Health benefits of evidence-based biophilic-designed environments: A review
Article information
Abstract
Background and objective
People-nature experiences, which suggest that humans seek connections between nature and other forms of life, were presented by biologist E. O. Wilson in 1984. Biophilic design attributes support environments that can improve human connections to nature. A significant amount of literature on environmental psychology provides empirical evidence that nature benefits humans, and that practical landscape and built environments can be designed to link humans and nature (e.g., the 14 biophilic design patterns). To date, however, there has been no well-done research on reviewing the health benefits of biophilic design.
Methods
The paper provides a narrative review on biophilic design and human health. The scope of this article is limited to biophilic-design books and peer-review articles related to “biophilic design,” “evidence-based,” “benefits,” “health,” rather than an attempt to identify universal issues with biophilia hypothesis.
Results
A total of 45 papers were included in our review, which was related to the top five biophilic design patterns and design: the presence of natural images, the presence of plants, visual and non-visual connections to nature, and material connection with nature. These studies were related to physiology and psychology through direct or indirect connections with nature and experiences in space and place.
Conclusion
This study presents two important comparisons of the empirical research on biophilic design and human health that can explain the relationship of people-nature experiences to biophilic design and human health and provides insights into related researches and recommendations for future application of our findings.
Introduction
When the COVID-19 pandemic spread worldwide, thousands of people were forced to stay indoors more than usual. Even though research has shown that 120 minutes of contact with nature every week increases health and well-being (White et al., 2019), this phenomenon has significantly affected people’s lifestyles; some of these changes include working from home and social distancing in public, each of which reduces opportunities to experience nature. A study by Lopez et al. (2020) described the critical social use of urban parks before and during the COVID-19 crisis: when one worried about social distancing, crowding, safety, accessibility, etc., it affects one’s willingness to visit parks/green spaces. However, research pointed out the increasing number of people start to visit greens even more than before COVID-19. Overall, people consider parks and green spaces, especially the elements of trails, trees, shading, seating, landscaping, and water, to be integral for physical and mental health (Lopez et al., 2020). Despite these recent changes, being in nature can be seen as a beneficial resource for health issues and the human ecology system, which enhances numerous physical and mental health benefits.
Humans live in the ecosystem and are part of the biosphere, so unsurprisingly, their emotions are closely connected to nature. Humans prefer savanna-like landscapes and positive attitudes that lead them to immerse themselves in nature (Balling and Falk, 1982; Heerwagen et al., 1993). In Biophilia Hypothesis, Wilson (1984) described humans as being deeply connected to nature and lifelike elements. Joye and De Block (2011) further asserted that different genetic predispositions influence biophilic tendencies. Several environmental psychology studies have been conducted into the contributions of nature verse urban areas that support attention restoration, positive emotions, reduced stress, and other physical benefits (Berto, 2005; Barton and Pretty, 2010; Hartig et al., 1991; Kaplan and Kaplan, 1989; Ulrich, 1981; Kim et al, 2016; Marcus and Sachs, 2013; White et al., 2019). Kellert (2018) pointed out human adaptations and design applications that focus on the use of biophilic design attributes, which are included in a built environment to improve the connection to nature, provide health benefits (Browning et al., 2014; Berto et al., 2015). These designs are inspired by natural patterns, attributes, and elements and encourage the use of these features and systems in a built environment to provide humans with the health benefits of a much-needed exposure to nature.
While the literature is replete with discussions related to biophilia and biophilic designs that relate to human health, an analysis of the relationship between nature and health is still lacking. As such, this study will address the following questions: What is a biophilic design, and what is the relationship between biophilic design and health outcomes? In the present study, we will review and evaluate several evidence-based studies and describe the critical role of landscape designers in our everyday contact with nature.
Research Methods
The goal was to build an evidence-based review of biophilic design and the health benefits thereof according to the broad concept described in 14 Patterns of Biophilic Design (Browning et al., 2014) and the elements presented in Nature by Design: The Practice of Biophilic Design (Kellert, 2018). Based on those descriptions, we included biophilic design as the variation of a direct and an indirect connection to nature and of a space and place with the health-benefit outcomes of “psychological health” and “physiological health,” as all of these describe the relationship between biophilic design and human health. The “cognitive” focuses on cognition and behavioral performance, including concentrating, communication, productivity, etc.; the “psychological health” includes positive emotion, tranquility, relax, low anger, environmental psychological sense of feelings, etc.; the “physiological health” is about low physical tension, such as lower heart rate, blood pressure, pain, etc. However, the “cognitive” outcomes are part of the psychological feeling, in this article, we connect and integrate those into “psychological health”, which could be more consistent with the study.
Search and selecting articles
Based on the core concept of biophilic design (Kellert et al., 2008; Kellert, 2018), this study is a narrative review of disparate literature that describes known health benefits related to biophilic design. The keywords “biophilic design,” “evidence-based,” “benefits,” and “health” were searched on Google Scholar; and 10 relevant studies, review articles, reports, and books were selected to interpret the concept of biophilic design and the relationship thereof to human health and well-being (i.e., Browning et al., 2014; Gillis and Gatersleben, 2015; Grinde and Patil, 2009; Gullone, 2000; Heerwagen and Hase, 2001; Heerwagen, 2006; Kellert et al., 2008; Kellert, 2018; Lumber et al., 2018; Ryan et al., 2014). The snowballing method was then used to further enlarge the body of related articles, particularly those published in SCI, SSCI, A&HCI journals, etc. A total of 62 articles were chosen; repeated articles, review articles, and irrelative content were excluded, resulting in 45 articles for the next step of the analysis, see Fig. 1. A majority of these papers were from the Journal of Environmental Psychology and Environment and Behavior; and some were from the International Journal of Environmental Research and Public Health, HortTechnology, and Health & Place, etc., among others. The experiments conducted in these studies typically involved the use of photographs, videos, direct contact with natural and/or urban environments, laboratories, and workplaces; and they utilized a quantitative or qualitative method, including the use of preference questionnaires, the Perceived Restorativeness Scale (PRS), a Profile of Mood States (POMS), Zuckerman Inventory of Personal Reactions (ZIPPER), biofeedback, and functional Magnetic Resonance Imaging (fMRI) to measure the health benefits and brain activities of biophilic designs.
The biophilic design patterns include visual and non-visual connections to nature; non-rhythmic sensory stimuli; thermal and airflow variability; the presence of water, plants, or animals; biomorphic forms and patterns; materials that are connected to nature; complexity and order; the concept of prospect and refuge; the risks and perils; and mystery (Browning et al., 2014). The elements considered were light, air, plants, animals, water, views, landscapes, weather, shapes and forms, materials, textures, colors, images, organized and complexity, prospect and refuge, etc., were integrated with similar concepts into new categories of biophilic design patterns and elements (Table 1); for example, “visual connection to nature” is related to “view” and “landscape,” so these were combined into one biophilic pattern.
Data analysis
The relationships between different natural patterns and elements and health benefits that were described in the literature and the experimental stimuli were analyzed to classify the environment into different biophilic patterns and elements. We then used Microsoft Excel (Office 2016) to integrate the results into one of the following categories: psychological health and well-being and physiological health.
Descriptive analysis of biophilic patterns and elements
A total of 45 peer-reviewed studies that re-examined the interactions between the environment and human health benefits were selected. Of the proposed biophilic design patterns and elements, we determined that “the presence of natural images” (24%), “the presence of plants” (14%), “non-visual connections to nature” (13%), and “visual connections to nature” (11%) and, “material connection with nature” (11%) etc. were the most frequently used in experimental research designs and related health benefits (Fig. 2).
Content analysis of the 45 articles
A brief description of the content analysis showed in Table 2. According to the contents, we found out there were 43 articles tested about the psychological outcomes by using the patterns of “direct and indirect experience of nature” and “space and place”. The psychological outcomes include increasing productivity, creativity, concentration, attention restoration, positive mood, lower tension, and anxiety, etc. Eighteen articles tested the physical index with the biophilic patterns, such as low heart rate, pain, decrease diastolic blood pressure (DBP), systolic blood pressure (SBP), skin conductance, etc. Besides, we found out the researchers would evaluate several health benefits or the similar concepts use a different method to test, for example, “stress” could be tested in the questionnaire or physical stress (i.e. DBP or SBP, etc.). Therefore, there were sixteen articles both discuss the psychological and physical outcomes. We would categorize those benefits into both labels in psychological and physical outcomes.
Results and Discussion
Health benefits of biophilic patterns: Psychological health and well-being
Table 3 shows the psychological health and well-being outcomes of biophilic designs, including but not limited to feeling positive emotions and pleasure, attention restoration, preference, feelings of relaxation, and decrease a sense of anger, etc. Moreover, it includes increasing cognitive functionality and performance.
Several studies found that visual and non-visual connections to nature and direct experiences with nature that is made possible by the presence of plants have positively affect psychological health and well-being in outdoor environments and interior designs (e.g., Barton and Pretty, 2010; Hartig et al., 2003; Larsen et al., 1998; Orsega-Smith et al., 2004; Pheasant et al., 2010; Thomsen et al., 2011); those results are in line with two environmental psychological theories–Attention Restoration Theory (Kaplan and Kaplan, 1989) and the Stress Reduction Theory (Ulrich et al., 1991), which explain two ways in which contact with nature improves people’s psychological states; the presence of plants in an office also reduces perceived stress (Dijkstra et al., 2008; Larsen et al., 1998). Moreover, in an office setting and a hospital, exposure to nature and sunlight through a window view can improve employee performance and mood (Zadeh et al., 2014); and patients are able to recover better from surgery (Ulrich, 1984). Besides, much of the literature described how a visual connection to nature and the presence of plants in an outdoor/indoor environment, also referred to as “direct experience with nature,” can improve cognitive functionality and performance by increasing communication, concentration, and productivity, (e.g., Shoemaker et al., 1992; Thomsen et al., 2011; Larsen et al., 1998; Zadeh et al., 2004). One of the cited studies highlighted that being physically present in nature not only could stimulate sensory perceptions and feelings of well-being, but also alters states-of-consciousness, especially feelings of relaxation (Kjellgren and Buhrkall, 2010).
However, these studies yielded few findings between the psychological impact of indirect experiences with nature, such as biomorphic forms and patterns, materials, and natural images that could enhance creativity and productivity (Joye, 2007; Lichtenfeld et al., 2012). Schatz and Bowers (2005) investigated how color design in the workplace influences worker moods, performance, productivity, and satisfaction. Tsunetsugu et al. (2007) discovered that an interior that is composed of 45% wood imbues a sense of comfort, naturalness, and restfulness; these results are similar to those of a study that incorporated natural elements in a hospital setting (Nyrud et al., 2014).
“Space and Place” is defined as the nature of the space. Visual connections to nature and exposure to natural environments with high prospect levels and low refuge levels are restorative; alternately, exposure to natural environments with low prospect levels and high refuge levels aren’t restorative, however, could increase negative emotion, physical stress, and attention fatigue (Gatersleben and Andrews, 2013). Whether in the field of in laboratory experiments, the feeling of being connected to nature in a naturally designed setting, as opposed to an urban setting, has been shown to markedly improve psychological health and well-being by affecting pleasure and emotion, restoring attention, and reducing stress (Browning et al., 2014; Hartig et al., 2003; Ryan et al., 2014; White et al., 2010); furthermore, a natural-setting space can evoke a sense of mystery, attraction, and one’s preference (Herzog and Bryce, 2007; Herzog and Kropscott, 2004). Rapee (1997) found, however, that perceived threats in nature-based activities, such as on a mountain, in an alley or forest, or while scuba diving, can lead to feelings of anxiety and fear.
Biophilic patterns: Physiological health benefits
Table 4 shows the physiological effects that were identified using instruments to detect heart rate, blood pressure, cortisol levels, and other physiological indicators, in addition to a questionnaire intended to understand stress reactions in the human body. These findings were similar to those for psychological health and well-being: Visual and non-visual connections to nature and the presence of plants and light reduces stress, lowers the heart rate, and decreases blood pressure, among other benefits (Hartig et al., 2003; Küller and Lindsten, 1992; Ulrich, 1984; Ulrich et al., 1991; Zadeh et al., 2014). Moreover, Pheasant et al. (2010) indicated that the perceived stimulation from the environment and the visual-auditory interactions thereof can affect a sense of tranquility; this is in line with Hunter et al. (2010), who found out that, compared to viewing a freeway, viewing a beach influences a stronger sense of tranquility and activates the connection between the auditory and perception areas in the brain. Tsunetsugu et al. (2007) also concluded that the use of natural analogs, such as natural materials, can lead to stress reduction.
Conclusion
This review collected and integrated the 18 patterns of biophilic design with the 18 physiological health outcomes and 42 psychological outcomes, including 14 cognitive functionality and performance; and concluded that most of the cited research used natural images (e.g., mountains, forests, water elements), the presence of plants in an interior environment, and a visual connection to nature in an indoor environment as methods to investigate the relationship between nature and human health. Moreover, some studies used non-visual nature connections such as natural sounds or textures to determine benefits with nature. These studies were selected because they present evidence-based conclusions that natural patterns and elements, which are associated with biophilic design principles that support human adaptation, engagement, and immersion in nature, improve human health and provide multiple benefits for humans in a built environment (e.g., increase productivity and provide aesthetic appeal, emotional attachment, and physical and social dimensions) (Kellert, 2018).
Five patterns were determined to limit the findings in this study: non-rhythmic sensory stimuli, thermal and airflow variability, the presence of water, organized/complexity, and integrating parts to create a whole. The empty cells in Table 2–4 indicate a possible direction for researchers who wish to test these relationships; for example, Kellert (2018) explained that direct or indirect connections to water, such as pictures and videos of wetlands, ponds, and waterfalls, provides human-nature experiences and the psychological and physiological benefits thereof. White et al. (2010) also asserted that photographs of water, plants, animals, and other elements of nature can influence a person’s preferences, affections, and levels of restorativeness, which can lead to further research to investigate the benefits of actual exposure to landscapes and water to psychological and physiological health. Patterns of thermal and airflow variability are associated with weather and good atmospheric conditions, which is linked to human-nature experiences (Browning et al., 2014; Kellert, 2018); future studies could shed light on the micro-climate indicators in a built environment that influence human feelings. Finally, the different forms of landscapes (e.g., English, French, Japanese, and Chinese gardens), the organization and complexity thereof, and the pattern of integrating parts of those landscape patterns to create a whole that can affect human health warrants further investigation.
The concept of biophilia is a psychological feeling of connecting nature and humans; the biophilic design is a method of using nature and natural-like patterns and elements that enhance the opportunity for humans to exposure to nature in the built environment. It can be used to construct a framework a people-nature experiences, to verify the impact that these biophilic patterns have on human physiological and psychological health in urban green spaces. More specifically, the research found out the 18 patterns and elements of biophilic design and health could be widely used in visual and non-visual connections to nature, the presence of natural images, natural material, and plants in outdoor or interior environment, which could reduce psychological and physical stress, recover attention restoration, and improve positive emotion and aesthetic attraction, etc. Those findings are related to the concept of restorativeness environment (i.e. being away, fascination, extent, and compatibility), landscape preference (i.e. legibility, mystery, complexity, coherence), and the stress reduction theory. By better understanding, these relationships and the related theories in environmental psychology, the methods that incorporate biophilic design measures to improve the landscapes and urban designs can be devised.
Our findings as using the biophilic patterns and elements might be linked to the Sustainable Development Goals (SDGs) of Goal 3 for the action of “ensuring healthy lives and promoting well-being”, Goal 11 for “making cities and human settlements inclusive, safe, resilient and sustainable”, and Goal 15 for “protecting, restoring and promoting sustainable of ecosystems on land”. Those policies are insights to link biophilic design as an approach of restorativeness and ecological environment for balancing human and species in the built environment.