Examining the Relationships Between Indoor Environmental Quality Parameters Pertaining to Light, Noise, Temperature, and Humidity and the Behavioral and Psychological Symptoms of People Living With Dementia: Scoping Review

Background: A common challenge for individuals caring for people with Alzheimer disease and related dementias is managing the behavioral and psychological symptoms of dementia (BPSD). Effective management of BPSD will increase the quality of life of people living with dementia, lessen caregivers’ burden, and lower health care cost. Objective: In this review, we seek to (1) examine how indoor environmental quality parameters pertaining to light, noise, temperature, and humidity are associated with BPSD and how controlling these parameters can help manage these symptoms and (2) identify the current state of knowledge in this area, current gaps in the research, and potential future directions. Methods: Searches were conducted in the CINAHL, Embase, MEDLINE, and PsycINFO databases for papers published from January 2007 to February 2024. We searched for studies examining the relationship between indoor environmental quality parameters pertaining to light, noise, temperature, and humidity and BPSD. Results: A total of 3123 papers were identified in the original search in October 2020. After an additional 2 searches and screening, 38 (0.


Background
Alzheimer disease and related dementias (ADRD) are a major public health challenge.The number of Americans aged ≥65 years with Alzheimer disease was estimated to be 6.7 million in 2023 [1].In 2023, total payments for health care, long-term care, and hospice services for people aged ≥65 years with dementia were estimated to be US $345 billion in the United States.The number of people with Alzheimer disease in the United States is projected to grow to 13.8 million by 2060 [1].
A major component of the high psychological and financial costs of ADRD is related to addressing the needs of people living with dementia who have behavioral and psychological symptoms of dementia (BPSD), also called neuropsychiatric symptoms.BPSD encompass the challenging behaviors exhibited by people living with dementia that comprise a variety of symptoms that commonly include, but are not limited to, apathy, anxiety, depression, agitation, delusions, hallucinations, motor disturbances, and sleep changes.These symptoms are associated with faster disease progression [2], increased caregiving burden [3], and earlier placement into long-term care settings [4].Pharmacological intervention is often not effective and is associated with undesirable side effects [5], with nonpharmacological therapy being a first-line approach to management [6].
The causes of BPSD are multiple, ranging from intrinsic neuropathologic factors to human factors such as caregiver interactions and the social-environmental milieu [7].There is considerable evidence suggesting that environmental factors can affect the progression of different diseases as well as human behaviors [8,9].The environment as a risk factor for ADRD has been reviewed, suggesting links between increased risks of ADRD and factors such as poor air quality, environmental toxins, and occupation-related exposures [10,11].However, what has been less clearly examined is the potential direct relationship between person-or residence-level experienced environmental factors and contemporaneous behavioral changes associated with ADRD.This is important because most older people and people living with dementia spend the majority of their time indoors [12].
There has long been debate regarding the definition of the environment [13].For the purpose of this review, we are focusing on the ambient environment as defined by Harris et al [14].Factors pertaining to the ambient environment, such as light, noise, temperature, and humidity, contribute to the visual, acoustic, and thermal comforts of the occupants and may be associated with their BPSD [15]; for example, inadequate light has been suggested to be a risk factor for sundowning syndrome (people with late-stage dementia exhibiting more agitated behaviors in the late afternoon and evening) because of the role of light in vision and its role in circadian rhythm modulation [16,17].Therefore, designing an indoor environment that would address the needs of people living with dementia is paramount and may reduce their BPSD.A first step to creating an optimal indoor environment for people living with dementia with BPSD is to understand which environmental factors are related to BPSD and how they impact the symptoms.
Previous papers have reviewed the effect of the long-term care environment on physical activity levels [18], the achievement of therapeutic goals such as safety and socialization [19], and neuropsychiatric symptoms [20,21].However, these reviews have primarily focused on the parameters of the built environment (eg, size and layout of spaces), interior design, and occupancy and staffing ratios, rather than aspects of the environmental quality that impact comfort, such as temperature and humidity, noise levels, and lighting.Comfort is especially important to consider for people living with dementia because BPSD represent an expression of discomfort, stress, and unmet needs when insight and communication become more difficult [22].Nevertheless, anosognosia and aphasia also prevent the subjective measurement of comfort.Thus, it is necessary to understand the impact of various objective aspects of environmental quality that may improve comfort and, in turn, BPSD.

Objectives
Accordingly, we conducted this scoping review to (1) examine how indoor environmental quality parameters pertaining to light, noise, temperature, and humidity are associated with BPSD and how controlling these parameters can help manage these symptoms and (2) identify the current state of knowledge on the relationship between indoor environmental quality parameters and BPSD, current gaps in the research, and potential future directions.

Overview
We followed the PRISMA-ScR (Preferred Reporting Items for Systematic Reviews and Meta-Analyses extension for Scoping Reviews) reporting guidelines for this scoping review.We conducted a scoping review because we aimed to (1) provide an overview of the broad literature examining the relationship between indoor environmental quality parameters and BPSD and (2) identify gaps and future directions.
The databases used were CINAHL, Embase, MEDLINE, and PsycINFO.A literature search strategy was crafted for each database that would retrieve records containing a combination of appropriate index terms and text words pertaining to the following concepts: dementia (dementia, Alzheimer disease, etc), environmental conditions (heat, temperature, light, humidity, etc), and BPSD (anxiety, depression, apathy, agitation, Six reviewers (WMA-Y, CW, MN, LM, RH, and KW) completed the screening process, which consisted of two stages: (1) title and abstract screening and (2) full-text screening.First, the title and abstract of each paper were reviewed by 2 reviewers independently to examine whether the studies met the inclusion criteria.The reviewers then met iteratively to reconcile any differences in their decisions regarding whether a particular paper should be included.If the 2 reviewers could not come to an agreement, a third reviewer would help reach a decision.After title and abstract screening was completed, the included papers at this stage were retrieved for full-text screening, and the process was repeated after reading the papers in their entirety.

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Written in English Six reviewers (WMA-Y, MN, ZB, LM, RH, and SG) extracted data from the included papers after the screening process was completed.A survey built in Qualtrics (Qualtrics International Inc) was created to assist this process.The survey listed questions covering study design, year of publication, the region and residential settings in which the research was conducted, sample size, demographics of the sample, which environmental conditions were assessed and how they were examined, and which BPSD were evaluated and how they were measured.
Next, the papers were categorized by the examined environmental factor or factors: (1) light level, (2) noise level, (3) temperature or humidity, and (4) multiple indoor environmental quality parameters.If there were unified themes of BPSD examined in the articles (eg, agitation and mood-related symptoms), the study results of each theme would be synthesized by summarizing the counts of different study designs and providing a narrative summary [23].All study data were also summarized into tables.In doing so, the current state of knowledge, gaps in research, and future directions were identified.

Ethical Considerations
Institutional review board approval was not required for this scoping review because the research did not involve human participants.

Overview
A total of 3123 articles were identified in the search initiated on October 7, 2020.After excluding papers published before 2006 as well as duplicates, the titles and abstracts of 1887 articles were screened, after which 1707 (90.46%) articles were excluded, and 180 (9.54%) were retrieved for full-text screening.Ultimately, of these 180 articles, 26 (14.4%) were included.
The search was updated on April 21, 2022, and on February 22, 2024, and 12 articles were added to the final pool; hence, 38 papers were included in this scoping review (Figure 1).Of the 38 papers, 8 (21%) were randomized controlled trials (RCTs), 14 (37%) were quasi-experiments, 5 (13%) were pretest-posttest studies, 6 (16%) were cross-sectional studies, 4 (11%) were case series, and 1 (3%) was a cohort study (refer to Table 1 for more information).The following sections synthesize the findings of the included studies, categorized by the indoor environmental quality factor or factors examined (Table 2).Residents who stayed in the traditional, large-scale unit showed significantly worse decline in irritable behaviors compared to those who stayed in the smallscale, home-like unit across time; the small-scale, home-like unit had significantly better ratings in stimulation (lighting, visual and tactile stimulation, and noise) as well as personalization according to the TESS-NH  [58], 2020

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The CMAI scores increased when residents were exposed to relatively cold or warm indoor temperatures at a statistically significant level; the level of agitation was also significantly correlated to the duration of the increased or decreased temperature -CMAI Agitation iButton data loggers (Maxim Integrated) -Temperature Tartarini et al [59], 2017 The comparison of CMAI sumscores between assessments before and during the intervention yielded significant differences with decreased agitated behavior after installation of the dynamic lighting system (P<.

Agitation
Of the 34 studies, 16 (47%) examined the effect of light on agitation either as a syndrome or related to individual agitated behaviors such as wandering or screaming [24][25][26][27]29,30,32,[35][36][37][38]46,[54][55][56]60].Of these 16 studies, 14 (88%) examined the effect of changing light exposure in RCTs (n=6, 43%) [30,35,37,46,54,55] or quasi-experimental study designs (n=8, 57%) [26,27,29,32,36,38,56,60], while 2 (12%) examined the effect of light on agitated behaviors in a purely observational or natural history study [24,25].Among the light therapies studied were bright light therapy [30,35,46,54,55] and outdoor environment simulations, such as dawn-dusk simulation [29,56].A wide range of light intensities was deployed in these light therapies, ranging from 1000 lux [36] to 10,000 lux [54].The duration and time of day of application of these light therapies were heterogeneous as well; for example, in the study by Onega et al [54], bright light therapies were applied twice a day (once in the morning and once in the afternoon), while in the study by Kolberg et al [46], light therapy was applied from 10 AM to 3 PM with varying light levels before and after this interval.Due to the heterogeneity of the light therapies and study designs, direct comparison across the studies was infeasible.Among these 16 studies, in addition to the multiple approaches to applying light therapy, there was also heterogeneity in the way agitation was assessed.The Cohen-Mansfield Agitation Inventory [64], which measures the frequencies of 29 different agitated behaviors, was the scale used most commonly to assess the level of agitation in people living with dementia across weeks.Other scales used included the Pittsburgh Agitation Scale [65] and the ABMI [63], both of which are based on direct observations of the patient.The 6 RCTs, which ranged in study duration from 8 weeks to 15 months, used bright light [30,35,37,46,54,55].However, the results from the RCTs were conflicting.The symptoms of agitation or restlessness were reduced in 3 (50%) of the 6 RCTs [37,54,55] but not in the remaining 3 (50%) [30,35,46].The lack of improvement in agitation after bright light exposure in these studies [30,35,46] could be due to measurement errors in the subjective assessment of either light level or level of agitation or because of changes in medications not being tracked, as suggested by the authors.
The study by Figueiro et al [38] showed that the effects of light therapy on patients' agitation varied depending on the participants' cognitive status.The study, which examined the effect of long-term, all-day exposure to circadian-effective light on the sleep, mood, and behavior in persons with dementia, revealed that the lighting intervention was more effective for people with severe dementia than for those with mild or moderate dementia in reducing agitation [38].
There can be discrepancies between self-reported sleep quality and objectively measured sleep quality.In the study by Hjetland et al [42], ambient bright light treatment was administered to nursing home patients with dementia in a placebo-controlled RCT.While better sleep was reported using the Sleep Disorders Inventory in the bright light therapy group than in the standard lighting group at weeks 16 and 20, actigraphically measured sleep outcomes showed no statistically significant differences between the 2 groups.

Mood-Related Symptoms
Of the 13 studies involving lighting that addressed the relationship between symptoms of depression in people living with dementia and light in the environment [25,30,[35][36][37][38][39]41,[45][46][47]54,55], 6 (46%) were RCTs [30,35,37,46,54,55], 4 (31%) were quasi-experimental studies [39,41,45,47], 2 (15%) were pretest-posttest studies [36,38], and 1 (8%) was a case series [25].A decrease in depressive symptoms was reported in 9 (75%) of the 12 lighting intervention studies [30,[36][37][38][39]46,47,54,55]; for example, in the RCT described in the study by Onega et al [54], those who were exposed to bright light over a 2-week period showed a significant improvement in depressive symptoms (P values ranging from .001 to .017 for DSAOA, DMAS-17, and Cohen-Mansfield Agitation Inventory [CSDD]) while those in the placebo control group showed no improvements in their depressive symptoms.In the quasi-experimental study by Konis et al [47], the participants in a daylight intervention experienced a decrease over the trial in the Cornell Scale for Depression in Dementia (CSDD) score, while the control participants showed a statistically nonsignificant increase in the CSDD score (a higher CSDD score indicates more severe depression).In a pretest-posttest experimental study by Figueiro et al [36], 300 to 400 lux of a blueish-white light was found to significantly decrease depressive symptoms as measured by the CSDD.Some of the studies (2/12, 17%) reported that the efficacy of a lighting intervention is dependent on participants' characteristics.In the study by Hickman et al [41], analysis indicated a sex-by-treatment interaction.Significant sex differences were found in CSDD scores in response to evening light, all-day light, and standard lighting.Male participants experienced significantly more depressive symptoms under morning light than under standard lighting (P=.007).By contrast, female participants experienced fewer depressive symptoms under morning light than under standard lighting, although this result was not statistically significant (P=.09).
Similarly, the study by Bromundt et al [29], in which a visual analog scale was used to assess mood, indicated that the improvement in mood from dawn-dusk simulation was dependent on age.In the study, the younger subgroup experienced a stronger positive effect from dawn-dusk simulation on mood [29].
The study by Jao et al [43] examined the effect of light on apathy.The study, which was a case series of people living with dementia in nursing home or assisted living settings, assessed apathy by rating 14 separate 20-minute videos on different days per participant using the Person-Environment Apathy Rating-Apathy subscale [66].Ambient light (and sound) measurements were collected during the 20-minute video sessions.Light level was found to have had no significant effect on apathy.
The RCT conducted by Kolberg et al [46] in nursing home dementia units with 69 participants examined the effect of light on anxiety and found that the group that received bright light treatment as the intervention had a larger reduction on the composite score of the Neuropsychiatric Inventory-Nursing Home version Affect subsyndrome, which indicated better improvement in depression and anxiety at follow-up after 16 weeks compared to the control group.

Agitation and Wandering
Of the 5 observational studies, 2 (40%) examined the relationship between noise and agitation among participants with dementia [25,44], and 1 (20%) of the 5 experimental studies aimed to decrease agitation using a white noise intervention [49].Noise level did not distinguish between episodes of agitation in 1 (50%) [25] of the 2 observational studies, although the study was limited by sample size (10 participants) [25].In addition, the study by Bankole et al [25] was the only study to examine environmental conditions in the private home setting, which may be distinct from long-term care settings in terms of the effects of noise on agitation.The observational study by Joosse [44], which had 53 participants and used a sound level meter to measure noise levels, found that a higher accumulation of exposure to noise over a day was significantly predictive of agitated behavior in residents with dementia in a long-term care facility [44].The study by Cohen-Mansfield et al [32] did not find an association between noise and agitation in residents in nursing homes.However, the study was limited by a lack of objective measurement of sound.Finally, in the study by Lin et al [49], an intervention providing daily ambient white noise (55-70 dB) for 20 minutes in the afternoon over a 4-week period significantly decreased the frequency of agitated behavior for participants in the experimental group but not for those in the control group, suggesting that the type of noise, rather than an absence of noise, may be calming.
The observational study by Algase et al [24] examined the effect of noise levels on wandering behavior.In the study of 122 nursing home residents, greater variation in ambient noise level was associated with periods of wandering.There was a significant increase in the risk of wandering (odds ratio 1.09) per SD of variation in ambient noise level [24].

Mood-Related Symptoms
The effect of noise on symptoms related to aspects of mood (apathy, affect, or anxiety) was considered in 7 studies that examined associations with depression [25], apathy [31,43], affect or mood [33,34,40], and anxiety [58]: 3 (43%) quasi-experimental studies [31,33,58], 2 (29%) cross-sectional studies [34,40], and 2 (29%) case series studies [25,43].When noise levels were moderate, rather than low or high, studies found that participants were more highly engaged (ie, less apathetic) [31,34,40] and exhibited greater pleasure or a more positive attitude [33,34].High levels of background noise in particular were related to less engagement in 2 (67%) of the 3 studies that examined affect or mood [34,40] but were not related to negative affect, leading the authors to conclude that high background noise may cause participants to become less attuned to their environment and bored or sleepy but not uncomfortable or upset [40].Another study provided evidence of the need for stimulating sound: Jao et al [43] did not find an association between apathy and overall noise level but did find an association between apathy and a lack of clear, discernible sound stimuli (ie, only chaotic background noise).Finally, signs of anxiety in participants with dementia were decreased with an intervention that applied white noise during a walking program in the experimental group only [58].
The case series study by Tartarini et al [59] found that the level of agitation of participants with dementia in a nursing home XSL • FO RenderX facility increased significantly when the indoor average temperatures diverged from 22.6 °C.At the same time, the duration of exposure to high temperature (>22.6 °C) and low temperature (<22.6 °C) was linearly correlated with Cohen-Mansfield Agitation Inventory scores.In the cross-sectional studies by Algase et al [24] and Cohen-Mansfield [34], the authors suggested that there was not enough variation in the indoor temperature level or humidity level to identify a relationship with participants' behaviors.
Of the 8 studies, 5 (62%) reported some associations between indoor environmental quality parameters and BPSD.One of the themes that these studies suggested was that both overstimulation and understimulation from indoor environmental quality parameters can worsen BPSD.Algase et al [24] reported that brighter light and more variations in sound levels were associated with wandering.The studies by Cohen-Mansfield et al [31,33] that examined the effect of the physical environment on pleasure, engagement, and mood had similar findings.It was found that in nursing homes, pleasure was most likely to be experienced by participants with dementia in environments with moderate noise levels [33].In addition, attention and engagement duration in participants with dementia were higher when light was normal in comparison to a dark room, and their attention and attitude were significantly less positive when the lighting in the room was bright than when the lighting was normal [31].In the same study, all indicators of engagement significantly favored a moderate level of noise over no noise or low noise levels, and engagement duration was significantly longer for a moderate level of noise compared to high and very high levels of noise.
The cross-sectional study by Garre-Olmo et al [40] measured the physical environment in multiple spaces within the nursing home and found that indoor environmental quality parameters (light, temperature, and noise) in individual living spaces in the nursing home were uniquely associated with participants' quality of life, behaviors, and mood as measured with the Quality of Life in Late-Stage Dementia Scale; for example, the authors found that low lighting levels in the bedroom were associated with signs of negative affect, high temperature in the bedroom was associated with lower quality of life experienced by the participants, and high noise levels in the living room were associated with low levels of social interaction.
To examine the relationship between multiple environmental factors and agitation in persons with cognitive decline in their home environments, Bankole et al [25] installed environmental sensors in people's homes that provided continuous data over a 30-day period; in addition, the participants with cognitive decline wore actigraphy devices that provided objective measures of their activity level continuously.Furthermore, 10 caregivers used smartwatches or tablets to report episodes of agitation experienced by the people with cognitive decline in real time, which enabled more direct analysis of the relationship between the behaviors and contemporaneous environmental conditions.Personalized neural networks were built for 6 dyads, which predicted episodes of agitation with light level as a predictor.These networks achieved F 1 -score values, which are measures of predictive performance in binary classifications, ranging from 86.12% to 97.07%.F 1 -score values can range from 0% to 100%, with a higher F 1 -score indicating a better predictive performance.Regarding temperature, the study [25] found that temperature showed strong positive correlation with Teager energy scores from actigraphy device data, which are measures of the aggregate energy of movement [68] and were associated with the agitation exhibited by the people living with dementia.
Of the 8 studies, 3 (38%) failed to identify a link between multiple domains of environmental conditions and BPSD.Jao et al [43] studied the association between apathy in residents with dementia in long-term care facilities and the characteristics of care environments, which included light level, noise level, environmental ambience, crowding, staff familiarity, and environmental stimulation.The authors found that light and sound levels did not show statistically significant effects on apathy [43].Cohen-Mansfield et al [32] found that lighting and background noise were not associated with levels of agitation in nursing home residents with dementia but that may be due to small variations in these factors.Similarly, Cohen-Mansfield [34] reported no association between noise and mood in people with dementia attending recreational groups.
As seen in Table 2, of the 38 included studies, 6 (16%) relied solely on self-report data for measuring the environment, 13 (34%) used only sensors, and 2 (5%) use both sensors and self-report data, while the environment was not measured but manipulated in 17 (45%) studies.For measurements of BPSD in people living with dementia, of the 38 studies, 36 (95%) used informant-report scales, such as the Neuropsychiatric Inventory Questionnaire; less than half of these studies (n=16, 44%) also used behavioral sensors such as actigraphy to provide objective data.

Overview
The definition of environment encompasses several major elements: physical environment (eg, light level, noise level, temperature, and humidity), social environment (eg, number of people in proximity), and built environment (eg, furnishings).The focus of this scoping review is on the effects of the indoor environmental quality parameters pertaining to light, noise, temperature, and humidity on BPSD.Given the fact that most older individuals, including people living with dementia, spend most of their time indoors, better understanding of how these physical indoor environmental quality parameters may affect behavioral health is critical.Overall, this review outlines preliminary evidence on the notable linkages between indoor environmental quality parameters and BPSD.Further research remains to be conducted in the field.

Principal Findings
The evidence base suggests that light during the day is helpful in modulating circadian rhythm, as well as alleviating sleep disturbance and mood-related disorders.Overall, overstimulation and understimulation of environmental factors can lead to challenging behaviors in people living with dementia; for example, when the environment exhibits high levels or low levels of noise, people living with dementia may exhibit more challenging or disturbing behaviors [44,49].Similarly, challenging behaviors may be associated with the ambient temperatures experienced by the people living with dementia because there was more agitation observed when the environment was either relatively too hot or too cold for the person living with dementia [59].Such findings are consistent with the existing models that explain the causes of BPSD, including the unmet needs model [69] and the progressively lowered stress threshold model [70].Ultimately, finding the proper balance of environmental factors for providing the most personal comfort and quality of life for people living with dementia and caregivers may help to minimize the occurrences of BPSD.

Future Directions of Research
Light is the most researched indoor environmental quality parameter.Most studies on light therapy have shown that it improves sleep and mood in people living with dementia.However, the findings regarding its effect on agitation are conflicting and warrant further research.
The evidence base generally suggests that when noise levels exceed tolerable ranges, behavioral symptoms become more frequent and severe.Studies indicate that both the time duration of exposure to noise and the type of noise exposure could contribute to behavioral symptoms.Future research should explore these factors further.
Studies examining the effects of temperature or humidity on BPSD are largely observational.There exists a need to better understand how thermal comfort affects BPSD in people living with dementia, especially because there are studies suggesting that older adults may need a higher ambient temperature to attain thermal comfort compared to younger adults [71,72].
Environmental factors were often evaluated using self-reported data, which can be prone to biases.The lack of objective measurement of the environment makes measuring and linking the specific effects of the indoor environmental quality parameters on the behaviors of people living with dementia difficult.Of the 38 included studies, 30 (79%) focused on a single environmental factor, measured over relatively short periods of time, limiting the ability to examine more holistically how the environment affects BPSD.To some degree, this single-domain focus may reflect the complexity as well as the cost of deploying multiple sensor types in multiple indoor spaces.As technology advances, indoor environmental quality parameter sensors are expected to become more affordable and scalable.
Although most environmental exposure occurs indoors, studies need to consider in parallel the outdoor environment in terms of its effects on behavior, which is especially important for studies conducted in personal residences because people also spend time outdoors.Going forward, studies should adopt a more holistic approach by deploying sensors to objectively and longitudinally measure the total environment.
While environmental conditions can be objectively sensed and measured, very often, BPSD of the people living with dementia are either reported by the person affected by dementia or observed and interpreted as occurring by an external observer (usually a caregiver) present when the behavior occurs.In this scoping review, 36 (95%) of the 38 included studies relied on these self-reports or observer reports of BPSD.This type of reporting may contain subjective bias.In addition, a variety of scales have been used for assessing the occurrences of BPSD, which differ in their content, structure, and timing of recall.This likely adds to imprecision in comparing the results across multiple studies.More research is needed to examine how different scales for evaluating BPSD relate to each other and, in turn, to multiple environmental conditions.At the same time, whenever possible, the assessment of BPSD should be corroborated with unobtrusive technology such as actigraphy, which can provide objective data.
As evidenced by multiple studies in this review, the effect of the environment on people living with dementia may be dependent on age, sex, and cognitive state.In addition, manifestations of BPSD may be unique for each person living with dementia as well.Recent work by Iaboni et al [73] showed that the features from wearable multimodal sensors varied in their importance to their predictive models for agitation by both individual and behavior type.Finding the optimal environment for each person living with dementia will help support aging in place, which will improve their quality of life and lower the cost of health care.This may be best achieved by being able to examine the environment and behavior at the individual level with a goal of achieving person-centered assessments of well-being in their environment.The use of continuous multimodal sensing data and frequent self-report facilitates the ability to evaluate and analyze data at the individual or "n-of-1" level [73][74][75], supporting the principle that each individual is unique.Care providers need to know the unique environments, needs, and preferences of each person with dementia to provide the best care and minimize troubling BPSD.Future research should seek to build effective computational models that will incorporate multiple continuous data streams, both environmental and behavioral, that will predict the occurrences of BPSD so that proactive intervention can be implemented [25].

Implications for Clinical Practice and Policy
At a macro level, the findings of this review, although they are rudimentary, can help inform the design of long-term care XSL • FO RenderX facilities and residential homes for people living with dementia.Individual assessments of responses to environmental factors can be conducted upon admission; for example, large windows may be used in long-term care facilities to let in sunlight, and this should be supplemented by a dawn-dusk simulation system to address the excessive, or lack of, sunlight in different seasons to modulate residents' sleep and circadian rhythm.In addition, the temperature in long-term care facilities and older adults' homes should be kept at an optimal range that would maximize the comfort of residents.Moreover, quiet flooring and sound-absorbing panels may be used in the long-term care facilities to reduce the noise level; as evidenced by the studies in this review, overly stimulating or noisy environments can increase BPSD.These measures may increase the cost of building and sustaining these long-term care facilities because, for example, maintaining a narrow temperature range can place additional strain on heating, ventilation, and air-conditioning systems in these facilities and may not be energy efficient.However, if the long-term care facilities are more attuned to the needs of people living with dementia, it may result in a decrease in BPSD, improving the quality of life of the people living with dementia and the caregivers as well.This would reduce staff burnout and turnover, ultimately lowering health care costs.Implementing such measures on a broad societal level requires further cost-benefit analysis.

Limitations
This scoping review has limitations.One of the limitations is that we included studies with heterogeneous designs (eg, observational or experimental), which made the synthesis of results difficult.However, 1 of the aims of this scoping review was to provide an overview of the current state of knowledge regarding the relationship between indoor environmental quality parameters and BPSD.As such, heterogeneous studies were included.Another limitation is that only articles published in English were included.Moreover, only a subset of indoor environmental factors (light level, noise level, temperature, and humidity) were included in this review, while there are other factors relating to BPSD as well, such as psychosocial and biological influences [76].Notably, this review did not include indoor air quality, another environmental factor that increasingly can be assessed objectively in situ.Air quality has been associated with depression and anxiety in older adults based on spatiotemporal models [77].A recent study suggested that total volatile organic compound level, among other indoor factors, was significantly correlated with specific areas where behavioral changes occurred in people with moderate to severe dementia in a nursing home [78].This review only provides evidence for the relationship between a subset of the indoor environmental quality parameters and BPSD, but the relationship likely is best interpreted in a much larger context.

Conclusions
This review suggests that indoor environmental quality parameters pertaining to light level, noise level, temperature, and humidity may be associated with BPSD.An environment that maximizes the comfort of people living with dementia may decrease their BPSD.Most of the studies (34/38, 89%) in this scoping review pertained to the environmental factor light level, while relatively few studies (5/38, 13%-11/38, 29%) examined the relationship between the remaining indoor environmental quality parameters and BPSD.Among the included studies, there were conflicting findings in the relationship between bright light and agitation, which will need further research.A variety of subjective scales were used to assess the environment and BPSD, which makes synthesizing and comparing results across studies difficult.Going forward, as computational methods and objective sensing technology advance and become more affordable, the behaviors of people living with dementia and their environments should be measured holistically and objectively so that future nonpharmacological intervention can be evidence based.

Figure 1 .
Figure 1.PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) flow diagram of the search and screening results.
i ADRD: Alzheimer disease and related dementias.
j GDS: Global Deterioration Scale.k BCRS: Brief Cognitive Rating Scale.l MMSE-KC: Korean version of the MMSE developed as part of the Korean version of the Consortium to Establish a Registry for Alzheimer's Disease assessment packet.m NR: not reported.n NITE-AD: Nighttime Insomnia Treatment and Education in Alzheimer's Disease.o ICD-10: International Classification of Diseases, Tenth Revision.
i CSDD: Cornell Scale for Depression in Dementia.
j MOUSEPAD: Manchester and Oxford Universities Scale for the Psychopathological Assessment of Dementia.k CRBRS: Crichton Royal Behavior Rating Scale.lABMI: Agitation Behavior Mapping Instrument.m GOME: Group Observational Measurement of Engagement.n NPI-NH: Neuropsychiatric Inventory-Nursing Home version.o SDI: Sleep Disorders Inventory.p QUALID: Quality of Life in Late-Stage Dementia.q PAIN-AD: Pain Assessment in Advanced Dementia.r PEAR: Person-Environment Apathy Rating.s KNPI-Q : Korean version of the Neuropsychiatric Inventory Questionnaire.t CSDD-K: Korean version of the Cornell Scale for Depression in Dementia.u VAS-GV: visual analog scale-global vigor.v VAS-GA: visual analog scale-global affect.w TESS-NH: Therapeutic Environment Screening Survey for Nursing Homes.x MOSES: Multidimensional Observational Scale for Elderly Subjects.
y PAS: Pittsburgh Agitation Scale.z BARS: Behavioral Activity Rating Scale.aa DSAOA: Depressive Symptom Assessment for Older Adults.ab DMAS-17: Dementia Mood Assessment Scale, 17 items.ac PGCARS: Philadelphia Geriatric Center Affect Rating Scale.ad PGCMS: Philadelphia Geriatric Center Morale Scale.

Table 1 .
Summary of residential settings, region, study design, intervention, sample size, participant cognitive status, and participant age for all included studies.MDS-COGS: Minimum Data Set Cognition Scale.
a Not applicable.bM: male.c F: female.d MMSE: Mini-Mental State Examination.e f S-MMSE: Standardized Mini-Mental State Examination.g CPS: Cognitive Performance Scale.h BIMS: Brief Interview for Mental Status.

Table 2 .
Summary of environmental conditions and behavioral and psychological symptoms of dementia (BPSD) outcomes examined, the subjective and objective methods of assessment, and the main results for all included studies.
NH/RC: Therapeutic Environment Screening Survey for Nursing Homes and Residential Care.