research-article

Understanding the Effects of the Neighbourhood Built Environment on Public Health with Open Data

Authors:

Apinan Hasthanasombat,

Cecilia MascoloAuthors Info & Claims

WWW '19: The World Wide Web Conference

Pages 648 - 658

https://doi.org/10.1145/3308558.3313701

Published: 13 May 2019 Publication History

Abstract

The investigation of the effect of the built environment in a neighbourhood and how it impacts residents' health is of value to researchers from public health policy to social science. The traditional methods to assess this impact is through surveys which lead to temporally and spatially coarse grained data and are often not cost effective. Here we propose an approach to link the effects of neighbourhood services over citizen health using a technique that attempts to highlight the cause-effect aspects of these relationships. The method is based on the theory of propensity score matching with multiple 'doses' and it leverages existing fine grained open web data. To demonstrate the method, we study the effect of sport venue presence on the prevalence of antidepressant prescriptions in over 600 neighbourhoods in London over a period of three years. We find the distribution of effects is approximately normal, centred on a small negative effect on prescriptions with increases in the availability of sporting facilities, on average. We assess the procedure through some standard quantitative metrics as well as matching on synthetic data generated by modelling the real data. This approach opens the door to fast and inexpensive alternatives to quantify and continuously monitor effects of the neighborhood built environment on population health.

References

[1]

2018. London Datastore. https://data.london.gov.uk/dataset/lsoa-atlas

[2]

Mariana C. Arcaya, Reginald D. Tucker-Seeley, Rockli Kim, Alina Schnake-Mahl, Marvin So, and S. V. Subramanian. 2016. Research on neighborhood effects on health in the United States: A systematic review of study characteristics. Social Science & Medicine 168 (Nov. 2016), 16-29.

[3]

Jo Barton, Rachel Bragg, Carly Wood, and Jules Pretty. 2016. Green exercise: Linking nature, health and well-being. Routledge.

[4]

Alexandra Blair, Nancy A. Ross, Geneviève Gariepy, and Norbert Schmitz. 2014. How do neighborhoods affect depression outcomes? A realist review and a call for the examination of causal pathways. Social Psychiatry and Psychiatric Epidemiology 49, 6 (June 2014), 873-887.

[5]

Emile Durkheim. 2005. Suicide: A study in sociology. Routledge.

[6]

Jack Edmonds. 1965. Maximum matching and a polyhedron with 0, 1-vertices. Journal of Research of the National Bureau of Standards B 69 (1965), 125-130.

[7]

Open Street Map Foundation. 2018. Map Features - OpenStreetMap Wiki. https://wiki.openstreetmap.org/wiki/Map_Features#Route

[8]

Panagis Galiatsatos, Cynthia Kineza, Seungyoun Hwang, Juliana Pietri, Emily Brigham, Nirupama Putcha, Cynthia S. Rand, Meredith McCormack, and Nadia N. Hansel. 2018. Neighbourhood characteristics and health outcomes: evaluating the association between socioeconomic status, tobacco store density and health outcomes in Baltimore City. Tobacco Control 27, e1 (July 2018), e19-e24.

[9]

Xing Sam Gu and Paul R. Rosenbaum. 1993. Comparison of Multivariate Matching Methods: Structures, Distances, and Algorithms. Journal of Computational and Graphical Statistics 2, 4 (1993), 405-420.

[10]

Desislava Hristova, Matthew J. Williams, Mirco Musolesi, Pietro Panzarasa, and Cecilia Mascolo. 2016. Measuring Urban Social Diversity Using Interconnected Geo-Social Networks. In Proceedings of the 25th International Conference on World Wide Web - WWW '16. ACM Press, Montréal, Québec, Canada, 21-30.

Digital Library

[11]

Marshall M. Joffe and Paul R. Rosenbaum. 1999. Invited Commentary: Propensity Scores. American Journal of Epidemiology 150, 4 (Aug. 1999), 327-333.

[12]

Markus Jokela. 2014. Are Neighborhood Health Associations Causal? A 10-Year Prospective Cohort Study With Repeated Measurements. American Journal of Epidemiology 180, 8 (Oct. 2014), 776-784.

[13]

Harold W Kuhn. 1956. Variants of the Hungarian method for assignment problems. Naval Research Logistics Quarterly 3, 4 (1956), 253-258.

[14]

Sheng Li, Nikos Vlassis, Jaya Kawale, and Yun Fu. 2016. Matching via Dimensionality Reduction for Estimation of Treatment Effects in Digital Marketing Campaigns. In IJCAI. 3768-3774.

Digital Library

[15]

Bruce G. Link and Jo Phelan. 1995. Social Conditions As Fundamental Causes of Disease. Journal of Health and Social Behavior(1995), 80-94.

[16]

Bo Lu, Elaine Zanutto, Robert Hornik, and Paul R. Rosenbaum. 2001. Matching with doses in an observational study of a media campaign against drug abuse. J. Amer. Statist. Assoc. 96, 456 (2001), 1245-1253.

[17]

Jens Ludwig, Greg J. Duncan, Lisa A. Gennetian, Lawrence F. Katz, Ronald C. Kessler, Jeffrey R. Kling, and Lisa Sanbonmatsu. 2012. Neighborhood Effects on the Long-Term Well-Being of Low-Income Adults. Science 337, 6101 (Sept. 2012), 1505-1510.

[18]

C. Mair, A. V. Diez Roux, and S. Galea. 2008. Are neighbourhood characteristics associated with depressive symptoms? A review of evidence. Journal of Epidemiology & Community Health 62, 11 (Nov. 2008), 940-946.

[19]

Kate E. Mason, Neil Pearce, and Steven Cummins. 2018. Associations between fast food and physical activity environments and adiposity in mid-life: cross-sectional, observational evidence from UK Biobank. The Lancet Public Health 3, 1 (Jan. 2018), e24-e33.

[20]

Peter McCullagh. 1980. Regression Models for Ordinal Data. Journal of the Royal Statistical Society. Series B (Methodological) 42, 2(1980), 109-142. http://www.jstor.org/stable/2984952

[21]

J. Michael Oakes. 2004. The (mis)estimation of neighborhood effects: causal inference for a practicable social epidemiology. Social Science & Medicine 58, 10 (May 2004), 1929-1952.

[22]

J. Michael Oakes, Kate E. Andrade, Ifrah M. Biyoow, and Logan T. Cowan. 2015. Twenty Years of Neighborhood Effect Research: An Assessment. Current Epidemiology Reports 2, 1 (March 2015), 80-87.

[23]

OSM. 2018. Key:sport - OpenStreetMap Wiki. https://wiki.openstreetmap.org/wiki/Key:sport

[24]

Michael J Paul and Mark Dredze. 2011. You Are What You Tweet: Analyzing Twitter for Public Health. (2011), 8.

[25]

Judea Pearl. 2009. Causality. Cambridge University Press. Google-Books-ID: f4nuexsNVZIC.

[26]

Jonas Peters, Dominik Janzing, and Bernhard Schölkopf. 2017. Elements of Causal Inference: Foundations and Learning Algorithms. MIT Press. Google-Books-ID: uie9AQAACAAJ.

Digital Library

[27]

Jo C. Phelan, Bruce G. Link, Ana Diez-Roux, Ichiro Kawachi, and Bruce Levin. 2004. ”Fundamental causes” of social inequalities in mortality: a test of the theory. Journal of Health and Social Behavior 45, 3 (Sept. 2004), 265-285.

[28]

Paul R. Rosenbaum and Donald B. Rubin. 1983. The central role of the propensity score in observational studies for causal effects. Biometrika 70, 1 (April 1983), 41-55.

[29]

Andrew G. Rundle, Michael D. M. Bader, Catherine A. Richards, Kathryn M. Neckerman, and Julien O. Teitler. 2011. Using Google Street View to Audit Neighborhood Environments. American Journal of Preventive Medicine 40, 1 (Jan. 2011), 94-100.

[30]

Chris Smith-Clarke and Licia Capra. 2016. Beyond the Baseline: Establishing the Value in Mobile Phone Based Poverty Estimates. In Proceedings of the 25th International Conference on World Wide Web(WWW '16). International World Wide Web Conferences Steering Committee, Republic and Canton of Geneva, Switzerland, 425-434.

Digital Library

[31]

United Nations Social and Economic Affairs Division. 2018. World Urbanization Prospects.

[32]

Wei Sun, Pengyuan Wang, Dawei Yin, Jian Yang, and Yi Chang. 2015. Causal Inference via Sparse Additive Models with Application to Online Advertising. In Proceedings of the Twenty-Ninth AAAI Conference on Artificial Intelligence(AAAI'15). AAAI Press, Austin, Texas, 297-303. http://dl.acm.org/citation.cfm?id=2887007.2887049

Digital Library

[33]

Fani Tsapeli, Mirco Musolesi, and Peter Tino. 2017. Non-parametric causality detection: An application to social media and financial data. Physica A: Statistical Mechanics and its Applications 483 (Oct. 2017), 139-155.

[34]

May C. Wang, Soowon Kim, Alma A. Gonzalez, Kara E. MacLeod, and Marilyn A. Winkleby. 2007. Socioeconomic and food-related physical characteristics of the neighbourhood environment are associated with body mass index. Journal of Epidemiology and Community Health 61, 6 (June 2007), 491-498.

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cover image ACM Other conferences

WWW '19: The World Wide Web Conference

May 2019

3620 pages

ISBN:9781450366748

DOI:10.1145/3308558

Editors:
Ling Liu
Georgia Tech, USA
,
Ryen White
Microsoft Research, USA

Copyright © 2019 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

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IW3C2: International World Wide Web Conference Committee

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Publication History

Published: 13 May 2019

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WWW '19

WWW '19: The Web Conference

May 13 - 17, 2019

CA, San Francisco, USA

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Cited By

Wang JChen LLycett DVernon DZheng D(2024)Toward Population Health Intelligence: When Artificial Intelligence Meets Population Health ResearchComputer10.1109/MC.2023.328385757:6(62-72)Online publication date: 3-Jun-2024
https://dl.acm.org/doi/10.1109/MC.2023.3283857
Liu CFan CMostafavi A(2024)Graph attention networks unveil determinants of intra- and inter-city health disparityUrban Informatics10.1007/s44212-024-00049-53:1Online publication date: 22-May-2024
https://doi.org/10.1007/s44212-024-00049-5
Chen JWang HFan ZSong X(2024)How to Be a Well-Prepared Organizer: Studying the Causal Effects of City Events on Human MobilityAI, Data, and Digitalization10.1007/978-3-031-53770-7_4(42-64)Online publication date: 14-Mar-2024
https://doi.org/10.1007/978-3-031-53770-7_4
Vallapuram AKwon YLee LXu FHui P(2022)Causal Analysis on the Anchor Store Effect in a Location-based Social Network2022 IEEE/ACM International Conference on Advances in Social Networks Analysis and Mining (ASONAM)10.1109/ASONAM55673.2022.10068687(202-209)Online publication date: 10-Nov-2022
https://doi.org/10.1109/ASONAM55673.2022.10068687
Zhang YXu FXia TLi Y(2021)Quantifying the Causal Effect of Individual Mobility on Health Status in Urban SpaceProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/34949905:4(1-30)Online publication date: 30-Dec-2021
https://dl.acm.org/doi/10.1145/3494990

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