area under receiver operating characteristic curve (AUC) of 0.975 and 0.991, and F1 scores of 0.845 and 0.870, respectively. Considering better clinical interpretability, linear support vector machine-trained medical subdomain classifier using hybrid bag-of-words and clinically relevant UMLS concepts as the feature representation, with term frequency-inverse document frequency (tf-idf)-weighting, outperformed other shallow learning classifiers on iDASH and MGH datasets with AUC of 0.957 and 0.964, and F1 scores of 0.932 and 0.934 respectively. We trained classifiers on one dataset, applied to the other dataset and yielded the threshold of F1 score of 0.7 in classifiers for half of the medical subdomains we studied. Conclusion Our study s

Published

2018

3. Medical subdomain classification of clinical notes using a machine learning-based natural language processing approach.

Author

Wei-Hung Weng, Wagholikar, Kavishwar B., McCray, Alexa T., Szolovits, Peter, Chueh, Henry C., and Weng, Wei-Hung

Subjects

NATURAL languages, MACHINE learning, THEORY of knowledge, NEUROLOGY, CARDIOLOGY

Abstract

Background: The medical subdomain of a clinical note, such as cardiology or neurology, is useful content-derived metadata for developing machine learning downstream applications. To classify the medical subdomain of a note accurately, we have constructed a machine learning-based natural language processing (NLP) pipeline and developed medical subdomain classifiers based on the content of the note.Methods: We constructed the pipeline using the clinical NLP system, clinical Text Analysis and Knowledge Extraction System (cTAKES), the Unified Medical Language System (UMLS) Metathesaurus, Semantic Network, and learning algorithms to extract features from two datasets - clinical notes from Integrating Data for Analysis, Anonymization, and Sharing (iDASH) data repository (n = 431) and Massachusetts General Hospital (MGH) (n = 91,237), and built medical subdomain classifiers with different combinations of data representation methods and supervised learning algorithms. We evaluated the performance of classifiers and their portability across the two datasets.Results: The convolutional recurrent neural network with neural word embeddings trained-medical subdomain classifier yielded the best performance measurement on iDASH and MGH datasets with area under receiver operating characteristic curve (AUC) of 0.975 and 0.991, and F1 scores of 0.845 and 0.870, respectively. Considering better clinical interpretability, linear support vector machine-trained medical subdomain classifier using hybrid bag-of-words and clinically relevant UMLS concepts as the feature representation, with term frequency-inverse document frequency (tf-idf)-weighting, outperformed other shallow learning classifiers on iDASH and MGH datasets with AUC of 0.957 and 0.964, and F1 scores of 0.932 and 0.934 respectively. We trained classifiers on one dataset, applied to the other dataset and yielded the threshold of F1 score of 0.7 in classifiers for half of the medical subdomains we studied.Conclusion: Our study shows that a supervised learning-based NLP approach is useful to develop medical subdomain classifiers. The deep learning algorithm with distributed word representation yields better performance yet shallow learning algorithms with the word and concept representation achieves comparable performance with better clinical interpretability. Portable classifiers may also be used across datasets from different institutions. [ABSTRACT FROM AUTHOR]

Published

2017

4. An international effort towards developing standards for best practices in analysis, interpretation and reporting of clinical genome sequencing results in the CLARITY Challenge.

Author

Brownstein, Catherine A., Beggs, Alan H., Homer, Nils, Merriman, Barry, Yu, Timothy W., Flannery, Katherine C., DeChene, Elizabeth T., Towne, Meghan C., Savage, Sarah K., Price, Emily N., Holm, Ingrid A., Luquette, Lovelace J., Lyon, Elaine, Majzoub, Joseph, Neupert, Peter, McCallie Jr., David, Szolovits, Peter, Willard, Huntington F., Mendelsohn, Nancy J., and Temme, Renee

Published

2014

5. An intelligent listening framework for capturing encounter notes from a doctor-patient dialog.

Author

Klann, Jeffrey G. and Szolovits, Peter

Subjects

*AUTOMATIC speech recognition, *DATA extraction, *PHYSICIAN-patient privilege, *DATA structures, *XML (Extensible Markup Language), *MICROPHONES

Abstract

Background: Capturing accurate and machine-interpretable primary data from clinical encounters is a challenging task, yet critical to the integrity of the practice of medicine. We explore the intriguing possibility that technology can help accurately capture structured data from the clinical encounter using a combination of automated speech recognition (ASR) systems and tools for extraction of clinical meaning from narrative medical text. Our goal is to produce a displayed evolving encounter note, visible and editable (using speech) during the encounter. Results: This is very ambitious, and so far we have taken only the most preliminary steps. We report a simple proof-of-concept system and the design of the more comprehensive one we are building, discussing both the engineering design and challenges encountered. Without a formal evaluation, we were encouraged by our initial results. The proof-of-concept, despite a few false positives, correctly recognized the proper category of single-and multi-word phrases in uncorrected ASR output. The more comprehensive system captures and transcribes speech and stores alternative phrase interpretations in an XML-based format used by a text-engineering framework. It does not yet use the framework to perform the language processing present in the proof-of-concept. Conclusion: The work here encouraged us that the goal is reachable, so we conclude with proposed next steps. Some challenging steps include acquiring a corpus of doctor-patient conversations, exploring a workable microphone setup, performing user interface research, and developing a multi-speaker version of our tools. [ABSTRACT FROM AUTHOR]

Published

2009

6. Automated de-identification of free-text medical records.

Author

Neamatullah, Ishna, Douglass, Margaret M., Lehman, Li-wei H., Reisner, Andrew, Villarroel, Mauricio, Long, William J., Szolovits, Peter, Moody, George B., Mark, Roger G., and Clifford, Gari D.

Subjects

MEDICAL records, MEDICAL informatics, PHYSICIAN-patient privilege, PERL (Computer program language), HEALTH Insurance Portability & Accountability Act

Abstract

Background: Text-based patient medical records are a vital resource in medical research. In order to preserve patient confidentiality, however, the U.S. Health Insurance Portability and Accountability Act (HIPAA) requires that protected health information (PHI) be removed from medical records before they can be disseminated. Manual de-identification of large medical record databases is prohibitively expensive, time-consuming and prone to error, necessitating automatic methods for large-scale, automated de-identification.Methods: We describe an automated Perl-based de-identification software package that is generally usable on most free-text medical records, e.g., nursing notes, discharge summaries, X-ray reports, etc. The software uses lexical look-up tables, regular expressions, and simple heuristics to locate both HIPAA PHI, and an extended PHI set that includes doctors' names and years of dates. To develop the de-identification approach, we assembled a gold standard corpus of re-identified nursing notes with real PHI replaced by realistic surrogate information. This corpus consists of 2,434 nursing notes containing 334,000 words and a total of 1,779 instances of PHI taken from 163 randomly selected patient records. This gold standard corpus was used to refine the algorithm and measure its sensitivity. To test the algorithm on data not used in its development, we constructed a second test corpus of 1,836 nursing notes containing 296,400 words. The algorithm's false negative rate was evaluated using this test corpus.Results: Performance evaluation of the de-identification software on the development corpus yielded an overall recall of 0.967, precision value of 0.749, and fallout value of approximately 0.002. On the test corpus, a total of 90 instances of false negatives were found, or 27 per 100,000 word count, with an estimated recall of 0.943. Only one full date and one age over 89 were missed. No patient names were missed in either corpus.Conclusion: We have developed a pattern-matching de-identification system based on dictionary look-ups, regular expressions, and heuristics. Evaluation based on two different sets of nursing notes collected from a U.S. hospital suggests that, in terms of recall, the software out-performs a single human de-identifier (0.81) and performs at least as well as a consensus of two human de-identifiers (0.94). The system is currently tuned to de-identify PHI in nursing notes and discharge summaries but is sufficiently generalized and can be customized to handle text files of any format. Although the accuracy of the algorithm is high, it is probably insufficient to be used to publicly disseminate medical data. The open-source de-identification software and the gold standard re-identified corpus of medical records have therefore been made available to researchers via the PhysioNet website to encourage improvements in the algorithm. [ABSTRACT FROM AUTHOR]

Published

2008

7. An international effort towards developing standards for best practices in analysis, interpretation and reporting of clinical genome sequencing results in the CLARITY Challenge

Author

Brownstein, Catherine A, Beggs, Alan H, Homer, Nils, Merriman, Barry, Yu, Timothy W, Flannery, Katherine C, DeChene, Elizabeth T, Towne, Meghan C, Savage, Sarah K, Price, Emily N, Holm, Ingrid A, Luquette, Lovelace J, Lyon, Elaine, Majzoub, Joseph, Neupert, Peter, McCallie Jr, David, Szolovits, Peter, Willard, Huntington F, Mendelsohn, Nancy J, Temme, Renee, Finkel, Richard S, Yum, Sabrina W, Medne, Livija, Sunyaev, Shamil R, Adzhubey, Ivan, Cassa, Christopher A, de Bakker, Paul IW, Duzkale, Hatice, Dworzyński, Piotr, Fairbrother, William, Francioli, Laurent, Funke, Birgit H, Giovanni, Monica A, Handsaker, Robert E, Lage, Kasper, Lebo, Matthew S, Lek, Monkol, Leshchiner, Ignaty, MacArthur, Daniel G, McLaughlin, Heather M, Murray, Michael F, Pers, Tune H, Polak, Paz P, Raychaudhuri, Soumya, Rehm, Heidi L, Soemedi, Rachel, Stitziel, Nathan O, Vestecka, Sara, Supper, Jochen, Gugenmus, Claudia, Klocke, Bernward, Hahn, Alexander, Schubach, Max, Menzel, Mortiz, Biskup, Saskia, Freisinger, Peter, Deng, Mario, Braun, Martin, Perner, Sven, Smith, Richard JH, Andorf, Janeen L, Huang, Jian, Ryckman, Kelli, Sheffield, Val C, Stone, Edwin M, Bair, Thomas, Black-Ziegelbein, E Ann, Braun, Terry A, Darbro, Benjamin, DeLuca, Adam P, Kolbe, Diana L, Scheetz, Todd E, Shearer, Aiden E, Sompallae, Rama, Wang, Kai, Bassuk, Alexander G, Edens, Erik, Mathews, Katherine, Moore, Steven A, Shchelochkov, Oleg A, Trapane, Pamela, Bossler, Aaron, Campbell, Colleen A, Heusel, Jonathan W, Kwitek, Anne, Maga, Tara, Panzer, Karin, Wassink, Thomas, Van Daele, Douglas, Azaiez, Hela, Booth, Kevin, Meyer, Nic, Segal, Michael M, Williams, Marc S, Tromp, Gerard, White, Peter, Corsmeier, Donald, Fitzgerald-Butt, Sara, Herman, Gail, Lamb-Thrush, Devon, McBride, Kim L, Newsom, David, Pierson, Christopher R, Rakowsky, Alexander T, Maver, Aleš, Lovrečić, Luca, Palandačić, Anja, Peterlin, Borut, Torkamani, Ali, Wedell, Anna, Huss, Mikael, Alexeyenko, Andrey, Lindvall, Jessica M, Magnusson, Måns, Nilsson, Daniel, Stranneheim, Henrik, Taylan, Fulya, Gilissen, Christian, Hoischen, Alexander, van Bon, Bregje, Yntema, Helger, Nelen, Marcel, Zhang, Weidong, Sager, Jason, Zhang, Lu, Blair, Kathryn, Kural, Deniz, Cariaso, Michael, Lennon, Greg G, Javed, Asif, Agrawal, Saloni, Ng, Pauline C, Sandhu, Komal S, Krishna, Shuba, Veeramachaneni, Vamsi, Isakov, Ofer, Halperin, Eran, Friedman, Eitan, Shomron, Noam, Glusman, Gustavo, Roach, Jared C, Caballero, Juan, Cox, Hannah C, Mauldin, Denise, Ament, Seth A, Rowen, Lee, Richards, Daniel R, Lucas, F Anthony San, Gonzalez-Garay, Manuel L, Caskey, C Thomas, Bai, Yu, Huang, Ying, Fang, Fang, Zhang, Yan, Wang, Zhengyuan, Barrera, Jorge, Garcia-Lobo, Juan M, González-Lamuño, Domingo, Llorca, Javier, Rodriguez, Maria C, Varela, Ignacio, Reese, Martin G, De La Vega, Francisco M, Kiruluta, Edward, Cargill, Michele, Hart, Reece K, Sorenson, Jon M, Lyon, Gholson J, Stevenson, David A, Bray, Bruce E, Moore, Barry M, Eilbeck, Karen, Yandell, Mark, Zhao, Hongyu, Hou, Lin, Chen, Xiaowei, Yan, Xiting, Chen, Mengjie, Li, Cong, Yang, Can, Gunel, Murat, Li, Peining, Kong, Yong, Alexander, Austin C, Albertyn, Zayed I, Boycott, Kym M, Bulman, Dennis E, Gordon, Paul MK, Innes, A Micheil, Knoppers, Bartha M, Majewski, Jacek, Marshall, Christian R, Parboosingh, Jillian S, Sawyer, Sarah L, Samuels, Mark E, Schwartzentruber, Jeremy, Kohane, Isaac S, and Margulies, David M

Abstract

Background: There is tremendous potential for genome sequencing to improve clinical diagnosis and care once it becomes routinely accessible, but this will require formalizing research methods into clinical best practices in the areas of sequence data generation, analysis, interpretation and reporting. The CLARITY Challenge was designed to spur convergence in methods for diagnosing genetic disease starting from clinical case history and genome sequencing data. DNA samples were obtained from three families with heritable genetic disorders and genomic sequence data were donated by sequencing platform vendors. The challenge was to analyze and interpret these data with the goals of identifying disease-causing variants and reporting the findings in a clinically useful format. Participating contestant groups were solicited broadly, and an independent panel of judges evaluated their performance. Results: A total of 30 international groups were engaged. The entries reveal a general convergence of practices on most elements of the analysis and interpretation process. However, even given this commonality of approach, only two groups identified the consensus candidate variants in all disease cases, demonstrating a need for consistent fine-tuning of the generally accepted methods. There was greater diversity of the final clinical report content and in the patient consenting process, demonstrating that these areas require additional exploration and standardization. Conclusions: The CLARITY Challenge provides a comprehensive assessment of current practices for using genome sequencing to diagnose and report genetic diseases. There is remarkable convergence in bioinformatic techniques, but medical interpretation and reporting are areas that require further development by many groups.

Published

2014

8. Medical subdomain classification of clinical notes using a machine learning-based natural language processing approach.

Author

Weng WH, Wagholikar KB, McCray AT, Szolovits P, and Chueh HC

Subjects

Humans, Clinical Decision-Making, Machine Learning, Medical Records, Natural Language Processing, Unified Medical Language System

Abstract

Background: The medical subdomain of a clinical note, such as cardiology or neurology, is useful content-derived metadata for developing machine learning downstream applications. To classify the medical subdomain of a note accurately, we have constructed a machine learning-based natural language processing (NLP) pipeline and developed medical subdomain classifiers based on the content of the note., Methods: We constructed the pipeline using the clinical NLP system, clinical Text Analysis and Knowledge Extraction System (cTAKES), the Unified Medical Language System (UMLS) Metathesaurus, Semantic Network, and learning algorithms to extract features from two datasets - clinical notes from Integrating Data for Analysis, Anonymization, and Sharing (iDASH) data repository (n = 431) and Massachusetts General Hospital (MGH) (n = 91,237), and built medical subdomain classifiers with different combinations of data representation methods and supervised learning algorithms. We evaluated the performance of classifiers and their portability across the two datasets., Results: The convolutional recurrent neural network with neural word embeddings trained-medical subdomain classifier yielded the best performance measurement on iDASH and MGH datasets with area under receiver operating characteristic curve (AUC) of 0.975 and 0.991, and F1 scores of 0.845 and 0.870, respectively. Considering better clinical interpretability, linear support vector machine-trained medical subdomain classifier using hybrid bag-of-words and clinically relevant UMLS concepts as the feature representation, with term frequency-inverse document frequency (tf-idf)-weighting, outperformed other shallow learning classifiers on iDASH and MGH datasets with AUC of 0.957 and 0.964, and F1 scores of 0.932 and 0.934 respectively. We trained classifiers on one dataset, applied to the other dataset and yielded the threshold of F1 score of 0.7 in classifiers for half of the medical subdomains we studied., Conclusion: Our study shows that a supervised learning-based NLP approach is useful to develop medical subdomain classifiers. The deep learning algorithm with distributed word representation yields better performance yet shallow learning algorithms with the word and concept representation achieves comparable performance with better clinical interpretability. Portable classifiers may also be used across datasets from different institutions.

Published

2017