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Identifying Smoking Environments From Images of Daily Life With Deep Learning
IMPORTANCE: Environments associated with smoking increase a smoker’s craving to smoke and may provoke lapses during a quit attempt. Identifying smoking risk environments from images of a smoker’s daily life provides a basis for environment-based interventions. OBJECTIVE: To apply a deep learning app...
Autores principales: | , , , , , , |
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Formato: | Online Artículo Texto |
Lenguaje: | English |
Publicado: |
American Medical Association
2019
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Materias: | |
Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6681554/ https://www.ncbi.nlm.nih.gov/pubmed/31373647 http://dx.doi.org/10.1001/jamanetworkopen.2019.7939 |
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author | Engelhard, Matthew M. Oliver, Jason A. Henao, Ricardo Hallyburton, Matt Carin, Lawrence E. Conklin, Cynthia McClernon, F. Joseph |
author_facet | Engelhard, Matthew M. Oliver, Jason A. Henao, Ricardo Hallyburton, Matt Carin, Lawrence E. Conklin, Cynthia McClernon, F. Joseph |
author_sort | Engelhard, Matthew M. |
collection | PubMed |
description | IMPORTANCE: Environments associated with smoking increase a smoker’s craving to smoke and may provoke lapses during a quit attempt. Identifying smoking risk environments from images of a smoker’s daily life provides a basis for environment-based interventions. OBJECTIVE: To apply a deep learning approach to the clinically relevant identification of smoking environments among settings that smokers encounter in daily life. DESIGN, SETTING, AND PARTICIPANTS: In this cross-sectional study, 4902 images of smoking (n = 2457) and nonsmoking (n = 2445) locations were photographed by 169 smokers from Durham, North Carolina, and Pittsburgh, Pennsylvania, areas from 2010 to 2016. These images were used to develop a probabilistic classifier to predict the location type (smoking or nonsmoking location), thus relating objects and settings in daily environments to established smoking patterns. The classifier combines a deep convolutional neural network with an interpretable logistic regression model and was trained and evaluated via nested cross-validation with participant-wise partitions (ie, out-of-sample prediction). To contextualize model performance, images taken by 25 randomly selected participants were also classified by smoking cessation experts. As secondary validation, craving levels reported by participants when viewing unfamiliar environments were compared with the model’s predictions. Data analysis was performed from September 2017 to May 2018. MAIN OUTCOMES AND MEASURES: Classifier performance (accuracy and area under the receiver operating characteristic curve [AUC]), comparison with 4 smoking cessation experts, contribution of objects and settings to smoking environment status (standardized model coefficients), and correlation with participant-reported craving. RESULTS: Of 169 participants, 106 (62.7%) were from Durham (53 [50.0%] female; mean [SD] age, 41.4 [12.0] years) and 63 (37.3%) were from Pittsburgh (31 [51.7%] female; mean [SD] age, 35.2 [13.8] years). A total of 4902 images were available for analysis, including 3386 from Durham (mean [SD], 31.9 [1.3] images per participant) and 1516 from Pittsburgh (mean [SD], 24.1 [0.5] images per participant). Images were evenly split between the 2 classes, with 2457 smoking images (50.1%) and 2445 nonsmoking images (49.9%). The final model discriminated smoking vs nonsmoking environments with a mean (SD) AUC of 0.840 (0.024) (accuracy [SD], 76.5% [1.6%]). A model trained only with images from Durham participants effectively classified images from Pittsburgh participants (AUC, 0.757; accuracy, 69.2%), and a model trained only with images from Pittsburgh participants effectively classified images from Durham participants (AUC, 0.821; accuracy, 75.0%), suggesting good generalizability between geographic areas. Only 1 expert’s performance was a statistically significant improvement compared with the classifier (α = .05). Median self-reported craving was significantly correlated with model-predicted smoking environment status (ρ = 0.894; P = .003). CONCLUSIONS AND RELEVANCE: In this study, features of daily environments predicted smoking vs nonsmoking status consistently across participants. The findings suggest that a deep learning approach can identify environments associated with smoking, can predict the probability that any image of daily life represents a smoking environment, and can potentially trigger environment-based interventions. This work demonstrates a framework for predicting how daily environments may influence target behaviors or symptoms that may have broad applications in mental and physical health. |
format | Online Article Text |
id | pubmed-6681554 |
institution | National Center for Biotechnology Information |
language | English |
publishDate | 2019 |
publisher | American Medical Association |
record_format | MEDLINE/PubMed |
spelling | pubmed-66815542019-08-16 Identifying Smoking Environments From Images of Daily Life With Deep Learning Engelhard, Matthew M. Oliver, Jason A. Henao, Ricardo Hallyburton, Matt Carin, Lawrence E. Conklin, Cynthia McClernon, F. Joseph JAMA Netw Open Original Investigation IMPORTANCE: Environments associated with smoking increase a smoker’s craving to smoke and may provoke lapses during a quit attempt. Identifying smoking risk environments from images of a smoker’s daily life provides a basis for environment-based interventions. OBJECTIVE: To apply a deep learning approach to the clinically relevant identification of smoking environments among settings that smokers encounter in daily life. DESIGN, SETTING, AND PARTICIPANTS: In this cross-sectional study, 4902 images of smoking (n = 2457) and nonsmoking (n = 2445) locations were photographed by 169 smokers from Durham, North Carolina, and Pittsburgh, Pennsylvania, areas from 2010 to 2016. These images were used to develop a probabilistic classifier to predict the location type (smoking or nonsmoking location), thus relating objects and settings in daily environments to established smoking patterns. The classifier combines a deep convolutional neural network with an interpretable logistic regression model and was trained and evaluated via nested cross-validation with participant-wise partitions (ie, out-of-sample prediction). To contextualize model performance, images taken by 25 randomly selected participants were also classified by smoking cessation experts. As secondary validation, craving levels reported by participants when viewing unfamiliar environments were compared with the model’s predictions. Data analysis was performed from September 2017 to May 2018. MAIN OUTCOMES AND MEASURES: Classifier performance (accuracy and area under the receiver operating characteristic curve [AUC]), comparison with 4 smoking cessation experts, contribution of objects and settings to smoking environment status (standardized model coefficients), and correlation with participant-reported craving. RESULTS: Of 169 participants, 106 (62.7%) were from Durham (53 [50.0%] female; mean [SD] age, 41.4 [12.0] years) and 63 (37.3%) were from Pittsburgh (31 [51.7%] female; mean [SD] age, 35.2 [13.8] years). A total of 4902 images were available for analysis, including 3386 from Durham (mean [SD], 31.9 [1.3] images per participant) and 1516 from Pittsburgh (mean [SD], 24.1 [0.5] images per participant). Images were evenly split between the 2 classes, with 2457 smoking images (50.1%) and 2445 nonsmoking images (49.9%). The final model discriminated smoking vs nonsmoking environments with a mean (SD) AUC of 0.840 (0.024) (accuracy [SD], 76.5% [1.6%]). A model trained only with images from Durham participants effectively classified images from Pittsburgh participants (AUC, 0.757; accuracy, 69.2%), and a model trained only with images from Pittsburgh participants effectively classified images from Durham participants (AUC, 0.821; accuracy, 75.0%), suggesting good generalizability between geographic areas. Only 1 expert’s performance was a statistically significant improvement compared with the classifier (α = .05). Median self-reported craving was significantly correlated with model-predicted smoking environment status (ρ = 0.894; P = .003). CONCLUSIONS AND RELEVANCE: In this study, features of daily environments predicted smoking vs nonsmoking status consistently across participants. The findings suggest that a deep learning approach can identify environments associated with smoking, can predict the probability that any image of daily life represents a smoking environment, and can potentially trigger environment-based interventions. This work demonstrates a framework for predicting how daily environments may influence target behaviors or symptoms that may have broad applications in mental and physical health. American Medical Association 2019-08-02 /pmc/articles/PMC6681554/ /pubmed/31373647 http://dx.doi.org/10.1001/jamanetworkopen.2019.7939 Text en Copyright 2019 Engelhard MM et al. JAMA Network Open. http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the terms of the CC-BY License. |
spellingShingle | Original Investigation Engelhard, Matthew M. Oliver, Jason A. Henao, Ricardo Hallyburton, Matt Carin, Lawrence E. Conklin, Cynthia McClernon, F. Joseph Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title | Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title_full | Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title_fullStr | Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title_full_unstemmed | Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title_short | Identifying Smoking Environments From Images of Daily Life With Deep Learning |
title_sort | identifying smoking environments from images of daily life with deep learning |
topic | Original Investigation |
url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6681554/ https://www.ncbi.nlm.nih.gov/pubmed/31373647 http://dx.doi.org/10.1001/jamanetworkopen.2019.7939 |
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