Deep Learning to Unveil Correlations between Urban Landscape and Population Health †

The global healthcare landscape is continuously changing throughout the world as technology advances, leading to a gradual change in lifestyle. Several diseases such as asthma and cardiovascular conditions are becoming more diffuse, due to a rise in pollution exposure and a more sedentary lifestyle. Healthcare providers deal with increasing new challenges, and thanks to fast-developing big data technologies, they can be faced with systems that provide direct support to citizens. In this context, within the EU-funded Participatory Urban Living for Sustainable Environments (PULSE) project, we are implementing a data analytic platform designed to provide public health decision makers with advanced approaches, to jointly analyze maps and geospatial information with healthcare and air pollution data. In this paper we describe a component of such platforms, which couples deep learning analysis of urban geospatial images with healthcare indexes collected by the 500 Cities project. By applying a pre-learned deep Neural Network architecture, satellite images of New York City are analyzed and latent feature variables are extracted. These features are used to derive clusters, which are correlated with healthcare indicators by means of a multivariate classification model. Thanks to this pipeline, it is possible to show that, in New York City, health care indexes are significantly correlated to the urban landscape. This pipeline can serve as a basis to ease urban planning, since the same interventions can be organized on similar areas, even if geographically distant.

[1]  Katharina Heinke Schlünzen,et al.  How Does the Urban Environment Affect Health and Well-Being? A Systematic Review , 2018 .

[2]  Thommen George Karimpanal,et al.  Self-organizing maps for storage and transfer of knowledge in reinforcement learning , 2018, Adapt. Behav..

[3]  M. McHugh Interrater reliability: the kappa statistic , 2012, Biochemia medica.

[4]  Dimitrios I. Fotiadis,et al.  Machine learning applications in cancer prognosis and prediction , 2014, Computational and structural biotechnology journal.

[5]  Yao Yao,et al.  Using deep learning to examine street view green and blue spaces and their associations with geriatric depression in Beijing, China , 2019, Environment international.

[6]  Mahmude Özkale,et al.  Wiley StatsRef: Statistics Reference Online , 2016 .

[7]  A. Litonjua,et al.  Race, socioeconomic factors, and area of residence are associated with asthma prevalence , 1999, Pediatric pulmonology.

[8]  C. Borrell,et al.  Mortality and socioeconomic deprivation in census tracts of an urban setting in Southern Europe , 2005, Journal of Urban Health.

[9]  Xiaoling Xia,et al.  Inception-v3 for flower classification , 2017, 2017 2nd International Conference on Image, Vision and Computing (ICIVC).

[10]  Ole Winther,et al.  DeepLoc: prediction of protein subcellular localization using deep learning , 2017, Bioinform..

[11]  N. Krieger A Century of Census Tracts: Health & the Body Politic (1906–2006) , 2006, Journal of Urban Health.

[12]  Riccardo Bellazzi,et al.  Spatial Enablement to Support Environmental, Demographic, Socioeconomics, and Health Data Integration and Analysis for Big Cities: A Case Study With Asthma Hospitalizations in New York City , 2019, Front. Med..

[13]  Xin Pan,et al.  An object-based convolutional neural network (OCNN) for urban land use classification , 2018, Remote Sensing of Environment.

[14]  Pedro H. O. Pinheiro,et al.  Extending the spatial scale of land use regression models for ambient ultrafine particles using satellite images and deep convolutional neural networks. , 2019, Environmental research.

[15]  Itai Kloog,et al.  Long- and Short-Term Exposure to PM2.5 and Mortality: Using Novel Exposure Models , 2013, Epidemiology.

[16]  G. Ferilli,et al.  Cities, the Urban Green Environment, and Individual Subjective Well-Being: The Case of Milan, Italy , 2015 .

[17]  Chirag J. Patel,et al.  Analytic Complexity and Challenges in Identifying Mixtures of Exposures Associated with Phenotypes in the Exposome Era , 2017, Current Epidemiology Reports.

[18]  Aleksander Madry,et al.  Exploring the Landscape of Spatial Robustness , 2017, ICML.

[19]  C. Anandan,et al.  Is the prevalence of asthma declining? Systematic review of epidemiological studies , 2010, Allergy.

[20]  Matthew Doude,et al.  Semantic Segmentation with Transfer Learning for Off-Road Autonomous Driving , 2019, Sensors.

[21]  Huimin Yan,et al.  A Deep Convolution Neural Network Method for Land Cover Mapping: A Case Study of Qinhuangdao, China , 2018, Remote. Sens..

[22]  J. Balmes,et al.  Outdoor air pollution and asthma , 2014, The Lancet.

[23]  Lara P. Clark,et al.  Changes in Transportation-Related Air Pollution Exposures by Race-Ethnicity and Socioeconomic Status: Outdoor Nitrogen Dioxide in the United States in 2000 and 2010 , 2017, Environmental health perspectives.

[24]  George Grekousis,et al.  Artificial neural networks and deep learning in urban geography: A systematic review and meta-analysis , 2019, Comput. Environ. Urban Syst..

[25]  Jörg Stückler,et al.  Semi-Supervised Deep Learning for Monocular Depth Map Prediction , 2017, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[26]  Junhao Wen,et al.  Fundus Image Classification Using VGG-19 Architecture with PCA and SVD , 2018, Symmetry.

[27]  Cristiana Larizza,et al.  Transfer Learning for Urban Landscape Clustering and Correlation with Health Indexes , 2019, ICOST.

[28]  Gebreab K Zewdie,et al.  Applying Deep Neural Networks and Ensemble Machine Learning Methods to Forecast Airborne Ambrosia Pollen , 2019, International journal of environmental research and public health.

[29]  Pravesh Kothari,et al.  An Analysis of the t-SNE Algorithm for Data Visualization , 2018, COLT.