Yu Deng scite author profile

This article reviews recent advances in applying natural language processing (NLP) to Electronic Health Records (EHRs) for computational phenotyping. NLP-based computational phenotyping has numerous applications including diagnosis categorization, novel phenotype discovery, clinical trial screening, pharmacogenomics, drug-drug interaction (DDI) and adverse drug event (ADE) detection, as well as genome-wide and phenome-wide association studies. Significant progress has been made in algorithm development and resource construction for computational phenotyping. Among the surveyed methods, well-designed keyword search and rule-based systems often achieve good performance. However, the construction of keyword and rule lists requires significant manual effort, which is difficult to scale. Supervised machine learning models have been favored because they are capable of acquiring both classification patterns and structures from data. Recently, deep learning and unsupervised learning have received growing attention, with the former favored for its performance and the latter for its ability to find novel phenotypes. Integrating heterogeneous data sources have become increasingly important and have shown promise in improving model performance. Often better performance is achieved by combining multiple modalities of information. Despite these many advances, challenges and opportunities remain for NLP-based computational phenotyping, including better model interpretability and generalizability, and proper characterization of feature relations in clinical narratives.

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Deep Learning in Human Activity Recognition with Wearable Sensors: A Review on Advances

Zhang

et al. 2022

Sensors

162

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Mobile and wearable devices have enabled numerous applications, including activity tracking, wellness monitoring, and human–computer interaction, that measure and improve our daily lives. Many of these applications are made possible by leveraging the rich collection of low-power sensors found in many mobile and wearable devices to perform human activity recognition (HAR). Recently, deep learning has greatly pushed the boundaries of HAR on mobile and wearable devices. This paper systematically categorizes and summarizes existing work that introduces deep learning methods for wearables-based HAR and provides a comprehensive analysis of the current advancements, developing trends, and major challenges. We also present cutting-edge frontiers and future directions for deep learning-based HAR.

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RDF Aggregate Queries and Views

Hung

Deng

Subrahmanian

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Rethinking pre-training on medical imaging

Wen

Chen

Deng

et al. 2021

Journal of Visual Communication and Image Representation

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Dynamic Faceted Search for Technical Support Exploiting Induced Knowledge

Mihindukulasooriya

Mahindru

Chowdhury

et al. 2020

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A Technical Question Answering System with Transfer Learning

Yu¹,

Wu²,

Deng³

et al. 2020

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In recent years, the need for community technical question-answering sites has increased significantly. However, it is often expensive for human experts to provide timely and helpful responses on those forums. We develop TransTQA, which is a novel system that offers automatic responses by retrieving proper answers based on correctly answered similar questions in the past. TransTQA is built upon a siamese ALBERT network, which enables it to respond quickly and accurately. Furthermore, TransTQA adopts a standard deep transfer learning strategy to improve its capability of supporting multiple technical domains.

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A deep learning-based approach to automatic proximal femur segmentation in quantitative CT images

Deng

Zhao

Tang

et al. 2022

Med Biol Eng Comput

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Probabilistic Ontologies and Relational Databases

Udrea

Deng

Hung

et al. 2005

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Yu Deng

Natural Language Processing for EHR-Based Computational Phenotyping

Deep Learning in Human Activity Recognition with Wearable Sensors: A Review on Advances

RDF Aggregate Queries and Views

Rethinking pre-training on medical imaging

Dynamic Faceted Search for Technical Support Exploiting Induced Knowledge

A Technical Question Answering System with Transfer Learning

A deep learning-based approach to automatic proximal femur segmentation in quantitative CT images

Probabilistic Ontologies and Relational Databases

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