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Intervention for sleep problems in nursing home residents with dementia: a cluster-randomized study

Published online by Cambridge University Press:  08 January 2024

Martin Nikolaus Dichter Open the ORCID record for Martin Nikolaus Dichter [Opens in a new window] ,
Jonas Dörner ,
Denise Wilfling ,
Almuth Berg ,
Thomas Klatt ,
Ralph Möhler ,
Burkhard Haastert ,
Gabriele Meyer ,
Margareta Halek  and
Sascha Köpke
Martin Nikolaus Dichter*
Affiliation:
Institute of Nursing Science, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Jonas Dörner
Affiliation:
Deutsches Zentrum für Neurodegenerative Erkrankungen (DZNE), Witten, Germany School of Nursing Science, Faculty of Health, Witten/Herdecke University, Witten, Germany
Denise Wilfling
Affiliation:
Institute of Social Medicine and Epidemiology, Nursing Research Group, University of Lübeck, Lübeck, Germany
Almuth Berg
Affiliation:
Institute of Health and Nursing Sciences, Martin Luther University Halle-Wittenberg, Medical Faculty, Halle (Saale), Germany
Thomas Klatt
Affiliation:
Institute of Health and Nursing Sciences, Martin Luther University Halle-Wittenberg, Medical Faculty, Halle (Saale), Germany
Ralph Möhler
Affiliation:
Institute for Health Services Research and Health Economics, Centre for Health and Society, Medical Faculty and University Hospital Düsseldorf, Heinrich-Heine-University Düsseldorf, Düsseldorf, Germany
Burkhard Haastert
Affiliation:
mediStatistica, Neuenrade, Germany
Gabriele Meyer
Affiliation:
Institute of Health and Nursing Sciences, Martin Luther University Halle-Wittenberg, Medical Faculty, Halle (Saale), Germany
Margareta Halek
Affiliation:
School of Nursing Science, Faculty of Health, Witten/Herdecke University, Witten, Germany
Sascha Köpke
Affiliation:
Institute of Nursing Science, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
*
Correspondence should be addressed to: M. N. Dichter, Institute of Nursing Science, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany. Tel: +49 221-478-34640; Mobil: +49 15142228492; Fax: +49 221 478-85931. Email: [email protected].

Abstract

Objective:

To reduce sleep problems in people living with dementia using a multi-component intervention.

Design:

Cluster-randomized controlled study with two parallel groups and a follow-up of 16 weeks.

Setting:

Using external concealed randomization, 24 nursing homes (NH) were allocated either to the intervention group (IG, 12 clusters, 126 participants) or the control group (12 clusters, 116 participants).

Participants:

Participants were eligible if they had dementia or severe cognitive impairment, at least two sleep problems, and residence of at least two weeks in a NH.

Intervention:

The 16-week intervention consists of six components: (1) assessment of sleep-promoting activities and environmental factors in NHs, (2) implementation of two “sleep nurses,” (3) basic education, (4) advanced education for staff, (5) workshops to develop sleep-promoting concepts, and (6) written information and education materials. The control group (CG) received standard care.

Measurements:

Primary outcome was ≥ two sleep problems after 16 weeks assessed with the Sleep Disorders Inventory (SDI).

Results:

Twenty-two clusters (IG = 10, CG = 12) with 191 participants completed the study. At baseline, 90% of people living with dementia in the IG and 93% in the CG had at least two sleep problems. After 16 weeks, rates were 59.3% (IG) vs 83.8% (CG), respectively, a difference of −24.5% (95% CI, −46.3% – −2.7%; cluster-adjusted odds ratio 0.281; 95% CI 0.087–0.909). Secondary outcomes showed a significant difference only for SDI scores after eight and 16 weeks.

Conclusions:

The MoNoPol-Sleep intervention reduced sleep problems of people living with dementia in NH compared to standard care.

Keywords

nursing homesdementiasleep problemssleepcomplex interventionsdyssomniasperson-centered care
Type
Original Research Article
Information
International Psychogeriatrics , Volume 36 , Special Issue 10: Issue Theme: Positive Psychiatry of Aging , October 2024 , pp. 965 - 978
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of International Psychogeriatric Association

Introduction

Sufficient and restful sleep is essential for physical and psychological functioning (Ramar et al., Reference Ramar, Malhotra, Carden, Martin, Abbasi-Feinberg, Aurora, Kapur, Olson, Rosen, Rowley, Shelgikar and Trotti2021; Suzuki et al., Reference Suzuki, Miyamoto and Hirata2017). In the course of dementia, sleep problems regularly occur, preventing sufficient sleep in people living with dementia from obtaining sufficient sleep (Webster et al., Reference Webster, Costafreda Gonzalez, Stringer, Lineham, Budgett, Kyle, Barber and Livingston2020a; Wilfling et al., Reference Wilfling, Dichter, Trutschel and Kopke2019). Sleep problems can be defined as documented disturbances of sleep/wake cycle characterized by the presence of at least two of the four following characteristics: (1) increased wake after sleep onset which affect the function or well-being of either the individual or whose caregiver, (2) decreased total sleep time of one-quarter of the individual total nocturnal sleep compared to premorbid nocturnal sleep patterns or, if this is not known, a sleep pattern of less than six hours between 9:00 pm and 6:00 am, (3) poor continuity in daytime waking compared to premorbid waking and wakefulness, with an increase in the number and/or duration of daytime naps, and (4) changed diurnal sleep pattern (Yesavage et al., Reference Yesavage, Friedman, Ancoli-Israel, Bliwise, Singer, Vitiello, Monjan and Lebowitz2003). Sleep problems include symptoms like difficulty falling asleep, frequent nocturnal awakenings, waking too early in the morning, and daytime sleepiness (Li and Gooneratne, Reference Li and Gooneratne2019; Tractenberg et al., Reference Tractenberg, Singer, Cummings and Thal2003). Important reasons for the occurrence of sleep problems are advanced age, chronic illnesses, mobility restrictions, reduced brain performance, medication intake, (Fung et al., Reference Fung, Vitiello, Alessi, Kuchel and Committee2016; Neikrug and Ancoli-Israel, Reference Neikrug and Ancoli-Israel2010), and environmental factors (Dörner et al., Reference Dörner, Hüsken, Schmüdderich, Dinand, Dichter and Halek2023).

The majority of people living with dementia in nursing homes are in an advanced stage of dementia with a high prevalence of sleep problems. A German study and a meta-analysis showed prevalence of 23% (Wilfling et al., Reference Wilfling, Dichter, Trutschel and Kopke2019) and 20% (Webster et al., Reference Webster, Costafreda Gonzalez, Stringer, Lineham, Budgett, Kyle, Barber and Livingston2020a).

Poor sleep quality is associated with a decrease of physical and mental health and quality of life (Uchmanowicz et al., Reference Uchmanowicz, Markiewicz, Uchmanowicz, Koltuniuk and Rosinczuk2019; Zhang et al., Reference Zhang, Li, Zhao, Mao, Abdulai, Liu, Tu, Wang, Qian, Jiang, Tian, Luo, Dong, Wang and Bie2019). People living with dementia report that, in addition to a decrease in functional and cognitive abilities, they have difficulties getting out of bed in the morning. Nursing staff report that people living with dementia refuse food, care, and daytime activities after a “bad night” (Dörner et al., Reference Dörner, Hüsken, Schmüdderich, Dinand, Dichter and Halek2023).

Sleep problems in people living with dementia are often accompanied by agitation or aggressive behavior (Cipriani et al., Reference Cipriani, Lucetti, Danti and Nuti2015; Webster et al., Reference Webster, Powell, Costafreda and Livingston2020b). For treatment of agitation and sleep problems, psychoactive drugs including hypnotics are frequently prescribed. A comparison of Western European countries demonstrated a heterogeneous prevalence of antipsychotic prescription for people living with dementia in nursing homes between 12 and 59% (pooled percentage 27%) depending on country (Janus et al., Reference Janus, van Manen, I.J. and Zuidema2016).

Currently, there are no effective pharmacological interventions for reducing sleep problems (McCleery et al., Reference McCleery and Sharpley2020). In contrast, a recent Cochrane review indicates that multi-component, complex interventions, containing multiple (interacting) components, have the strongest potential in preventing or reducing sleep problems (Wilfling et al., Reference Wilfling, Calo, Dichter, Meyer, Mohler and Kopke2023b), which is also reflected by current guideline recommendations(National Institute for Health and Care Excellence, 2018). A complex intervention with different (interacting) components seems worthwhile, considering the diverse challenges in preventing or reducing sleep problems in this population. These challenges include potential triggers and causes of sleep disturbances, the number and complexity of behaviors and skills required by those delivering the intervention, different groups of organizational levels targeted by the intervention, the number and heterogeneity of outcomes, and the need of flexibility or tailoring of the intervention (Craig et al., Reference Craig, Dieppe, Macintyre, Michie, Nazareth and Petticrew2008). Available multi-component interventions have combined the following components: Activating nursing home residents during daytime, creating bedtime routines, creating sleep-promoting night care, avoiding negative symptoms such as pain, itching, anxiety, and/or creating a sleep-promoting environment (e.g. concerning light, noise, temperature) (Wilfling et al., Reference Wilfling, Hylla, Berg, Meyer, Köpke, Halek, Möhler and Dichter2021). The MoNoPol-Sleep (multi-modal, non-pharmacological intervention for sleep disturbances in people with dementia living in nursing homes) study pursues the development and evaluation of a new non-pharmacological multi-component intervention to prevent and reduce sleep problems in people living with dementia in nursing homes.

Methods

Study design

The MoNoPol-Sleep study is a cluster-randomized controlled study with two parallel groups (IG: intervention group, CG: control group) and a follow-up after eight (T 1) and 16 weeks (T 2) (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021). The study was approved by the ethics committee of the German Society of Nursing Science (no. 20–016) and registered in the ISRCTN registry (ISRCTN36015309). The study protocol has been published in advance (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021). Data collection was performed between May 2021 and April 2022.

Recruitment and eligibility criteria

Potential participating nursing homes were approached in the regions of Lübeck (Northern Germany), Halle (Saale) (Eastern Germany) and Witten (Western Germany), based on existing institutional networks between study centers and nursing homes as well as information flyers and publications in long-term care journals and the via the study website. Eligible nursing homes required at least 50 residents and sufficient resources (staff and time) to implement the intervention and support data collection. Nursing homes were excluded if they participated in a concurrent dementia-specific, care-related project or planned to do so.

Inclusion criteria for people living with dementia were a documented dementia diagnosis or a Dementia Screening Scale score of ≥ three (Köhler et al., Reference Köhler, Weyerer and Schäufele2007), occurrence of at least two sleep problems based on the Sleep Disorders Inventory (SDI) (Tractenberg et al., Reference Tractenberg, Singer, Cummings and Thal2003), and a nursing home stay of at least two weeks. In deviation from the study protocol, we also included people living with dementia with only one sleep problem according to the SDI, due to the unexpectedly low prevalence of sleeping problems. Residents’ exclusion criteria were documented sleep apnea, REM-Sleep-behavior disorders, or respite care.

Intervention

The intervention was developed according to the MRC framework for complex interventions (Craig et al., Reference Craig, Dieppe, Macintyre, Michie, Nazareth and Petticrew2013) based on the principles of person-centered care and a summary of the current evidence (Wilfling et al., Reference Wilfling, Calo, Dichter, Meyer, Mohler and Kopke2023b; Wilfling et al., Reference Wilfling, Hylla, Berg, Meyer, Köpke, Halek, Möhler and Dichter2021). Stakeholder perspectives were explored in two surveys regarding the prevalence of sleep problems (Wilfling et al., Reference Wilfling, Dichter, Trutschel and Kopke2019), nurses’ burden caused by sleep problems of nursing home residents (Wilfling et al., Reference Wilfling, Dichter, Trutschel and Kopke2020), and attitudes and knowledge of night nurses in relation to sleep promotion in nursing home residents (Wilfling et al., Reference Wilfling, Berg, Dörner, Bartmann, Klatt, Meyer, Halek, Möhler, Köpke and Dichter2023a). Also, a qualitative study exploring the perspectives of people living with dementia and nurses working in nursing homes on sleep and sleep problems was conducted (Dörner et al., Reference Dörner, Hüsken, Schmüdderich, Dinand, Dichter and Halek2023). A program theory in the form of a theory of change was developed (Dichter et al., Reference Dichter, Hylla, Berg and Wilfling2020).

The resulting multi-component MoNoPol-Sleep intervention is based on the principles of person-centered care and consists of six components: (1) Assessment of established sleep-promoting interventions and environmental aspects in the participating nursing homes, (2) training and implementation of two sleep nurses as change agents per nursing home, (3) basic education courses for nursing staff: “Sleep problems in dementia,” (4) advanced education courses for nursing staff: “Tailored problem-solving” (two workshops), (5) two workshops with nursing management and sleep nurses: “Development of an institutional sleep-promoting concept,” and (6) written information and education material (e.g. brochures and “One Minute Wonder” posters) (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021). A comprehensive description of the intervention can be found elsewhere (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021).

In the CG, standard care was applied.

Measures

The primary outcome was the prevalence of at least two sleep problems in people living with dementia at T2 assessed with the SDI (Tractenberg et al., Reference Tractenberg, Singer, Cummings and Thal2003). The SDI allows for proxy-based assessment of the frequency and severity of seven sleep problems: (1) “difficulty falling asleep,” (2) “getting up in the night,” (3) “walking around, walking up and down, or engaging in inappropriate activities at night,” (4) “waking up at night, getting dressed with the intention of going outside, thinking that it is morning and it is time to start the day,” (5) “waking up too early in the morning,” (6) “sleeping excessively during the day,” and (7) “other disturbing nocturnal behaviors.” Rating covers the presence of these sleep problems assessed by “yes” or “no.” The SDI assessment was carried out exclusively by nurses who had at least a part time (50%) contract and had worked at least three night shifts during the preceeding three months.

Frequency and severity of sleep problems, daytime sleepiness, and self-rated sleep quality were assessed as secondary outcomes.

The SDI allows for rating of frequency and severity for each sleep problem (range 0 to 12) and for the whole instrument (range 0 to 84) (Hjetland et al., Reference Hjetland, Nordhus, Pallesen, Cummings, Tractenberg, Thun, Kolberg and Flo2020). Higher values indicate more severe sleep problems. Data were collected at all three measurement points.

Daytime sleepiness was assessed at T0 and T2 based on the Essener Questionnaire of Age and Sleepiness in the Elderly (EFAS) (Frohnhofen et al., Reference Frohnhofen, Bibl, Nickel and Popp2010). The EFAS assesses the extent of daytime sleepiness by proxy ratings. The total value ranges between 0 and 48. Higher values indicate higher daily sleepiness. A value ≥ three indicates a moderate daytime sleepiness (Frohnhofen et al., Reference Frohnhofen, Bibl, Nickel and Popp2010).

Self-rated sleep quality was measured at T0 and T2 with the Pittsburgh Sleep Quality Index (PSQI) (Buysse et al., Reference Buysse, Reynolds, Monk, Berman and Kupfer1988), which covers a range of 0–21 points, whereby ≥ five points indicate poor sleep quality. Self-assessment was supported by researchers to allow for self-assessment for as many people living with dementia as possible.

Actigraphy was applied to assess participants’ activity and sleep patterns at T0 and T2 for at least 3 three days between 6pm and 10am in 40 randomly selected participants (n = 20 (IG), n = 20 (CG), max. of five participants per nursing home). Due to significant feasibility problems in the application of the actigraphs in all nursing homes, actigraphy data were only available for a very small number of participants. Therefore, it was decided not to analyze the data.

Non-sleep-related secondary outcomes were participants’ agitation and quality of life, both observed by nursing staff. Agitated behavior was assessed at T0 and T2 using the German version of the Cohen-Mansfield Agitation Inventory. Total scores range from 29 to 203 with higher scores indicating increased agitated behavior (Cohen-Mansfield, Reference Cohen-Mansfield1991; Hülser, Reference Hülser2001). Quality of life was measured at T0 and T2 with the German version of the QUALIDEM 2.0 (Dichter et al., Reference Dichter, Ettema, Schwab, Meyer, Bartholomeyczik and Halek2016; Ettema et al., Reference Ettema, Dröes, de Lange, Mellenbergh and Ribbe2007). The QUALIDEM 2.0 consists of two successive versions for mild to severe (37 items) and very severe dementia (18 items). In order to compare the two groups with each other and to summarize the quality of life in a single value, a QUALIDEM total sum score was calculated and transformed to values between 0 and 100, (Dichter et al., Reference Dichter, Quasdorf, Schwab, Trutschel, Haastert, Riesner, Bartholomeyczik and Halek2015; Verbeek et al., Reference Verbeek, Zwakhalen, van Rossum, Ambergen, Kempen and Hamers2010) with higher scores indicating e a higher quality of life. The handling of missing values for each applied measure is described in Table S1.

Sociodemographic data (e.g. age, sex, and care dependency level) were collected from the available care documentation at T0. Accidental falls, application of physical restraints, and psychotropic medication (N05C, N05A, N05B, N06A) were extracted as safety outcomes at all three measurement points from nursing records or collected through self-developed forms applied in previous studies (Abraham et al., Reference Abraham, Kupfer, Behncke, Berger-Höger, Icks, Haastert, Meyer, Köpke and Möhler2019; Richter et al., Reference Richter, Berg, Langner, Meyer, Köpke, Balzer, Wolschon, Silies, Sönnichsen, Löscher, Haastert, Icks, Wolf and Fleischer2019).

Cost parameters on the expenses for intervention implementation were collected during and after the trial using structured protocols. Costs of the intervention’s delivery were computed based on current valid collective labor agreements for the involved scientific staff as well as nursing home staff. Material costs were calculated based on real costs.

We also collected data regarding nursing home staff-related outcomes and conducted a mixed-methods process evaluation (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021). These data will be presented elsewhere.

Randomization and blinding

Randomization lists, computer-generated by the independent external biostatistician, were used for allocation of clusters in blocks of two nursing homes. Randomization was stratified by region (study center): Lübeck, Halle (Saale), and Witten. An independent external administrative person performed allocation of clusters and informed cluster representatives about group assignment. Baseline assessment had been completed prior to randomization to minimize bias. Due to the type of intervention, it was not possible to blind nursing home staff and researchers carrying out the intervention and performing data collection. However, researchers entering the data into the database and the biostatistician were blinded to group allocation of clusters.

Sample size calculation

This study was planned to detect a group difference of at least two sleep problems in people living with dementia assessed with the SDI after 16 weeks. The prevalence at follow-up was expected to be 80% in the CG and 61% in the IG (absolute risk difference 19%). The sample size calculation was performed with the cluster-adjusted χ 2-test based on Donner and Klar (Reference Donner and Klar2000). An intra-cluster correlation coefficient (ICCC) of 0.05, a significance level of 5%, and an average cluster size of 15 people living with dementia was applied. In addition, a loss of 10% of study participants and no loss of clusters within 16 weeks was assumed to achieve a power of 84%. Based on these assumptions, the goal was to recruit 12 clusters and 180 people living with dementia for each group. Post-randomization recruitment in case of drop-outs of clusters or participants was not planned.

Data analysis

The statistical analysis was conducted using GCP standards and the intention-to-treat principle. Baseline characteristics of nursing homes and participants were described separately by IG and CG with frequency tables, means ± standard deviations, and percentiles. For the primary outcome, the prevalence of ≥ two sleep problems (measured using the SDI) was compared between the IG and CG using a two-sided cluster-adjusted χ 2-test (Donner and Klar, Reference Donner and Klar2000) including the difference and the odds ratio with cluster-adjusted 95% confidence intervals and the corresponding ICCC. Rates of participants who terminated the study at T2 for IG and CG were also compared by a cluster-adjusted χ 2-test.

Secondary endpoints were analyzed in their longitudinal course at time points T0, T1 (if available), and T2. Depending on the type of distribution (continuous/approximate normal or binary), group-specific means or prevalences and cluster-adjusted 95% confidence intervals were estimated at each time point, and ICCCs were calculated. Mixed linear or logistic models were fitted using the outcome as dependent variable, group, time, the interaction group*time, and the corresponding initial value as independent variables and homes as random effects for cluster adjustment. If T1 values were available, adjustment for repeated measurements was performed by covariance patterns (general structure). From these models, the mean differences or odds ratios comparing intervention and control groups and 95% confidence intervals were estimated as being adjusted for clustering and initial values including overall tests for group differences.

As there were no violations of the protocol, no per-protocol analysis was performed. According to the study protocol (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021), an adjustment for missing values was applied by analyzing the course of the outcomes using mixed models as described above. After the blinded review, because of the drop-out rate of approx. 17%, it was decided to conduct additional sensitivity analyses after imputing missing values by the last observation carried forward (LOCF) principle for primary and secondary outcomes. As both analyses do not principally change the results, we do not expect more valid information from a more complex and elaborate multiple imputation.

The two-sided significance level was α = 0.05. SAS Version 9.4 was used as statistical software.

Cost data on the expenses for the intervention’s implementation were calculated as the total amount for all intervention clusters.

Results

Participants

Twenty-four nursing homes participated with 242 people living with dementia at baseline (IG = 12 nursing homes with 126 participants; CG: 12 nursing homes with 116 participants). During follow-up, the number of clusters in the IG decreased (remaining n = 11 at T1, n = 10 at T2) while no cluster dropped out in the CG. For both clusters, nursing home managers stated that the impact of the SARS-CoV-2 pandemic led to the decision of early study termination. The number of participants decreased to n = 90 in the IG and n = 111 in the CG at T2. Rates of participants who terminated the study at T2 differed significantly between groups (IG: 28.6%; CG: 4.3%; p = 0.027). Overall, 41 participants terminated the study early due to death (n = 21), moving (n = 1) or cluster drop-out (n = 19, Fig. 1). Baseline characteristics of clusters and participants, including the prevalence of sleep problems, were comparable between study groups (Table 1).

Figure 1. Participant flow chart.

Table 1. Baseline characteristics of participating cluster and people living with dementia

Data are reported as means (±SD) or numbers (%) if not reported otherwise.

a Between 5 and 6 missing values per variable.

b As determined by expert raters of the medical service of the German statutory long-term care service.

Intervention effects

Results for the primary outcome, i.e. prevalence of sleep problems after 16 weeks (T2), are displayed in Table 2. At baseline, prevalences of sleep problems were comparable between groups: 89.5% in the IG vs 92.9% in the CG. After 16 weeks, the prevalence of sleep problems was significantly lower in the IG, 59.3%, vs 83.8% in the CG (difference: −24.5%; 95% CI: −46.3% – −2.7%; cluster-adjusted OR: 0.281; 95% CI: 0.087 – 0.909; p = 0.029; ICCC: 0.230).

Table 2. Intervention effect of the primary analysis of the primary outcome (prevalence of ≥ two sleep problems)

CG = control group; ICCC = intra-class correlation coefficient; IG = intervention group; SDI = sleep disorders inventory; 95% CI = 95% cluster-adjusted (Donner and Klar, Reference Donner and Klar2000) confidence Interval.

Results for further sleep-related outcomes were mostly comparable between groups, with a statistically significant difference between groups at T1 and T2 for the SDI scores in favor of the IG (Table 3).

Table 3. Intervention effect of sleep-related secondary outcomes based on mixed linear or logistic models

CG = control Group; ICCC = intra-class correlation coefficient; IG = intervention group; 95% CI = 95% cluster-adjusted (Donner and Klar, Reference Donner and Klar2000) confidence interval.

Due to the loss of the two clusters and of more residents than assumed (21% vs. 10%), we conducted a post hoc LOCF analysis. Results showed no significant differences with regard to the primary and most secondary endpoints, but the significant group differences with respect to the SDI score remained at T1 and T2 (Table S2).

For non-sleep-related outcomes, no significant group differences were detected (Table 4). Also, for safety outcomes, no significant group differences at any measurement point were found with one exception, the unexpected group difference in the prevalence of falls at follow-up after eight weeks in favor of the IG. However, after 16 weeks this difference was no longer present (Table 4).

Table 4. Intervention effects of further secondary outcomes

ATC classification = “anatomical therapeutic chemical” classification of drugs; CG = control Group; ICCC = intra-class correlation coefficient; IG = intervention group; 95% CI = 95% cluster-adjusted (Donner and Klar, Reference Donner and Klar2000) confidence interval.

Intervention implementation and costs

The intervention was predominantly implemented as planned. However, the process evaluation showed that for some components, the “dose delivered” differed from the initial plan, mainly due to the COVID-19 pandemic. Detailed results of the process evaluation will be published elsewhere.

Resource use due to the implementation of the intervention yielded total costs of 19,605.53$ (18,436.65 €) in the intervention group (Table S2).

Discussion

This cluster-randomized controlled study showed that the newly developed multi-component, non-pharmacological MoNoPol-Sleep intervention substantially reduced the prevalence of sleep problems in people living with dementia in nursing homes after 16 weeks. Moreover, the study demonstrated significant group differences at T1 and T2 regarding the SDI score as secondary outcome in favor of the IG. However, no differences between groups were found for other secondary outcomes, including daytime sleepiness, self-rated sleep quality, agitation, and quality of life. The interventions seem to be safe as for safety outcomes (accidental falls, physical restraints, and psychotropic medication) no meaningful group differences were detected.

The identified difference for the primary outcome with −24.5% (95% −46.3 – −2.7) is noticeably higher than the estimated -19%, although due to the smaller than expected number of participants, the 95% confidence interval is fairly broad.

Also, the statistically significant group difference concerning severity of sleep problems determined by SDI scores appears clinically relevant. The cluster-adjusted SDI score in the IG was reduced by an average of 10.2 points between baseline and follow-up after 16 weeks, compared to a reduction of one point in the CG. For the SDI, no standard values for interpretation of clinically important differences are available. However, the SDI is based on the Neuropsychiatric Inventory Nursing Home (NPI-NH, range 0–144 points), (Reuther et al., Reference Reuther, Dichter, Bartholomeyczik, Nordheim and Halek2016; Wood et al., Reference Wood, Cummings, Hsu, Barclay, Wheatley, Yarema and Schnelle2000) for which a relevant behavioral change is assumed at a difference of 11 points (Zuidema et al., Reference Zuidema, Buursema, Gerritsen, Oosterwal, Smits, Koopmans and de Jonghe2011).

However, these positive results may be influenced by an attrition bias. As mentioned above, two clusters dropped out of the IG during the study as a result of the COVID-19 pandemic. Considering the enormous burden in the course of the COVID-19 pandemic, it could be assumed that the remaining clusters in the IG were particularly motivated to participate in the study.

The post hoc LOCF analysis showed no significant differences with regard to the primary and most secondary endpoints, but the significant group differences with respect to the SDI score remained at T1 and T2. Thus, it cannot be ruled out that results are influenced at least partly by attrition of clusters and/or participants. In a future adequately powered cluster-randomized controlled study, the observed intervention effect should therefore be confirmed, including a sufficient number of clusters and participants and avoiding drop-out of clusters.

The positive study results principally confirm the results of previous multi-component studies, although due to the complexity of these studies, comparisons are challenging. The Cochrane review by Wilfling et al. Reference Wilfling, Hylla, Berg, Meyer, Köpke, Halek, Möhler and Dichter(2021) shows the heterogeneity of previous multi-component interventions and of outcomes used in these studies. Currently, there is only one other multi-component intervention based on the principles of person-centered care. This intervention showed an increased nighttime sleep based on actigraphy in a pre-post-controlled pilot study (Li et al., Reference Li, Grandner, Chang, Jungquist and Porock2017). The SDI has been used as an outcome measure in three further non-pharmacological studies (Hjetland et al., Reference Hjetland, Kolberg, Pallesen, Thun, Nordhus, Bjorvatn and Flo-Groeneboom2021; Kim et al., Reference Kim, Lee and Sohng2016; Petrovsky et al., Reference Petrovsky, Bradt, McPhillips, Sefcik, Gitlin and Hodgson2023) with one of these studies (Hjetland et al., Reference Hjetland, Kolberg, Pallesen, Thun, Nordhus, Bjorvatn and Flo-Groeneboom2021) showing a significant effect. However, this was related to the SDI score and not to the prevalence of sleeping problems. Although there is certainly a need for further research on suitable outcomes for sleep studies in nursing homes (Blytt et al., Reference Blytt, Bjorvatn, Husebo and Flo2017; Hjetland et al., Reference Hjetland, Kolberg, Pallesen, Thun, Nordhus, Bjorvatn and Flo-Groeneboom2021), the prevalence of at least two sleep problems seems to be a clinically relevant and specifically measurable outcome. Although arguably, this is a rather unspecific measure as it does not take into account severity and frequency of sleep problems, but offers an easy-to-assess dichotomous outcome. In the context of our study, measuring actigraphy on a subsample was not feasible, as the measurement protocol was frequently not adhered to by the nursing home staff. Non-adherence was explained by the special burden due to the COVID-19 pandemic and lack of support from the study staff. Also due to the pandemic, we were unable to directly support conduction of actigraphy in nursing homes. The advantage of “objective” sleep assessment using actigraphy is increasingly questioned in the literature (Blytt et al., Reference Blytt, Bjorvatn, Husebo and Flo2017; Hjetland et al., Reference Hjetland, Kolberg, Pallesen, Thun, Nordhus, Bjorvatn and Flo-Groeneboom2021), as actigraphy basically records activity and inactivity is than interpreted as sleep even if participants are awake, but just inactive. Accordingly, actigraphy has a high sensitivity in detecting sleep, but a low specificity compared to polysomnography (Van de Water et al., Reference Van de Water, Holmes and Hurley2011). In addition, it requires a defined rest interval for actigraphy data. However, this contradicts the individuality of sleep habits and sleep times. It is therefore easy to imagine that people living with dementia have individual preferences for sleep times, e.g. falling asleep in the second half of the night and sleeping into the morning, which contradicts a fixed sleep time window from 22:00 to 6:00 o’clock as chosen for this study. Further research on valid and objective sleep-related outcomes in the nursing home setting is required. Both technical solutions and standardized observations by trained and, as far as possible, blinded training staff should be considered.

The observed moderate daytime sleep periods in both groups could not be substantially influenced by the intervention. There still seems to be potential for further development of the intervention through additional intervention components aimed at reducing daytime sleepiness. The subsample of participants who self-assessed their sleep quality showed poor sleep quality based on the PSQI at baseline. This improved in the intervention group compared to the control group in the expected direction, although not significantly, probably due to the small size of the subsample. The lack of effects on agitation and quality of life seems comprehensible, as the intervention does not include any components specifically targeted at these outcomes. Still, as increased agitation and decreased quality of life have been described as consequences of sleep problems (Cipriani et al., Reference Cipriani, Lucetti, Danti and Nuti2015; Uchmanowicz et al., Reference Uchmanowicz, Markiewicz, Uchmanowicz, Koltuniuk and Rosinczuk2019; Webster et al., Reference Webster, Powell, Costafreda and Livingston2020b), a longer follow-up period might have been needed to show such effects.

Study strengths and limitations

A strength of the MoNoPo-Sleep study is the carefully developed complex intervention guided by the MRC framework (Craig et al., Reference Craig, Dieppe, Macintyre, Michie, Nazareth and Petticrew2013). The intervention required active engagement of nursing home staff in the intervention clusters, who developed, tailored, and implemented person-centered care for the individual promotion of residents’ sleep. Based on the intervention components, staff members were able to develop and implement person-centered micro-interventions for individual sleep promotion for residents. Moreover, the intervention enabled the development of an institutional sleep-promoting concept oriented on the individual situations in each nursing home.

The practicability of the study protocol and the feasibility of the intervention enabled 22 of 24 nursing homes to complete the study despite the COVID-19 pandemic. However, two nursing homes in the IG dropped out, and overall, the prevalence of sleep problems was lower than assumed. This resulted in a smaller sample size than planned, and the dropped-out clusters might have caused an attrition bias. The power was further reduced by the higher-than-expected ICCC (0.23 vs 0.05). Despite the reduced statistical power, the study was able to show a substantial effect with regard to the primary outcome. However, due to the sample size, the large confidence interval indicates considerable uncertainty. In order to produce meaningful results, the inclusion criterion for the presence of at least two sleep problems according to the SDI was adjusted to at least one sleep problem, in deviation from the study protocol. Thus, 21 additional participants could be included.

Due to the nature of the intervention, we were unable to blind nursing home staff, as well as study personnel (except the statistician). This means that nursing home staff members who were involved in the intervention also made the proxy assessments for the outcomes, causing potential detection bias.

The heterogeneous cluster sizes including small clusters (<10 residents) result in a less precise cluster adjustment. Due to the small sample sizes within clusters, we did not assess cluster variation in outcomes.

Based on the study design, no conclusions can be drawn about long-term effects of the intervention. This should be the aim of a future study.

The results of the accompanying process evaluation as well as for nursing staff outcomes (Dichter et al., Reference Dichter, Berg, Hylla, Eggers, Wilfling, Möhler, Haastert, Meyer, Halek and Köpke2021) will be published elsewhere and will provide important results on influencing and context factors of the intervention implementation.

Conclusions and implications

The MoNoPol-Sleep study demonstrated the effectiveness of a new complex non-pharmacological intervention regarding sleep problems in nursing home residents living with dementia after 16 weeks without adverse effects. The intervention effects presented here should be further investigated in future studies. Specific attention should be drawn to the selection of sleep-related outcomes. Currently, there is no gold standard for the assessment of sleep problems. Therefore, based on the literature and the experience from this study, we recommend the use of a method triangulation consisting of a self-assessment and a proxy assessment as well as the use of trained blinded observers. The use of technical aids such as actigraphy must be critically reflected. Specifically, the ability of the intervention to reduce daytime sleepiness should be examined.

In conclusion, nursing homes and nurses should reflect on the extent of sleep problems in their facility. If sleep problems exist, the implementation of the MoNoPol-sleep intervention could help to reduce sleep problems in residents living with dementia.

Conflict of interest

None.

Description of the authors’ roles

Study design: MND, JD, DW, AB, RM, GM, MH, SK.

Data collection: JD, DW, AB, TK.

Data analysis: MND, JD, BH, SK.

Data interpretation: MND, JD, DW, AB, TK, RM, BH, GM, MH, SK.

First draft of the manuscript: MND, BH, SK.

Final approval of the manuscript: MND, JD, DW, AB, TK, RM, BH, GM, MH, SK.

Acknowledgements

We thank the sleep nurses, nursing staff, and participating people living with dementia of 24 nursing homes and the members of the external advisory board as well as all experts who participated in the workshops for the development of the theory of change.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1041610223004489

References

Abraham, J., Kupfer, R., Behncke, A., Berger-Höger, B., Icks, A., Haastert, B., Meyer, G., Köpke, S., Möhler, R. (2019). Implementation of a multicomponent intervention to prevent physical restraints in nursing homes (IMPRINT): a pragmatic cluster randomized controlled trial. Internationl Journal of Nursing Studies, 96, 2734.CrossRefGoogle ScholarPubMed
Blytt, K. M., Bjorvatn, B., Husebo, B., & Flo, E. (2017). Clinically significant discrepancies between sleep problems assessed by standard clinical tools and actigraphy. BMC Geriatrics, 17(1), 253.CrossRefGoogle ScholarPubMed
Buysse, D. J., Reynolds, C. F., Monk, T. H., Berman, S. R., & Kupfer, D. J. (1988). The pittsburgh sleep quality index: a new instrument for psychiatric practice and research. Psychiatry Research, 28(2), 193213.CrossRefGoogle Scholar
Cipriani, G., Lucetti, C., Danti, S., & Nuti, A. (2015). Sleep disturbances and dementia. Psychogeriatrics, 15(1), 6574.CrossRefGoogle ScholarPubMed
Cohen-Mansfield, J. (1991). Instruction Manual for the Cohen-Mansfield Agitation Inventory (CMAI) Rockville. https://oregonbhi.org/wp-content/uploads/2020/01/CMAI_Manual.pdf Google Scholar
Craig, P., Dieppe, P., Macintyre, S., Michie, S., Nazareth, I., & Petticrew, M. (2013). Developing and evaluating complex interventions: the new medical research council guidance. International Journal of Nursing Studies, 50(5), 587592.CrossRefGoogle ScholarPubMed
Craig, P., Dieppe, P., Macintyre, S., Michie, S., Nazareth, I., Petticrew, M. (2008). Developing and evaluating complex interventions: the new medical research council guidance. BMJ, 337, a1655.CrossRefGoogle ScholarPubMed
Dichter, M. N., Berg, A., Hylla, J., Eggers, D., Wilfling, D., Möhler, R., Haastert, B., Meyer, G., Halek, M., Köpke, S. (2021). Evaluation of a multi-component, non-pharmacological intervention to prevent and reduce sleep disturbances in people with dementia living in nursing homes (MoNoPol-sleep): study protocol for a cluster-randomized exploratory trial. Bmc Geriatrics, 21(1), 40.CrossRefGoogle ScholarPubMed
Dichter, M. N., Ettema, T. P., Schwab, C. G. G., Meyer, G., Bartholomeyczik, S., & Halek, M. (2016). Benutzerhandbuch für die deutschsprachige QUALIDEM Version 2.0. Witten.Google Scholar
Dichter, M. N., Hylla, J., Berg, A., Wilfling, D. (2020). Entwicklung einer Theory of Change als Grundlage Einer Intervention zur Reduktion von Schlafproblemen bei Menschen mit Demenz in der stationären Altenpflege. [Development of a Theory of Change as Basis for a Intervention Aiming the Reduction of Sleep Problems of People With Dementia in Nursing Homes] (pp. 21). Jahrestagung des EbM Netzwerks 2020 Universität Basel.Google Scholar
Dichter, M. N., Quasdorf, T., Schwab, C. G.. C.;nter G., Trutschel, D., Haastert, B., Riesner, C., Bartholomeyczik, S., Halek, M. (2015). Dementia care mapping: effects on residents’ quality of life and challenging behavior in german nursing homes. A quasi-experimental trial. International Psychogeriatrics, 27(11), 18751892.CrossRefGoogle ScholarPubMed
Donner, A., & Klar, N. (2000). Design and Analysis of Cluster Randomization Trials in Health Research. Arnold.Google Scholar
Dörner, J., Hüsken, J. M., Schmüdderich, K., Dinand, C., Dichter, M. N., & Halek, M. (2023). Perspectives on sleep of people living with dementia in nursing homes: a qualitative interview study. Bmc Geriatrics, 23(1), 331.CrossRefGoogle ScholarPubMed
Ettema, T. P., Dröes, R. M., de Lange, J., Mellenbergh, G. J., & Ribbe, M. W. (2007). QUALIDEM: development and evaluation of a dementia specific quality of life instrument. Scalability, reliability and internal structure. Int J Geriatr Psychiatry, 22(6), 549556.CrossRefGoogle ScholarPubMed
Frohnhofen, H., Bibl, M., Nickel, B., & Popp, R. (2010). Der essener fragebogen alter und schläfrigkeit (EFAS) – ein neues assessmentinstrument zur Messung von Tagesschläfrigkeit bei alten menschen. [The Essen questionnaire on age and sleepiness – a new assessment tool to measure daytime sleepiness in elderly people]. European Journal of Geriatrics, 12, 8490.Google Scholar
Fung, C. H., Vitiello, M. V., Alessi, C. A., Kuchel, G. A., Committee, A. N. S. C. P., & Faculty (2016). Report and research agenda of the American geriatrics society and national institute on aging bedside-to-bench conference on sleep, circadian rhythms, and aging: new avenues for improving brain health, physical health, and functioning. J Am Geriatr Soc, 64, e238e247.CrossRefGoogle Scholar
Hjetland, G. J., Kolberg, E. Pallesen, S. Thun, E. Nordhus, I. H., Bjorvatn, B. Flo-Groeneboom, E. (2021). Ambient bright light treatment improved proxy-rated sleep but not sleep measured by actigraphy in nursing home patients with dementia: a placebo-controlled randomised trial. Bmc Geriatrics, 21, 312.CrossRefGoogle Scholar
Hjetland, G. J., Nordhus, I. H., Pallesen, Såle, Cummings, J., Tractenberg, R. E., Thun, E., Kolberg, E., Flo, E. (2020). An actigraphy-based validation study of the sleep disorder inventory in the nursing home. Front Psychiatry, 11, 173.CrossRefGoogle ScholarPubMed
Hülser, K. (2001). Diagnostic in the framework of quality development [Diagnostik im Rahmen der Qualitätssicherung]. Ruhr-Universität Bochum.Google Scholar
Janus, S. I., van Manen, J. G., I.J., M. J., & Zuidema, S. U. (2016). Psychotropic drug prescriptions in Western European nursing homes. International Psychogeriatrics, 28(11), 17751790.CrossRefGoogle ScholarPubMed
Kim, H. J., Lee, Y., & Sohng, K. Y. (2016). The effects of footbath on sleep among the older adults in nursing home: a quasi-experimental study. Complementary Therapies in Medicine, 26, 4046.CrossRefGoogle ScholarPubMed
Köhler, L., Weyerer, S., Schäufele, M. (2007). Proxy screening tools improve the recognition of dementia in old-age homes: results of a validation study. Age and Ageing, 36(5), 549554.CrossRefGoogle ScholarPubMed
Li, J., & Gooneratne, N. S. (2019). Sleep and Health in Older Adults (pp. 3143). Elsevier.Google Scholar
Li, J., Grandner, M. A., Chang, Y. P., Jungquist, C., & Porock, D. (2017). Person-centered dementia care and sleep in assisted living residents with dementia: a pilot study. Behavioral Sleep Medicine, 15(2), 97113.CrossRefGoogle ScholarPubMed
McCleery, J., & Sharpley, A. L. (2020). Pharmacotherapies for sleep disturbances in Alzheimer’s disease. Cochrane Database of Systematic Reviews, (11), CD009178. https://doi.org/10.1002/14651858.CD009178.pub4 Google Scholar
National Institute for Health and Care Excellence (2018). Dementia: Assessment, Management and Support for People Living with Dementia and Their Carers. https://www.nice.org.uk/guidance/ng97/resources/dementia-assessment-management-and-support-for-people-living-with-dementia-and-their-carers-pdf-1837760199109 Google Scholar
Neikrug, A. B., & Ancoli-Israel, S. (2010). Sleep disturbances in nursing homes. Journal of Nutrition Health & Aging, 14(3), 207211.CrossRefGoogle ScholarPubMed
Petrovsky, D. V., Bradt, J., McPhillips, M. V., Sefcik, J. S., Gitlin, L. N., & Hodgson, N. A. (2023). Tailored music listening in persons with dementia: a feasibility randomized clinical trial. American Journal of Alzheimer’s Disease & Other Dementias®, 38, 15333175231186728.CrossRefGoogle ScholarPubMed
Ramar, K., Malhotra, R. K., Carden, K. A., Martin, J. L., Abbasi-Feinberg, F., Aurora, R. N., Kapur, V. K., Olson, E. J., Rosen, C. L., Rowley, J. A., Shelgikar, A. V., Trotti, L. M. (2021). Sleep is essential to health: an American academy of sleep medicine position statement. Journal of Clinical Sleep Medicine, 17(10), 21152119.CrossRefGoogle ScholarPubMed
Reuther, S., Dichter, M. N., Bartholomeyczik, S., Nordheim, J., & Halek, M. (2016). Construct validity and internal consistency of the neuropsychiatric inventory - nursing home (NPI-NH) in German nursing homes. International Psychogeriatrics, 28(6), 10171027.CrossRefGoogle ScholarPubMed
Richter, C., Berg, A., Langner, H., Meyer, G., Köpke, S., Balzer, K., Wolschon, E.-M., Silies, K., Sönnichsen, A., Löscher, S., Haastert, B., Icks, A., Wolf, U., Fleischer, S. (2019). Effect of person-centred care on antipsychotic drug use in nursing homes (EPCentCare): a cluster-randomised controlled trial. Age and Ageing, 48(3), 419425.CrossRefGoogle ScholarPubMed
Suzuki, K., Miyamoto, M., & Hirata, K. (2017). Sleep disorders in the elderly: diagnosis and management. J Gen Fam Med, 18(2), 6171.CrossRefGoogle ScholarPubMed
Tractenberg, R. E., Singer, C. M., Cummings, J. L., & Thal, L. J. (2003). The sleep disorders inventory: an instrument for studies of sleep disturbance in persons with Alzheimer’s disease. Journal European Sleep Research Society, 12(4), 331337.CrossRefGoogle ScholarPubMed
Uchmanowicz, I., Markiewicz, K., Uchmanowicz, B., Koltuniuk, A., & Rosinczuk, J. (2019). The relationship between sleep disturbances and quality of life in elderly patients with hypertension. Clinical Interventions in Aging, 14, 155165.CrossRefGoogle ScholarPubMed
Van de Water, A. T., Holmes, A., & Hurley, D. A. (2011). Objective measurements of sleep for non-laboratory settings as alternatives to polysomnography--a systematic review. Journal of Sleep Research, 20(1pt2), 183200.CrossRefGoogle ScholarPubMed
Verbeek, H., Zwakhalen, S. M., van Rossum, E., Ambergen, T., Kempen, G. I., & Hamers, J. P. (2010). Dementia care redesigned: effects of small-scale living facilities on residents, their family caregivers, and staff. Journal of The American Medical Directors Association, 11(9), 662670.CrossRefGoogle ScholarPubMed
Webster, L., Costafreda Gonzalez, S., Stringer, A., Lineham, A., Budgett, J., Kyle, S., Barber, J., Livingston, G. (2020a). Measuring the prevalence of sleep disturbances in people with dementia living in care homes: a systematic review and meta-analysis. Sleep, 43(4), 1–14. https://doi.org/10.1093/sleep/zsz251 CrossRefGoogle Scholar
Webster, L., Powell, K., Costafreda, S. G., & Livingston, G. (2020b). The impact of sleep disturbances on care home residents with dementia: the SIESTA qualitative study. International Psychogeriatrics, 32(7), 839847.CrossRefGoogle ScholarPubMed
Wilfling, D., Berg, A., Dörner, J., Bartmann, N., Klatt, T., Meyer, G., Halek, M., Möhler, R., Köpke, S., Dichter, M. N. (2023a). Attitudes and knowledge of nurses working at night and sleep promotion in nursing home residents: multicenter cross-sectional survey. Bmc Geriatrics, 23(1), 206.CrossRefGoogle ScholarPubMed
Wilfling, D., Calo, S., Dichter, M. N., Meyer, G., Mohler, R., & Kopke, S. (2023b). Non-pharmacological interventions for sleep disturbances in people with dementia. Cochrane Database Syst Rev, 1(1), CD011881.Google ScholarPubMed
Wilfling, D., Dichter, M. N., Trutschel, D., & Kopke, S. (2019). Prevalence of sleep disturbances in German nursing home residents with dementia: a multicenter cross-sectional study. Journal of Alzheimers Disease, 69(1), 227236.CrossRefGoogle ScholarPubMed
Wilfling, D., Dichter, M. N., Trutschel, D., & Kopke, S. (2020). Nurses’ burden caused by sleep disturbances of nursing home residents with dementia: multicenter cross-sectional study. BMC Nurs, 19(1), 83.CrossRefGoogle ScholarPubMed
Wilfling, D., Hylla, J., Berg, A., Meyer, G., Köpke, S., Halek, M., Möhler, R., Dichter, M. N. (2021). Characteristics of multicomponent, nonpharmacological interventions to reduce or avoid sleep disturbances in nursing home residents: a systematic review. International Psychogeriatrics, 33(3), 245273.CrossRefGoogle ScholarPubMed
Wood, S., Cummings, J. L., Hsu, M.-A., Barclay, T., Wheatley, M. V., Yarema, K. T., Schnelle, J. F. (2000). The use of the neuropsychiatric inventory in nursing home residents. Characterization and measurement. Am J Geriatr Psychiatry, 8(1), 7583.CrossRefGoogle ScholarPubMed
Yesavage, J. A., Friedman, L., Ancoli-Israel, S., Bliwise, D., Singer, C., Vitiello, M. V., Monjan, A. A., Lebowitz, B. (2003). Development of diagnostic criteria for defining sleep disturbance in Alzheimer’s disease. J Geriatr Psychiatry Neurol, 16(3), 131139.CrossRefGoogle ScholarPubMed
Zhang, H., Li, Y., Zhao, X., Mao, Z., Abdulai, T., Liu, X., Tu, R., Wang, Y., Qian, X., Jiang, J., Tian, Z., Luo, Z., Dong, X., Wang, C., Bie, R. (2019). The association between PSQI score and hypertension in a Chinese rural population: the Henan rural cohort study. Sleep Medicine, 58, 2734.CrossRefGoogle Scholar
Zuidema, S. U., Buursema, A. L., Gerritsen, M. G. J. M., Oosterwal, K. C., Smits, M. M. M., Koopmans, R. T. C. M., de Jonghe, J. F. M. (2011). Assessing neuropsychiatric symptoms in nursing home patients with dementia: reliability and reliable change index of the neuropsychiatric inventory and the Cohen-mansfield agitation inventory. Int J Geriatr Psychiatry, 26(2), 127134.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Participant flow chart.

Figure 1

Table 1. Baseline characteristics of participating cluster and people living with dementia

Figure 2

Table 2. Intervention effect of the primary analysis of the primary outcome (prevalence of ≥ two sleep problems)

Figure 3

Table 3. Intervention effect of sleep-related secondary outcomes based on mixed linear or logistic models

Figure 4

Table 4. Intervention effects of further secondary outcomes

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