Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-23T20:33:11.415Z Has data issue: false hasContentIssue false

Exposure to green spaces and schizophrenia: a systematic review

Published online by Cambridge University Press:  09 September 2024

Louise Marcham
Affiliation:
School of Psychology, University of Southampton, Southampton, UK
Lyn Ellett*
Affiliation:
School of Psychology, University of Southampton, Southampton, UK
*
Corresponding author: Lyn Ellett; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The mental health benefits of exposure to green spaces are well known. This systematic review summarizes the evidence of green space exposure for people with schizophrenia spectrum disorders (SSDs), focusing on incidence and mental health outcomes, including mental health symptoms and health service use. The study was pre-registered (PROSPERO ID: CRD42023431954), and conducted according to PRISMA guidelines. Seven databases, reference lists, and gray literature sources were searched. Methodological quality was assessed using The Quality Assessment Tool for Quantitative Studies. 126 studies were screened, and 12 studies were eligible for inclusion. Seven studies found that exposure to green space was associated with a reduced risk of schizophrenia (lowest to highest green space exposure: HRs = 0.62–0.37; IRRs = 1.52–1.18), with five studies reporting a dose-response relationship. Of these studies, four examined childhood exposure and the remainder examined adult exposure. Regarding health service use, proximity to green space was not significantly associated with length of hospital admission, though greater green space exposure was associated with reduced hospital admission rates. Three studies found reduced symptoms of anxiety (d = −0.70–2.42), depression (d = −0.97–1.70) and psychosis (d = −0.94) with greater green space exposure. Exposure to green space reduces the risk of schizophrenia, and there is emerging evidence of the potential benefits of green space for reducing symptoms and health service use among people with SSDs. Future research using experimental and longitudinal designs will provide more robust evidence of the benefits of green space for people with SSDs.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

There is a growing body of research exploring the relationship between exposure to green space and mental health benefits. In addition, organizations have advocated for the development and protection of green spaces, with the aim of improving population health and wellbeing (Department for Levelling Up, Housing and Communities, 2023; Public Health England; PHE, 2020; World Health Organisation; WHO, 2017). Green spaces can be defined as areas of grass, shrubs, trees, or other vegetation, situated within or adjacent to an urban area (PHE, 2020), and have also been defined by their composition or use, such as nature reserves, parks, forests, and gardens (Taylor & Hochuli, Reference Taylor and Hochuli2017). Exposure to green space generally refers to how often individuals have contact with, or access to, these environments, but can also include single interventions (WHO, 2016). With a growing trend towards urbanization (United Nations, 2018), there is a need to establish the role of green spaces in conferring mental health benefits, to support the continued integration and maintenance of these areas within urban settings (Barton & Rogerson, Reference Barton and Rogerson2017; Houlden, Weich, Porto de Albuquerque, Jarvis, & Rees, Reference Houlden, Weich, Porto de Albuquerque, Jarvis and Rees2018) and to establish their (potential) therapeutic benefits.

Existing reviews have primarily focused on the benefits of green space in terms of common mental health problems and symptomology. Research has shown that exposure to green spaces is associated with a wide range of mental health benefits (Alcock, White, Wheeler, Fleming, & Depledge, Reference Alcock, White, Wheeler, Fleming and Depledge2014; Tran, Sabol, & Mote, Reference Tran, Sabol and Mote2022; Van den Berg, Maas, Verheij, & Groenewegen, Reference Van den Berg, Maas, Verheij and Groenewegen2010; Wendelboe-Nelson, Kelly, Kennedy, & Cherrie, Reference Wendelboe-Nelson, Kelly, Kennedy and Cherrie2019), including improvements in mood and reduced levels of stress and mental fatigue (Bowler, Buyung-Ali, Knight, & Pullin, Reference Bowler, Buyung-Ali, Knight and Pullin2010; Gascon et al., Reference Gascon, Triguero-Mas, Martínez, Dadvand, Forns, Plasència and Nieuwenhuijsen2015; Houlden et al., Reference Houlden, Weich, Porto de Albuquerque, Jarvis and Rees2018), effects which have been found across the lifespan (Dzhambov, Reference Dzhambov2018; Fjaestad et al., Reference Fjaestad, Mackelprang, Sugiyama, Chandrabose, Owen, Turrell and Kingsley2023; McCormick, Reference McCormick2017; Pun, Manjourides, & Suh, Reference Pun, Manjourides and Suh2018). Greater exposure to green spaces has been associated with a reduced risk of developing depression (Brown et al., Reference Brown, Perrino, Lombard, Wang, Toro, Rundek and Szapocznik2018; Min, Kim, Kim, & Min, Reference Min, Kim, Kim and Min2017; Sarkar, Webster, & Gallacher, Reference Sarkar, Webster and Gallacher2018) and anxiety disorders (Gascon et al., Reference Gascon, Sánchez-Benavides, Dadvand, Martínez, Gramunt, Gotsens and Nieuwenhuijsen2018), and has been found to reduce symptoms related to anxiety and depression, suggesting potential protective effects for improving mental health (Pun et al., Reference Pun, Manjourides and Suh2018). Studies have therefore advocated for the use of green space as an intervention for public mental health (Maas, Verheij, Groenewegen, de Vries, & Spreeuwenberg, Reference Maas, Verheij, Groenewegen, de Vries and Spreeuwenberg2006; Soga, Evans, Tsuchiya, & Fukano, Reference Soga, Evans, Tsuchiya and Fukano2021).

Exposure to green space could be an effective intervention for managing mental health difficulties. Engaging in activities such as gardening, have resulted in overall improved mental wellbeing and reduction in social isolation (Howarth, Brettle, Hardman, & Maden, Reference Howarth, Brettle, Hardman and Maden2020). For example, accessing horticultural programs has been associated with improvements for stress-related mental illness and burnout (Adevi & Lieberg, Reference Adevi and Lieberg2012; Sahlin, Ahlborg, Tenenbaum, & Grahn, Reference Sahlin, Ahlborg, Tenenbaum and Grahn2015). A systematic review of gardening as a mental health intervention found overall reduced symptoms of anxiety and depression for a clinical population (Clatworthy, Hinds, & Camic, Reference Clatworthy, Hinds and Camic2013). Additionally, therapeutic applications of green space have been found to reduce symptoms of clinical depression (Berman et al., Reference Berman, Kross, Krpan, Askren, Burson, Deldin and Jonides2012; Gonzalez, Hartig, Patil, Martinsen, & Kirkevold, Reference Gonzalez, Hartig, Patil, Martinsen and Kirkevold2010). Other reviews have found that nature walks were associated with a reduction in symptoms of anxiety and depression for clinical and nonclinical populations (Kotera, Lyons, Vione, & Norton, Reference Kotera, Lyons, Vione and Norton2021) and, as an intervention for anxiety and depression, resulted in mental health improvements (Grassini, Reference Grassini2022). Access to activities within green spaces have also been found to reduce stress in psychiatric inpatient populations (Vujcic et al., Reference Vujcic, Tomicevic-Dubljevic, Grbic, Lecic-Tosevski, Vukovic and Toskovic2017) and have the potential to reduce mental health admissions (Wheater et al., Reference Wheater, Potts, Shaw, Perkins, Smith, Casstles and Bellis2007).

However, there is a lack of synthesis of research exploring the effects of green space for people with diagnoses of severe mental health conditions, such as schizophrenia spectrum disorders (SSDs) (Tran et al., Reference Tran, Sabol and Mote2022). Therefore, the aim of this review is to identify and synthesize the evidence of the association of green space and mental health outcomes for people with SSDs. Green space interventions are promising due to their relatively low cost and accessibility (Bowen & Lynch, Reference Bowen and Lynch2017; Bowen & Parry, Reference Bowen and Parry2015), with the potential to incur cost savings for the NHS (Wheater et al., Reference Wheater, Potts, Shaw, Perkins, Smith, Casstles and Bellis2007). Any identified benefits of green space could provide a rationale for preventative strategies, alongside integrating aspects of green spaces into therapeutic interventions and mental health services for this population. This review will include quantitative studies that explore the relationship between green space and SSDs and will address the following research questions:

  1. 1. What is the association between exposure to green space and the incidence of SSDs?

  2. 2. What are the benefits of exposure to green space for individuals with SSDs in relation to: (a) health service use, and (b) mental health symptoms?

Method

This systematic review was pre-registered on PROSPERO (available at https://www.crd.york.ac.uk/PROSPERO/, ID: CRD42023431954) and conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA; Page et al., Reference Page, Mckenzie, Bossuyt, Boutron, Hoffmann, Mulrow and Moher2021). Databases were initially searched in July 2023, and an updated search was conducted in November 2023 (with no new papers identified). A PRISMA checklist is included as supplementary material.

Inclusion and exclusion criteria

Inclusion criteria were: (1) articles of any date, published in English, with findings available; (2) involving exposure to green spaces, with green spaces defined as areas of vegetation (e.g. trees, grass, shrubs), adjacent to or within urban and rural areas, such as parks, gardens, forests, and nature reserves; (3) sample population of people with SSDs; (4) participants of any age (children to older adults); (5) quantitative studies (i.e. cross-sectional, cohort, experimental, correlational, longitudinal) reporting on either the relationship between exposure to green space(s) and SSDs or the benefits of green spaces for SSDs in relation to health service use and/or mental health symptoms; (6) outcomes of interest included reported risk of SSDs, health service use e.g., admission rates, and symptoms of SSDs and other related mental health outcomes e.g., anxiety, depression, etc.

Exclusion criteria were: (1) qualitative studies; (2) studies that did not include exposure to green space; (3) dissertations or theses; (4) existing reviews.

Search strategy and sources of information

Seven electronic databases were searched, including PubMed (including MEDLINE), Web of Science, PsycARTICLES, APA, PsycINFO, CINAHL, ProQuest, and gray literature sources (EThOS, PsyArXiv, Open Science Framework). The following search terms were adopted: Psychosis OR psychoses OR psychotic OR schiz* OR paranoi* OR delusion* OR hallucinat* AND ‘Green space*’ OR ‘nature contact’ OR ‘urban nature’ OR ‘urban green’ OR ‘nature exposure’ OR ‘nature-based’ OR ‘nature experience’ OR ‘nature sound*’ OR ‘green area*’ OR greenspace* OR ‘natural space*’ OR ‘nature view*’

Screening process

Articles were initially identified by screening the title, abstract and subject or keywords, followed by full text screening. A second independent rater assessed 20% of all papers identified for full text screening using the outlined eligibility criteria. The search strategy and screening process are shown in Fig. 1.

Figure 1. PRISMA flowchart.

Quality assessment

The included studies were assessed for methodological quality using The Quality Assessment Tool for Quantitative Studies (Effective Public Health Practice Project; EPHPP, 2023). The EPHPP tool provides an overall rating of study methodology using the categories: ‘strong’, ‘moderate’ or ‘weak’, based on individual ratings for eight categories: study design, analysis, withdrawals and dropouts, data collection, selection bias, invention integrity, blinding as part of controlled trials, and confounders. Studies with two or more individual weak ratings are rated as weak overall. Studies with no weak ratings are rated as strong overall. This tool was used due to its ability to assess articles with a variety of quantitative study designs within the public health domain (Thomas, Ciliska, Dobbins, & Micucci, Reference Thomas, Ciliska, Dobbins and Micucci2004). All of the included studies were rated independently by the first author and an independent rater, and there were no discrepancies in overall study quality ratings.

Data extraction and synthesis

The main characteristics of each study and the study population were extracted, alongside data pertaining to the two research questions. A narrative synthesis approach was used, due to heterogeneity in study design, measurement of green space and reported outcomes. Only data relating to SSDs and green spaces were extracted and included in the analysis. Studies were grouped for synthesis according to the research questions they addressed.

Results

The titles and abstracts of 126 records were screened; 54 records were extracted for full-text evaluation (including one paper from gray literature). Ten studies were eligible for inclusion. An additional two papers were found via searching the reference lists of eligible papers. Therefore, twelve papers were included in the final review (see Table 1 for a summary of study characteristics).

Table 1. Summary of studies and quality analysis

a Size of greenspace area and edge.

b Connectedness of greenspaces within a location.

c Proximity to greenspace.

Characteristics of included studies

The total number of participants with SSDs across all studies was 50 708. The studies were conducted in seven countries: Denmark (k = 4), Taiwan (k = 2), the USA (k = 2), Canada (k = 1), Germany (k = 1), the Netherlands (k = 1), and Poland (k = 1). Study designs included cohort (k = 9), cross-sectional (k = 2), and quasi-experimental (k = 1). Seven studies explored the incidence rates of SSDs in relation to green spaces, and five studies explored the effect of green spaces on individuals with SSDs in relation to mood (k = 3), anxiety (k = 3), symptoms of psychosis (k = 1), hospital admission rates (k = 1), and length of hospital admission (k = 1).

Sample characteristics

Four studies reported descriptives for gender for people with SSDs (Bielinis, Jaroszewska, Łukowski, & Takayama, Reference Bielinis, Jaroszewska, Łukowski and Takayama2020; Boers, Hagoort, Scheepers, & Helbich, Reference Boers, Hagoort, Scheepers and Helbich2018; Henson, Pearson, Keshavan, & Torous, Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023), with a tendency towards male participants (range of 51–75%). Only two studies reported on participant ethnicity (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023), the samples were reported primarily as ‘White/Caucasian’ (35–54.3%). Four studies reported age descriptives, with ages ranging from 0–94 years (μ = 42.87, ±13.82) (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020; Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018; Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023).

Measurement of green space

For studies exploring schizophrenia incidence, green space was quantified using five metrics: (1) normalized difference vegetation index (NDVI), a metric used to capture the presence and density of green vegetation over a patch of land (Chang, Wu, Pan, Lung, & Su, Reference Chang, Wu, Pan, Lung and Su2019; Chang et al., Reference Chang, Wu, Wang, Chen, Wang and Su2020; Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018, Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2019, Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a, Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b). NDVI calculations range from −1 to 1, where a value of 1 indicates the highest density of green cover (The National Aeronautics and Space Administration [NASA], 2000); (2) enhanced vegetation index (EVI), a more sensitive measure of green space, in which calculations range from 0 to 1, where 1 indicates the greatest density of healthy green vegetation (Chang et al., Reference Chang, Wu, Wang, Chen, Wang and Su2020); (3) categories of green space (e.g. forest and recreational green spaces) and descriptors of green space (e.g. area size, connectedness of spaces) (Chang et al., Reference Chang, Wu, Wang, Chen, Wang and Su2020; Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018); (4) land cover from the Coordination of Information on the Environment (CORINE; European Environmental Agency, 2023), a database which classifies land cover according to categories ranging from urban green spaces to dense urban/industrial land use (Engemann et al., Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a); and (5) The Urban Health Equity Assessment and Response Tool (Urban HEART; Centre for Research in Inner City Health, 2024), which provides a measure of neighborhood-level green space, calculating the average amount of green space per km2 in a circular buffer around residential areas, based on geospatial data (Rotenberg, Tuck, Anderson, & McKenzie, Reference Rotenberg, Tuck, Anderson and McKenzie2022).

For studies exploring the benefits of exposure to green spaces for SSDs in relation to health service use and/or mental health symptoms, one study measured green space exposure as a forest recreation intervention (walking, stretching, watching landscapes) (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020). Two studies measured the percentage of agricultural, forest and natural areas within a circular buffer of patients' home addresses, using land databases (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018; Losert, Schmauß, Becker, & Kilian, Reference Losert, Schmauß, Becker and Kilian2012). Two studies matched GPS locations from participants' mobile phones to NDVI data (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023).

Measurement of schizophrenia and mental health symptoms

SSDs were quantified using the following: (1) the International Classification of Diseases (ICD-8, ICD-9, ICD-10; WHO, 1968, 1993) (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020; Chang et al., Reference Chang, Wu, Pan, Lung and Su2019, Reference Chang, Wu, Wang, Chen, Wang and Su2020; Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018, Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2019, Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a, Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b; Losert et al., Reference Losert, Schmauß, Becker and Kilian2012; Rotenberg et al., Reference Rotenberg, Tuck, Anderson and McKenzie2022); and (2) the Diagnostic and Statistical Manual of Mental Disorders (DSM-IV, DSM-V; American Psychiatric Association, 1994, 2001) (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018; Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023).

Other symptoms measured to assess the mental health benefits of green spaces included: (1) the Profile of Mood States (POMS; Dudek & Koniarek, Reference Dudek and Koniarek1987) (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020); (2) the State-Trait Anxiety Inventory, state anxiety measure only (STAI-S; Spielberger, Gorsuch, Lushene, Vagg, & Jacobs, Reference Spielberger, Gorsuch, Lushene, Vagg and Jacobs1983) (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020); (3) ecological momentary assessment (EMA; Shiffman, Stone, & Hufford, Reference Shiffman, Stone and Hufford2008), containing symptom questionnaires relating to anxiety and depression (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023), as well as symptoms of psychosis (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020); (4) Linguistic Inquiry and Word Count (LWIC) for affect expression (Pennebaker, Booth, Boyd, & Francis, Reference Pennebaker, Booth, Boyd and Francis2015) (Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023).

Measurement of health service use

Health service use was quantified by: (1) length of hospital admission in days (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018); and (2) psychiatric hospital admission rates, calculated by the number of admissions per location and analyzed as incidence rate ratios (IRRs). Only the first admission for each patient was counted and patients were excluded if their place of residence was unclear (Losert et al., Reference Losert, Schmauß, Becker and Kilian2012).

Main findings

A summary of the studies included in the review is provided in Table 1.

What is the association between exposure to green space and the incidence of schizophrenia spectrum disorders?

Seven studies, all with a cohort design, explored the incidence rate of SSDs in relation to exposure to green spaces. Four studies took a developmental approach, focusing on childhood exposure to green spaces and risk of later development of SSDs (Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018, Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2019, Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a, Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b), whilst the remainder focused on adult exposure to green spaces. After quality analysis, six studies were rated as ‘strong’ and one was rated as ‘moderate’. Four studies calculated risk of SSDs using hazard ratios (HRs), where a HR < 1 indicates beneficial effects of green space exposure for reducing the risk of SSDs. Three studies calculated relative risk of SSDs using IRRs, to measure differences between low and high greenspace exposure. IRRs were calculated from measuring differing levels of green space exposure and associated incidence rates for SSDs, with higher IRRs indicating a greater risk of SSDs. IRRs > 1 indicated an increased risk from exposure, IRRs equal to 1 indicated no difference, and IRRS < 1 indicated beneficial effects of green space exposure.

Exposure to green space is associated with a reduced risk of schizophrenia. Studies reported reductions in schizophrenia risk for individuals with greater green space exposure, with HRs ranging from 0.62 for the lowest green space exposure (Engemann et al., Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b), to 0.37 for the greatest greenspace exposure (Chang et al., Reference Chang, Wu, Pan, Lung and Su2019). Living in areas with the lowest concentration of green space was associated with an increased risk of developing schizophrenia (IRRs = 1.52 and 1.24), compared to living within the highest concentration of green space (Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018; Rotenberg et al., Reference Rotenberg, Tuck, Anderson and McKenzie2022). One study found that overall neighborhood greenness, such as forests and recreational green spaces, was associated with lower HRs for schizophrenia incidence (NDVI HR = 0.79, EVI HR = 0.57) (Chang et al., Reference Chang, Wu, Wang, Chen, Wang and Su2020). HRs were found to be lower for children who had grown up in environments with near-natural features (i.e. vegetation ranging from grasslands to forests, containing human influences, such as benches and pathways), compared to those growing up in environments with urban as the most frequent land cover category (HRs = 0.69–0.74) (Engemann et al., Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a), and HRs were lower for greater exposure to green space (HR = 0.62), compared to those with the lowest exposure (Engemann et al., Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b). Regarding specific psychiatric diagnoses, one study found that the reduced risk only applied to schizophrenia and schizophrenia-related disorders for greater green space exposure, this effect was not found for schizoaffective disorders (Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2019). In addition to these findings, one study reported potential protective effects of exposure to green spaces within cities (HR = 0.22) and metropolitan areas (HR = 0.46), with increased areas of green space within these locations associated with reduced HRs (Chang et al., Reference Chang, Wu, Pan, Lung and Su2019). Associations remained across all studies after controlling for a number of covariates for schizophrenia risk, including: gender, age, socioeconomic status (individual, parents and neighborhood-level), urbanicity, and family mental health history (see Table 1).

There may be a dose-response relationship between exposure to green space and schizophrenia risk. Three studies reported a dose-response relationship between exposure to green space and schizophrenia risk, with risk reducing as exposure to green space increased (Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018, Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2019, Reference Engemann, Pedersen, Agerbo, Arge, Børglum, Erikstrup and Horsdal2020a), IRRs ranged from 1.52 at the lowest green space exposure to 1.18 at the highest green space exposure (Engemann et al., Reference Engemann, Pedersen, Arge, Tsirogiannis, Mortensen and Svenning2018). Increasing green space density and cover was associated with a decreased risk of schizophrenia (HR = 0.62) (Engemann et al., Reference Engemann, Svenning, Arge, Brandt, Geels, Mortensen and Pedersen2020b), with larger green spaces and greater proximity to green space associated with HRs < 1 (Chang et al., Reference Chang, Wu, Wang, Chen, Wang and Su2020). Another study reported a significant negative association between surrounding greenness and schizophrenia risk, with HRs ranging from 0.49 to 0.37 as green space density increased (Chang et al., Reference Chang, Wu, Pan, Lung and Su2019).

What are the benefits of exposure to green space for individuals with SSDs in relation to (a) health service use and (b) mental health symptoms?

Five studies explored the benefits of exposure to green space for individuals with SSDs. Two studies used a cross-sectional design (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018; Losert et al., Reference Losert, Schmauß, Becker and Kilian2012), two studies used a cohort design (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023), and one study used a quasi-experimental design (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020). After quality analysis, three studies were rated as ‘moderate’ (Bielinis et al., Reference Bielinis, Jaroszewska, Łukowski and Takayama2020; Henson et al., Reference Henson, Pearson, Keshavan and Torous2020; Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023) and two were rated as ‘weak’ (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018; Losert et al., Reference Losert, Schmauß, Becker and Kilian2012).

(a) Health service use. The two cross-sectional studies explored proximity to green space in relation to: (1) length of hospital admission (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018), and (2) percentage of forest and agricultural areas in relation to admission rates for schizophrenia, calculated using IRRs (Losert et al., Reference Losert, Schmauß, Becker and Kilian2012). Findings suggest that proximity to green space was not significantly correlated with length of hospital admission (Boers et al., Reference Boers, Hagoort, Scheepers and Helbich2018). However, one study found a significant relationship between increases in the proportion of surrounding agricultural land and decreases in admission rates for people with SSDs (IRR = 0.96, p = 0.049) (Losert et al., Reference Losert, Schmauß, Becker and Kilian2012).

(b) Mental health symptoms. One cohort study measured symptoms of anxiety, depression, sleep, sociability, and psychotic symptoms amongst people with SSDs over the course of three months, an EMA survey accessed via mobile phone (Henson et al., Reference Henson, Pearson, Keshavan and Torous2020). GPS locations were collected alongside completion of the EMA, to measure green space cover and density. The study reported significantly lower symptoms for anxiety (d = −0.70), depression (d = −0.97) and psychosis (d = −0.94), and better sleep (d = −0.54) for settings with high levels of green space, compared to settings with low levels of green space.

Another cohort study measured emotional experience (happiness, sadness, and anxiety) and positive and negative speech affect (including negative affect subcategories: anxiety, anger, and sadness) over the course of seven days using EMA surveys accessed via mobile phones (Kangarloo et al., Reference Kangarloo, Mote, Abplanalp, Gold, James, Gard and Fulford2023). Data were collected three times a day at set times (10:00–13:00, 14:00–17:00, 17:00–20:00), and geolocations were collected alongside EMA data to measure green space cover and density. Results suggested small to moderate associations (rho values between −0.22 and −0.32) between greater green space exposure and lower scores for sadness and anxiety, across the seven days. There was also a moderate association (ρ = −0.29) between greater overall green space exposure and lower proportions of negative affect words used across the week, such as anxiety (ρ = −0.26) and anger words (ρ = −0.37). However, these findings were not significant at the daily level.

Finally, in a quasi-experimental study, 23 participants with SSDs participated in a forest recreation intervention, consisting of a one hour and 45-min walk in nature, with stretching and watching landscapes. The study captured pre and post-intervention scores using the POMS and the State-Trait Anxiety Inventory (STAI-S only). Significant decreases in all mood states of the POMS (except for vigor, which increased, and fatigue, where there were no changes) were found following the forest recreation intervention. There was also a significant decrease in anxiety levels (STAI-S), post intervention with a large effect size (d = 2.42).

Discussion

This review aimed to synthesize the findings from quantitative studies that explored exposure to green space, incidence rates of SSDs and benefits for people with SSDs in relation to health service use and mental health symptoms. Twelve studies were included in the review, of which seven explored associations between green space exposure and SSD incidence, and five explored the benefits of green space exposure for people with SSDs.

Overall, the findings suggest that exposure to green space is associated with a reduced risk of SSDs, with some evidence that there may be a dose-response relationship. Childhood exposure to green space may also reduce the risk of SSDs later on. The quality of evidence was mostly high for these studies, and sample sizes were large, suggesting that we can be relatively confident in these conclusions. This supports existing literature reporting an association between green space exposure and reduced risk of depression and anxiety disorders (Brown et al., Reference Brown, Perrino, Lombard, Wang, Toro, Rundek and Szapocznik2018; Gascon et al., Reference Gascon, Sánchez-Benavides, Dadvand, Martínez, Gramunt, Gotsens and Nieuwenhuijsen2018; Min et al., Reference Min, Kim, Kim and Min2017; Sarkar et al., Reference Sarkar, Webster and Gallacher2018). This body of evidence, taken together with the findings from the current review, provides clear evidence of the benefits of green space exposure in terms of reducing the risk of mental health diagnoses.

The studies in this review used a range of methods to explore the benefits of green space exposure, including cohort, cross-sectional and quasi-experimental designs. They report a range of benefits from green space exposure for people with SSDs, including improved mood, and reduced symptoms of anxiety and psychosis, as well as reductions in hospital admission rates. A strength of this body of literature is that a range of assessment methods have been used (e.g. EMA) such that it is not constrained by the sole use of self-report. However, the overall quality of the evidence was weaker, and sample sizes were much smaller, suggesting that we should be appropriately cautious when interpreting these findings. Nevertheless, these findings support existing literature showing that exposure to green space reduces symptoms of anxiety and depression (Berman et al., Reference Berman, Kross, Krpan, Askren, Burson, Deldin and Jonides2012; Gonzalez et al., Reference Gonzalez, Hartig, Patil, Martinsen and Kirkevold2010; Kotera et al., Reference Kotera, Lyons, Vione and Norton2021) and reduces length of psychiatric hospital admissions (Wheater et al., Reference Wheater, Potts, Shaw, Perkins, Smith, Casstles and Bellis2007). Despite the limitations in quality, these studies offer promising implications of the potential benefits of green space exposure for people with SSDs, which should be investigated further in future research to provide more robust evidence.

Collectively, the findings from the review provide support for the need to integrate and maintain green spaces as a public health intervention (Maas et al., Reference Maas, Verheij, Groenewegen, de Vries and Spreeuwenberg2006; Soga et al., Reference Soga, Evans, Tsuchiya and Fukano2021). Benefits reported from increasing surrounding green space suggests that planning should take into account the proportion of available green spaces within urban settings, with increases in green spaces having risk-reducing effects for SSDs. Given the reported risk-reducing effects of childhood exposure to green spaces from the current review, measures could include increasing access to green spaces for children, such as parks and recreational activities within green spaces. In addition, people with SSDs may benefit from access to green space interventions, such as horticulture programs, walks and other activities in nature, as demonstrated for other mental health conditions (Clatworthy et al., Reference Clatworthy, Hinds and Camic2013; Grassini, Reference Grassini2022; Kotera et al., Reference Kotera, Lyons, Vione and Norton2021).

Limitations

Regarding the literature included in the review, the evidence for the benefits of green space exposure for SSDs in relation to health service use and symptom reduction is emerging, such that the conclusions from this review are limited by the small number of studies available and the weaker quality of evidence, and findings are yet to be replicated. In addition, only two studies within the review reported on ethnicity, where the samples were majority White, and studies exploring incidence rates were mostly conducted in Denmark. Therefore, these results may not be generalizable cross-culturally.

It is also important to consider limitations of the review process. Omission of search terms for the full range of SSD symptoms may have biased results in favor of positive symptoms. Future studies should include search terms which encompass all dimensions of SSDs, including negative symptoms. In addition, the search terms for green spaces could be expanded to include components of green space, such as parks, woodlands, gardens, etc., to potentially increase eligible studies. Finally, this review did not investigate possible causes of heterogeneity for study results or complete sensitivity analyses, therefore the review is not able to determine the robustness of results beyond quality assessment.

Recommendations for future research

This review highlights the need to develop the evidence base for the benefits of green space exposure for individuals with SSDs. It is notable that only one published study to date has used an experimental design to examine in vivo green space exposure and the effects on a range of mental health symptoms. Larger scale studies are needed to assess the benefits of exposure to green space using both experimental and longitudinal designs, examining a broader range of outcomes that are not solely focused on symptom reduction, including wellbeing and recovery, and to determine the ‘dose’ of green space exposure that is needed to produce clinically-significant change. Future studies are needed to understand the components of green space that might be particularly beneficial, to identify the mechanisms through which green space interventions work, and finally to identify the factors that might act as moderators to determine who might benefit most from green space interventions. Additionally, examining cross-cultural differences in green space exposure and SSDs should be a research priority, as well as determining whether the findings linking green space exposure and incidence rates for SSDs are replicated in other countries.

Conclusion

Exposure to green space within both childhood and adulthood has risk reducing effects for the occurrence of SSDs, with some evidence for a dose response relationship. There is emerging evidence for the potential therapeutic benefits of exposure to green space for symptom reduction in people with SSDs and reduced health service use. Future research is needed to identify the optimal therapeutic ‘dose’ of green space exposure, to identify mediators and moderators of green space interventions and examine any cross-cultural differences.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291724001533.

Data availability statement

The datasets used during the review are available from the corresponding author on request.

Author contributions

Study design and protocol (L. M., L. E.); literature searches and summaries (L. M.); data extraction (L. M.); data synthesis (L. M.; L. E.); writing original draft (L. M.); editing (L. M., L. E.).

Funding statement

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Competing interests

None.

References

Adevi, A. A., & Lieberg, M. (2012). Stress rehabilitation through garden therapy: A caregiver perspective on factors considered most essential to the recovery process. Urban Forestry & Urban Greening, 11(1), 5158. https://doi.org/10.1016/j.ufug.2011.09.007CrossRefGoogle Scholar
Alcock, I., White, M. P., Wheeler, B. W., Fleming, L. E., & Depledge, M. H. (2014). Longitudinal effects on mental health of moving to greener and less green urban areas. Environmental Science & Technology, 48(2), 12471255. https://doi.org/10.1021/es403688wCrossRefGoogle ScholarPubMed
American Psychiatric Association. (1994). Diagnostic and statistical manual of mental disorders (4th ed.). Washington, DC: American Psychiatric Association.Google Scholar
American Psychiatric Association. (2001). Diagnostic and statistical manual of mental disorders (5th ed.). Washington, DC: American Psychiatric Association. https://doi.org/10.1176/appi.books.9780890425596Google Scholar
Barton, J., & Rogerson, M. (2017). The importance of greenspace for mental health. BJPsych International, 14(4), 7981. https://doi.org/10.1192/s2056474000002051CrossRefGoogle ScholarPubMed
Berman, M. G., Kross, E., Krpan, K. M., Askren, M. K., Burson, A., Deldin, P. J., … Jonides, J. (2012). Interacting with nature improves cognition and affect for individuals with depression. Journal of Affective Disorders, 140(3), 300305. https://doi.org/10.1016/j.jad.2012.03.012CrossRefGoogle ScholarPubMed
Bielinis, E., Jaroszewska, A., Łukowski, A., & Takayama, N. (2020). The effects of a forest therapy programme on mental hospital patients with affective and psychotic disorders. International Journal of Environmental Research and Public Health, 17(1), 118. https://doi.org/10.3390/ijerph17010118CrossRefGoogle Scholar
Boers, S., Hagoort, K., Scheepers, F., & Helbich, M. (2018). Does residential green and blue space promote recovery in psychotic disorders? A cross-sectional study in the province of Utrecht, the Netherlands. International Journal of Environmental Research and Public Health, 15(10), 2195. https://doi.org/10.3390/ijerph15102195CrossRefGoogle ScholarPubMed
Bowen, K. J., & Lynch, Y. (2017). The public health benefits of green infrastructure: The potential of economic framing for enhanced decision-making. Current Opinion in Environmental Sustainability, 25, 9095. https://doi.org/10.1016/j.cosust.2017.08.003CrossRefGoogle Scholar
Bowen, K. J., & Parry, M. (2015). The evidence base for linkages between green infrastructure, public health and economic benefit. Paper prepared for the project Assessing the Economic Value of Green Infrastructure. Victoria, Australia: Government of Victoria. https://www.vu.edu.au/sites/default/files/cses/pdfs/gi-econ-health-paper.pdfGoogle Scholar
Bowler, D. E., Buyung-Ali, L. M., Knight, T. M., & Pullin, A. S. (2010). A systematic review of evidence for the added benefits to health of exposure to natural environments. BMC Public Health, 10(1), 110. https://doi.org/10.1186/1471-2458-10-456CrossRefGoogle ScholarPubMed
Brown, S. C., Perrino, T., Lombard, J., Wang, K., Toro, M., Rundek, T., … Szapocznik, J. (2018). Health disparities in the relationship of neighborhood greenness to mental health outcomes in 249,405 US Medicare beneficiaries. International Journal of Environmental Research and Public Health, 15(3), 430. https://doi.org/10.3390/ijerph15030430CrossRefGoogle Scholar
Centre for Research in Inner City Health. (2024). Urban HEART @ Toronto. Toronto, Canada: Centre for Research in Inner City Health. http://www.torontohealthprofiles.ca/urbanheartattoronto.phpGoogle Scholar
Chang, H. T., Wu, C. D., Pan, W. C., Lung, S. C. C., & Su, H. J. (2019). Association between surrounding greenness and schizophrenia: A Taiwanese cohort study. International Journal of Environmental Research and Public Health, 16(8), 1415. https://doi.org/10.3390/ijerph16081415CrossRefGoogle ScholarPubMed
Chang, H. T., Wu, C. D., Wang, J. D., Chen, P. S., Wang, Y. J., & Su, H. J. (2020). Green space structures and schizophrenia incidence in Taiwan: Is there an association? Environmental Research Letters, 15(9), 094058. https://doi.org/10.1088/1748-9326/ab91e8CrossRefGoogle Scholar
Clatworthy, J., Hinds, J., & Camic, P. M. (2013). Gardening as a mental health intervention: A review. Mental Health Review Journal, 18(4), 214225. https://doi.org/10.1108/MHRJ-02-2013-0007CrossRefGoogle Scholar
Department for Levelling Up, Housing and Communities. (2023). National planning policy framework. London, UK: UK Government. https://www.gov.uk/government/publications/national-planning-policy-framework--2Google Scholar
Dudek, B., & Koniarek, J. (1987). The adaptation of profile of mood states (POMS) by DM McNair, M. Lorr, LF Droppelman. Przegląd Psychologiczny, 30, 753762.Google Scholar
Dzhambov, A. M. (2018). Residential green and blue space associated with better mental health: A pilot follow-up study in university students. Arhiv za higijenu rada i toksikologiju, 69(4), 340348. https://hrcak.srce.hr/file/312240CrossRefGoogle ScholarPubMed
Effective Public Health Practice Project (EPHPP). (2023, July 17). Quality assessment tool for quantitative studies. Ontario, Canada: Effective Public Health Practice Project (EPHPP). https://www.ephpp.ca/quality-assessment-tool-for-quantitative-studies/Google Scholar
Engemann, K., Pedersen, C. B., Agerbo, E., Arge, L., Børglum, A. D., Erikstrup, C., … Horsdal, H. T. (2020a). Association between childhood green space, genetic liability, and the incidence of schizophrenia. Schizophrenia Bulletin, 46(6), 16291637. https://doi.org/10.1093/schbul/sbaa058CrossRefGoogle ScholarPubMed
Engemann, K., Pedersen, C. B., Arge, L., Tsirogiannis, C., Mortensen, P. B., & Svenning, J. C. (2018). Childhood exposure to green space–a novel risk-decreasing mechanism for schizophrenia? Schizophrenia Research, 199, 142148. https://doi.org/10.1016/j.schres.2018.03.026CrossRefGoogle ScholarPubMed
Engemann, K., Pedersen, C. B., Arge, L., Tsirogiannis, C., Mortensen, P. B., & Svenning, J. C. (2019). Residential green space in childhood is associated with lower risk of psychiatric disorders from adolescence into adulthood. Proceedings of the National Academy of Sciences, 116(11), 51885193. https://doi.org/10.1073/pnas.1807504116CrossRefGoogle ScholarPubMed
Engemann, K., Svenning, J. C., Arge, L., Brandt, J., Geels, C., Mortensen, P. B., … Pedersen, C. B. (2020b). Natural surroundings in childhood are associated with lower schizophrenia rates. Schizophrenia Research, 216, 488495. https://doi.org/10.1016/j.schres.2019.10.012CrossRefGoogle ScholarPubMed
European Environment Agency. (2023, November 20). CORINE land cover. Copenhagen, Denmark: European Environment Agency, Datahub. Retrieved November 20, 2023, from https://www.eea.europa.eu/en/datahub/datahubitem-view/a5144888-ee2a-4e5d-a7b0-2bbf21656348Google Scholar
Fjaestad, S. L., Mackelprang, J. L., Sugiyama, T., Chandrabose, M., Owen, N., Turrell, G., & Kingsley, J. (2023). Associations of time spent gardening with mental wellbeing and life satisfaction in mid-to-late adulthood. Journal of Environmental Psychology, 87, 101993. https://doi.org/10.1016/j.jenvp.2023.101993CrossRefGoogle Scholar
Gascon, M., Sánchez-Benavides, G., Dadvand, P., Martínez, D., Gramunt, N., Gotsens, X., … Nieuwenhuijsen, M. (2018). Long-term exposure to residential green and blue spaces and anxiety and depression in adults: A cross-sectional study. Environmental Research, 162, 231239. https://doi.org/10.1016/j.envres.2018.01.012CrossRefGoogle ScholarPubMed
Gascon, M., Triguero-Mas, M., Martínez, D., Dadvand, P., Forns, J., Plasència, A., & Nieuwenhuijsen, M. J. (2015). Mental health benefits of long-term exposure to residential green and blue spaces: A systematic review. International Journal of Environmental Research and Public Health, 12(4), 43544379. https://doi.org/10.3390/ijerph120404354CrossRefGoogle ScholarPubMed
Gonzalez, M. T., Hartig, T., Patil, G. G., Martinsen, E. W., & Kirkevold, M. (2010). Therapeutic horticulture in clinical depression: A prospective study of active components. Journal of Advanced Nursing, 66(9), 20022013. https://doi.org/10.1111/j.1365-2648.2010.05383.xCrossRefGoogle ScholarPubMed
Grassini, S. (2022). A systematic review and meta-analysis of nature walk as an intervention for anxiety and depression. Journal of Clinical Medicine, 11(6), 1731. https://doi.org/10.3390/jcm11061731CrossRefGoogle Scholar
Henson, P., Pearson, J. F., Keshavan, M., & Torous, J. (2020). Impact of dynamic greenspace exposure on symptomatology in individuals with schizophrenia. PLoS One, 15(9), e0238498. https://doi.org/10.1371/journal.pone.0238498CrossRefGoogle ScholarPubMed
Houlden, V., Weich, S., Porto de Albuquerque, J., Jarvis, S., & Rees, K. (2018). The relationship between greenspace and the mental wellbeing of adults: A systematic review. PLoS One, 13(9), e0203000. https://doi.org/10.1371/journal.pone.0203000CrossRefGoogle ScholarPubMed
Howarth, M., Brettle, A., Hardman, M., & Maden, M. (2020). What is the evidence for the impact of gardens and gardening on health and well-being: A scoping review and evidence-based logic model to guide healthcare strategy decision making on the use of gardening approaches as a social prescription. BMJ Open, 10(7), e036923. http://doi.org/10.1136/bmjopen-2020-036923CrossRefGoogle ScholarPubMed
Kangarloo, T., Mote, J., Abplanalp, S., Gold, A., James, P., Gard, D., & Fulford, D. (2023). The influence of greenspace exposure on affect in people with and those without schizophrenia: Exploratory study. JMIR Formative Research, 7, e44323. https://doi.org/10.2196/44323CrossRefGoogle ScholarPubMed
Kotera, Y., Lyons, M., Vione, K. C., & Norton, B. (2021). Effect of nature walks on depression and anxiety: A systematic review. Sustainability, 13(7), 4015. https://doi.org/10.3390/su13074015CrossRefGoogle Scholar
Losert, C., Schmauß, M., Becker, T., & Kilian, R. (2012). Area characteristics and admission rates of people with schizophrenia and affective disorders in a German rural catchment area. Epidemiology and Psychiatric Sciences, 21(4), 371379. http://doi.org/10.1017/S2045796012000157CrossRefGoogle Scholar
Maas, J., Verheij, R. A., Groenewegen, P. P., de Vries, S., & Spreeuwenberg, P. (2006). Green space, urbanity, and health: How strong is the relation? Journal of Epidemiology & Community Health, 60, 587592. https://jech.bmj.com/content/60/7/587CrossRefGoogle ScholarPubMed
McCormick, R. (2017). Does access to green space impact the mental well-being of children: A systematic review. Journal of Pediatric Nursing, 37, 37. https://doi.org/10.1016/j.pedn.2017.08.027CrossRefGoogle ScholarPubMed
Min, K. B., Kim, H. J., Kim, H. J., & Min, J. Y. (2017). Parks and green areas and the risk for depression and suicidal indicators. International Journal of Public Health, 62, 647656. https://doi.org/10.1007/s00038-017-0958-5CrossRefGoogle ScholarPubMed
National Aeronautics and Space Administration. (2023, November 11). Measuring vegetation (NDVI & EVI). Maryland, USA: National Aeronautics and Space Administration. https://earthobservatory.nasa.gov/features/MeasuringVegetation/measuring_vegetation_2.phpGoogle Scholar
Page, M. J., Mckenzie, J. E., Bossuyt, P. M., Boutron, I., Hoffmann, T. C., Mulrow, C. D., … Moher, D. (2021). The PRISMA 2020 statement: An updated guideline for reporting systematic reviews. The BMJ, 372, n71. https://doi.org/10.1136/bmj.n71Google ScholarPubMed
Pennebaker, J. W., Booth, R. J., Boyd, R. L., & Francis, M. E. (2015). Linguistic inquiry and word count: LIWC2015. Texas, USA: Pennebaker Conglomerates. www.LIWC.netGoogle Scholar
Public Health England. (2020). Improving access to greenspace: A new review for 2020. London, UK: UK Government. https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/904439/Improving_access_to_greenspace_2020_review.pdfGoogle Scholar
Pun, V. C., Manjourides, J., & Suh, H. H. (2018). Association of neighborhood greenness with self-perceived stress, depression and anxiety symptoms in older US adults. Environmental Health, 17, 111. https://doi.org/10.1186/s12940-018-0381-2CrossRefGoogle Scholar
Rotenberg, M., Tuck, A., Anderson, K. K., & McKenzie, K. (2022). Green space and the incidence of schizophrenia in Toronto, Canada. The Canadian Journal of Psychiatry, 67(3), 238240. https://doi.org/10.1177/07067437221076722CrossRefGoogle ScholarPubMed
Sahlin, E., Ahlborg, G. Jr., Tenenbaum, A., & Grahn, P. (2015). Using nature-based rehabilitation to restart a stalled process of rehabilitation in individuals with stress-related mental illness. International Journal of Environmental Research and Public Health, 12(2), 19281951. https://doi.org/10.3390/ijerph120201928CrossRefGoogle ScholarPubMed
Sarkar, C., Webster, C., & Gallacher, J. (2018). Residential greenness and prevalence of major depressive disorders: A cross-sectional, observational, associational study of 94 879 adult UK Biobank participants. The Lancet Planetary Health, 2(4), e162e173. https://doi.org/10.1016/S2542-5196(18)30051-2CrossRefGoogle ScholarPubMed
Shiffman, S., Stone, A. A., & Hufford, M. R. (2008). Ecological momentary assessment. Annual Review Clinical Psychology, 4, 132. https://doi.org/10.1146/annurev.clinpsy.3.022806.091415CrossRefGoogle ScholarPubMed
Soga, M., Evans, M. J., Tsuchiya, K., & Fukano, Y. (2021). A room with a green view: The importance of nearby nature for mental health during the COVID-19 pandemic. Ecological Applications, 31(2), e2248. https://doi.org/10.1002/eap.2248CrossRefGoogle Scholar
Spielberger, C., Gorsuch, R., Lushene, R., Vagg, P., & Jacobs, G. (1983). Manual for the stait-trait anxiety inventory. California, USA: Consulting Psychologists Press.Google Scholar
Taylor, L., & Hochuli, D. F. (2017). Defining greenspace: Multiple uses across multiple disciplines. Landscape and Urban Planning, 158, 2538. https://doi.org/10.1016/j.landurbplan.2016.09.024CrossRefGoogle Scholar
Thomas, B. H., Ciliska, D., Dobbins, M., & Micucci, S. (2004). A process for systematically reviewing the literature: Providing the research evidence for public health nursing interventions. Worldviews on Evidence-Based Nursing, 1(3), 176184. https://doi.org/10.1111/j.1524-475X.2004.04006.xCrossRefGoogle ScholarPubMed
Tran, I., Sabol, O., & Mote, J. (2022). The relationship between greenspace exposure and psychopathology symptoms: A systematic review. Biological Psychiatry Global Open Science, 2(3), 206222. https://doi.org/10.1016/j.bpsgos.2022.01.004CrossRefGoogle ScholarPubMed
United Nations. (2018). 2018 revision of world urbanization prospects. New York, USA: Population Division of the United Nations Department of Economic and Social Affairs (UN DESA). https://www.un.org/en/desa/2018-revision-world-urbanization-prospectsGoogle Scholar
Van den Berg, A. E., Maas, J., Verheij, R. A., & Groenewegen, P. P. (2010). Green space as a buffer between stressful life events and health. Social Science & Medicine, 70(8), 12031210. https://doi.org/10.1016/j.socscimed.2010.01.002CrossRefGoogle ScholarPubMed
Vujcic, M., Tomicevic-Dubljevic, J., Grbic, M., Lecic-Tosevski, D., Vukovic, O., & Toskovic, O. (2017). Nature based solution for improving mental health and well-being in urban areas. Environmental Research, 158, 385392. https://doi.org/10.1016/j.envres.2017.06.030CrossRefGoogle ScholarPubMed
Wendelboe-Nelson, C., Kelly, S., Kennedy, M., & Cherrie, J. W. (2019). A scoping review mapping research on green space and associated mental health benefits. International Journal of Environmental Research and Public Health, 16(12), 2081. https://doi.org/10.3390/ijerph16122081CrossRefGoogle ScholarPubMed
Wheater, C. P., Potts, E., Shaw, E. M., Perkins, C., Smith, H., Casstles, H., & Bellis, M. A. (2007). Returning urban parks to their public health roots. Manchester: Department of Environmental and Geographical Sciences, Manchester Metropolitan University. https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=988083195defa6e19cd15cf9dd7a2ea3a05ad8c0Google Scholar
World Health Organization. (1968). ICD-8: International classification of diseases (8th revision). Geneva, Switzerland: World Health Organization.Google Scholar
World Health Organization. (1993). ICD-10: International classification of diseases (10th revision). Geneva, Switzerland: World Health Organization. https://icd.who.int/browse10/2016/enGoogle Scholar
World Health Organisation. Regional Office for Europe. (2016). Urban greenspaces and health. Copenhagen, Denmark: World Health Organisation. https://iris.who.int/handle/10665/345751Google Scholar
World Health Organisation. Regional Office for Europe. (2017). Urban green space interventions and health: A review of impacts and effectiveness. Copenhagen, Denmark: World Health Organisation. https://www.who.int/europe/publications/m/item/urban-green-space-interventions-and-health--a-review-of-impacts-and-effectiveness.-full-reportGoogle Scholar
Figure 0

Figure 1. PRISMA flowchart.

Figure 1

Table 1. Summary of studies and quality analysis

Supplementary material: File

Marcham and Ellett supplementary material

Marcham and Ellett supplementary material
Download Marcham and Ellett supplementary material(File)
File 32.6 KB