The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies

Amy Mizen; Daniel A. Thompson; Alan Watkins; Ashley Akbari; Joanne K. Garrett; Rebecca Geary; Rebecca Lovell; Ronan A. Lyons; Mark Nieuwenhuijsen; Sarah C. Parker; Francis M. Rowney; Jiao Song; Gareth Stratton; Benedict W. Wheeler; James White; Mathew P. White; Sue Williams; Sarah E. Rodgers; Richard Fry

doi:10.1038/s41370-024-00650-5

The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies

Amy Mizen (Corresponding author), Daniel A. Thompson, Alan Watkins, Ashley Akbari, Joanne K. Garrett, Rebecca Geary, Rebecca Lovell, Ronan A. Lyons, Mark Nieuwenhuijsen, Sarah C. Parker, Francis M. Rowney, Jiao Song, Gareth Stratton, Benedict W. Wheeler, James White, Mathew P. White, Sue Williams, Sarah E. Rodgers, Richard Fry

Vienna Cognitive Science Hub

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Background: Exposure to green space can protect against poor health through a variety of mechanisms. However, there is heterogeneity in methodological approaches to exposure assessments which makes creating effective policy recommendations challenging. Objective: Critically evaluate the use of a satellite-derived exposure metric, the Enhanced Vegetation Index (EVI), for assessing access to different types of green space in epidemiological studies. Methods: We used Landsat 5–8 (30 m resolution) to calculate average EVI for a 300 m radius surrounding 1.4 million households in Wales, UK for 2018. We calculated two additional measures using topographic vector data to represent access to green spaces within 300 m of household locations. The two topographic vector-based measures were total green space area stratified by type and average private garden size. We used linear regression models to test whether EVI could discriminate between publicly accessible and private green space and Pearson correlation to test associations between EVI and green space types. Results: Mean EVI for a 300 m radius surrounding households in Wales was 0.28 (IQR = 0.12). Total green space area and average private garden size were significantly positively associated with corresponding EVI measures (β = < 0.0001, 95% CI: 0.0000, 0.0000; β = 0.0001, 95% CI: 0.0001, 0.0001 respectively). In urban areas, as average garden size increases by 1 m2, EVI increases by 0.0002. Therefore, in urban areas, to see a 0.1 unit increase in EVI index score, garden size would need to increase by 500 m2. The very small β values represent no ‘measurable real-world’ associations. When stratified by type, we observed no strong associations between greenspace and EVI. Impact: It is a widely implemented assumption in epidiological studies that an increase in EVI is equivalent to an increase in greenness and/or green space. We used linear regression models to test associations between EVI and potential sources of green reflectance at a neighbourhood level using satellite imagery from 2018. We compared EVI measures with a ‘gold standard’ vector-based dataset that defines publicly accessible and private green spaces. We found that EVI should be interpreted with care as a greater EVI score does not necessarily mean greater access to publicly available green spaces in the hyperlocal environment.

Original language	English
Pages (from-to)	753-760
Number of pages	8
Journal	Journal of Exposure Science and Environmental Epidemiology
Volume	34
Issue number	5
Early online date	29 Feb 2024
DOIs	https://doi.org/10.1038/s41370-024-00650-5
Publication status	Published - Sept 2024

Austrian Fields of Science 2012

501002 Applied psychology

Keywords

Enhanced Vegetation Index (EVI), Exposure assessment
Epidemiological studies
Residential greenness

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1038/s41370-024-00650-5

Cite this

Mizen, A., Thompson, D. A., Watkins, A., Akbari, A., Garrett, J. K., Geary, R., Lovell, R., Lyons, R. A., Nieuwenhuijsen, M., Parker, S. C., Rowney, F. M., Song, J., Stratton, G., Wheeler, B. W., White, J., White, M. P., Williams, S., Rodgers, S. E., & Fry, R. (2024). The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies. Journal of Exposure Science and Environmental Epidemiology, 34(5), 753-760. https://doi.org/10.1038/s41370-024-00650-5

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title = "The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies",

abstract = "Background: Exposure to green space can protect against poor health through a variety of mechanisms. However, there is heterogeneity in methodological approaches to exposure assessments which makes creating effective policy recommendations challenging. Objective: Critically evaluate the use of a satellite-derived exposure metric, the Enhanced Vegetation Index (EVI), for assessing access to different types of green space in epidemiological studies. Methods: We used Landsat 5–8 (30 m resolution) to calculate average EVI for a 300 m radius surrounding 1.4 million households in Wales, UK for 2018. We calculated two additional measures using topographic vector data to represent access to green spaces within 300 m of household locations. The two topographic vector-based measures were total green space area stratified by type and average private garden size. We used linear regression models to test whether EVI could discriminate between publicly accessible and private green space and Pearson correlation to test associations between EVI and green space types. Results: Mean EVI for a 300 m radius surrounding households in Wales was 0.28 (IQR = 0.12). Total green space area and average private garden size were significantly positively associated with corresponding EVI measures (β = < 0.0001, 95% CI: 0.0000, 0.0000; β = 0.0001, 95% CI: 0.0001, 0.0001 respectively). In urban areas, as average garden size increases by 1 m2, EVI increases by 0.0002. Therefore, in urban areas, to see a 0.1 unit increase in EVI index score, garden size would need to increase by 500 m2. The very small β values represent no {\textquoteleft}measurable real-world{\textquoteright} associations. When stratified by type, we observed no strong associations between greenspace and EVI. Impact: It is a widely implemented assumption in epidiological studies that an increase in EVI is equivalent to an increase in greenness and/or green space. We used linear regression models to test associations between EVI and potential sources of green reflectance at a neighbourhood level using satellite imagery from 2018. We compared EVI measures with a {\textquoteleft}gold standard{\textquoteright} vector-based dataset that defines publicly accessible and private green spaces. We found that EVI should be interpreted with care as a greater EVI score does not necessarily mean greater access to publicly available green spaces in the hyperlocal environment.",

keywords = "Enhanced Vegetation Index (EVI), Exposure assessment, Epidemiological studies, Residential greenness",

author = "Amy Mizen and Thompson, {Daniel A.} and Alan Watkins and Ashley Akbari and Garrett, {Joanne K.} and Rebecca Geary and Rebecca Lovell and Lyons, {Ronan A.} and Mark Nieuwenhuijsen and Parker, {Sarah C.} and Rowney, {Francis M.} and Jiao Song and Gareth Stratton and Wheeler, {Benedict W.} and James White and White, {Mathew P.} and Sue Williams and Rodgers, {Sarah E.} and Richard Fry",

note = "Funding Information: This work was undertaken as part of independent research funded by the National Institute for Health Research (NIHR), project number 16/07/07. Time for SER to contribute to this project was funded by The National Institute for Health Research Applied Research Collaboration North West Coast (NIHR ARC NWC). The views expressed are those of the author(s) and not necessarily those of the NHS or the NIHR. This study was approved by the Secure Anonymised Information Linkage (SAIL) Information Governance Review Panel (project 0562) in Wales. All data were anonymised prior to access and analysis. This study makes use of anonymised data held in the Secure Anonymised Information Linkage (SAIL) Databank. We would like to acknowledge all the data providers who make anonymised data available for research. Funding Information: This research was conducted as part of independent research funded by the National Institute for Health Research (NIHR), project number 16/07/07. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR or the Department of Health and Social Care. Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = sep,

doi = "10.1038/s41370-024-00650-5",

language = "English",

volume = "34",

pages = "753--760",

journal = "Journal of Exposure Science and Environmental Epidemiology",

issn = "1559-0631",

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Mizen, A, Thompson, DA, Watkins, A, Akbari, A, Garrett, JK, Geary, R, Lovell, R, Lyons, RA, Nieuwenhuijsen, M, Parker, SC, Rowney, FM, Song, J, Stratton, G, Wheeler, BW, White, J, White, MP, Williams, S, Rodgers, SE & Fry, R 2024, 'The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies', Journal of Exposure Science and Environmental Epidemiology, vol. 34, no. 5, pp. 753-760. https://doi.org/10.1038/s41370-024-00650-5

TY - JOUR

T1 - The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies

AU - Mizen, Amy

AU - Thompson, Daniel A.

AU - Watkins, Alan

AU - Akbari, Ashley

AU - Garrett, Joanne K.

AU - Geary, Rebecca

AU - Lovell, Rebecca

AU - Lyons, Ronan A.

AU - Nieuwenhuijsen, Mark

AU - Parker, Sarah C.

AU - Rowney, Francis M.

AU - Song, Jiao

AU - Stratton, Gareth

AU - Wheeler, Benedict W.

AU - White, James

AU - White, Mathew P.

AU - Williams, Sue

AU - Rodgers, Sarah E.

AU - Fry, Richard

N1 - Funding Information: This work was undertaken as part of independent research funded by the National Institute for Health Research (NIHR), project number 16/07/07. Time for SER to contribute to this project was funded by The National Institute for Health Research Applied Research Collaboration North West Coast (NIHR ARC NWC). The views expressed are those of the author(s) and not necessarily those of the NHS or the NIHR. This study was approved by the Secure Anonymised Information Linkage (SAIL) Information Governance Review Panel (project 0562) in Wales. All data were anonymised prior to access and analysis. This study makes use of anonymised data held in the Secure Anonymised Information Linkage (SAIL) Databank. We would like to acknowledge all the data providers who make anonymised data available for research. Funding Information: This research was conducted as part of independent research funded by the National Institute for Health Research (NIHR), project number 16/07/07. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR or the Department of Health and Social Care. Publisher Copyright: © The Author(s) 2024.

PY - 2024/9

Y1 - 2024/9

N2 - Background: Exposure to green space can protect against poor health through a variety of mechanisms. However, there is heterogeneity in methodological approaches to exposure assessments which makes creating effective policy recommendations challenging. Objective: Critically evaluate the use of a satellite-derived exposure metric, the Enhanced Vegetation Index (EVI), for assessing access to different types of green space in epidemiological studies. Methods: We used Landsat 5–8 (30 m resolution) to calculate average EVI for a 300 m radius surrounding 1.4 million households in Wales, UK for 2018. We calculated two additional measures using topographic vector data to represent access to green spaces within 300 m of household locations. The two topographic vector-based measures were total green space area stratified by type and average private garden size. We used linear regression models to test whether EVI could discriminate between publicly accessible and private green space and Pearson correlation to test associations between EVI and green space types. Results: Mean EVI for a 300 m radius surrounding households in Wales was 0.28 (IQR = 0.12). Total green space area and average private garden size were significantly positively associated with corresponding EVI measures (β = < 0.0001, 95% CI: 0.0000, 0.0000; β = 0.0001, 95% CI: 0.0001, 0.0001 respectively). In urban areas, as average garden size increases by 1 m2, EVI increases by 0.0002. Therefore, in urban areas, to see a 0.1 unit increase in EVI index score, garden size would need to increase by 500 m2. The very small β values represent no ‘measurable real-world’ associations. When stratified by type, we observed no strong associations between greenspace and EVI. Impact: It is a widely implemented assumption in epidiological studies that an increase in EVI is equivalent to an increase in greenness and/or green space. We used linear regression models to test associations between EVI and potential sources of green reflectance at a neighbourhood level using satellite imagery from 2018. We compared EVI measures with a ‘gold standard’ vector-based dataset that defines publicly accessible and private green spaces. We found that EVI should be interpreted with care as a greater EVI score does not necessarily mean greater access to publicly available green spaces in the hyperlocal environment.

AB - Background: Exposure to green space can protect against poor health through a variety of mechanisms. However, there is heterogeneity in methodological approaches to exposure assessments which makes creating effective policy recommendations challenging. Objective: Critically evaluate the use of a satellite-derived exposure metric, the Enhanced Vegetation Index (EVI), for assessing access to different types of green space in epidemiological studies. Methods: We used Landsat 5–8 (30 m resolution) to calculate average EVI for a 300 m radius surrounding 1.4 million households in Wales, UK for 2018. We calculated two additional measures using topographic vector data to represent access to green spaces within 300 m of household locations. The two topographic vector-based measures were total green space area stratified by type and average private garden size. We used linear regression models to test whether EVI could discriminate between publicly accessible and private green space and Pearson correlation to test associations between EVI and green space types. Results: Mean EVI for a 300 m radius surrounding households in Wales was 0.28 (IQR = 0.12). Total green space area and average private garden size were significantly positively associated with corresponding EVI measures (β = < 0.0001, 95% CI: 0.0000, 0.0000; β = 0.0001, 95% CI: 0.0001, 0.0001 respectively). In urban areas, as average garden size increases by 1 m2, EVI increases by 0.0002. Therefore, in urban areas, to see a 0.1 unit increase in EVI index score, garden size would need to increase by 500 m2. The very small β values represent no ‘measurable real-world’ associations. When stratified by type, we observed no strong associations between greenspace and EVI. Impact: It is a widely implemented assumption in epidiological studies that an increase in EVI is equivalent to an increase in greenness and/or green space. We used linear regression models to test associations between EVI and potential sources of green reflectance at a neighbourhood level using satellite imagery from 2018. We compared EVI measures with a ‘gold standard’ vector-based dataset that defines publicly accessible and private green spaces. We found that EVI should be interpreted with care as a greater EVI score does not necessarily mean greater access to publicly available green spaces in the hyperlocal environment.

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KW - Residential greenness

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ER -

The use of Enhanced Vegetation Index for assessing access to different types of green space in epidemiological studies

Abstract

Austrian Fields of Science 2012

Keywords

UN SDGs

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