Authors
- Byun, Eeeseung PhD, RN
Abstract
Purpose: This study aimed to determine if brief psychosocial/behavioral therapy directed to reduce poststroke depression would decrease fatigue and improve sleep-wake disturbance.
Design: A preplanned secondary data analysis from a completed clinical trial was conducted.
Methods: One hundred participants received usual care, in-person intervention, or telephone intervention. Depression, fatigue, and sleep-wake disturbance were measured at entry, 8 weeks, 21 weeks, and 12 months following the intervention.
Findings: Fatigue (within: p = .042, between: p = .394), sleep disturbance (within: p = .024, between: p = .102), and wake disturbance (within: p = .004, between: p = .508) decreased over the 12 months in the intervention groups, but not in the control group. This difference was clinically meaningful for wake disturbance and approached the clinically important difference for fatigue.
Conclusions/Clinical Relevance: Reduction in wake disturbance was consistent with clinically meaningful difference standards for patient-reported outcomes, warranting further research in larger samples.
Article Content
Introduction
Living Well With Stroke 2 (LWWS2) was a randomized controlled trial to determine the effect of a telephone versus in-person brief psychosocial/behavioral therapy on poststroke depression, compared with usual care (Kirkness et al., 2017). After the conclusion of clinical trials of a nonpharmacological intervention in poststroke depression (Kirkness et al., 2017; Mitchell et al., 2009), we examined the data for secondary aims regarding fatigue and sleep (Kirkness et al., 2017). In this report, we describe the three sets of symptoms-fatigue, sleep disturbance, and wake disturbance-before and after treatment for depression.
Background
In the United States, approximately 795,000 new or recurrent strokes occur annually (Benjamin et al., 2019). Although the incidence of stroke has decreased in the United States to the fifth leading cause of death, it is still first or second in the most populous countries of the world (Feigin et al., 2014). Equally important, for those who survive, stroke is the leading cause of disability and lost productivity worldwide (Feigin et al., 2015). Furthermore, the impact of fatigue and sleep disturbance poststroke is not widely recognized (Brodtmann & van de Port, 2013).
Numerous systematic reviews have examined the prevalence of poststroke fatigue. Estimates range from 23% to 75% of people who have had a stroke report fatigue sufficient to interfere with normal activities (Cumming et al., 2016; Hinkle et al., 2017; Kutlubaev & Hackett, 2014; Lagogianni et al., 2018; Moran et al., 2013; Nadarajah & Goh, 2015; Whitehead et al., 2016). These estimates are confounded by varying definitions of fatigue, varying time points after the incidence of stroke when fatigue is measured, and varying measurements of fatigue. Several definitions of fatigue have been put forth in the stroke literature, only one of which is stroke specific (Lynch et al., 2007; Zedlitz et al., 2012). In creating a workable case definition of poststroke fatigue, Lynch and colleagues used a definition that incorporated "fatigue, lack of energy or increased need to rest every day or nearly every day" and that interfered with everyday activities (Lynch et al., 2007, p. 543). Although not stroke specific, Lerdal et al.'s (2012) definition helped separate fatigue from depression: "Sense of exhaustion, lack of perceived energy or tiredness, distinct from sadness or weakness" (p. 1).
Sleep disturbance following stroke is most commonly reported in terms of obstructive sleep apnea, with prevalence estimated as high as 60% in ischemic stroke patients (Johnson & Johnson, 2010; Menon et al., 2017). Estimates of the prevalence of poststroke sleep disturbance not attributed to obstructive sleep apnea are scarce. A recent systematic review of global literature indicated nonapnea sleep disturbances at 21.3%-70.6% in stroke survivors, whereas disorders of wakefulness (excessive daytime sleepiness) were cited ranging from 11.5% to 49.5% (Park & Choi-Kwon, 2018). In a more limited review, insomnia was estimated at a prevalence of 49%-68% in three studies, with insomnia related to worse quality of life (Tang et al., 2015). One Korean study showed low self-ratings for sleep problems following stroke (Kim et al., 2017).
Fatigue and sleep disturbance intertwine in depressive symptoms following stroke but are seldom reported separately in reviews of multiple symptoms (Baylor et al., 2014; Wang et al., 2016). Sleep disturbance, fatigue, and depression have been related to cognitive attention (Pearce et al., 2016), and these symptoms are target areas for intervention (Kouwenhoven et al., 2013; Nguyen et al., 2019). Sleep disturbance has been reported as a risk factor for stroke (Koo et al., 2018). In stroke, fatigue and sleep disturbance are closely related (Suh et al., 2014) and influence poststroke disability (Mandliya et al., 2016) and recovery (Hermann & Bassetti, 2016). Depression is also a strong predictor of sleep disturbance in stroke survivors (Suh et al., 2014). These findings suggest a tridirectional relationship among depression, fatigue, and sleep disturbance and that these symptoms may influence each other in this population.
The largest sample that examined all three distressing symptoms simultaneously used the Patient-Reported Outcome Measurement System (PROMIS) and the EuroQOL quality of life instruments to measure patient-reported outcomes in 1,195 stroke survivors (Katzan et al., 2018). Depression and sleep-wake impairment scores were worse for stroke survivors than for the general population, with sleep disturbance about the same (Katzan et al., 2018).
Aim of This Analysis
The primary results of this study, LWWS2, were previously published (Kirkness et al., 2017), and the prior LWWS1 study is included in meta-analyses of effective treatments (Deng et al., 2017). Based on prior research indicating that depression, fatigue, and sleep disturbance may occur separately or co-occur, this preplanned secondary analysis from the LWWS2 study was designed to determine if brief psychosocial/behavioral therapy aimed at poststroke depression might also improve fatigue and sleep-wake disturbance.
Methods
Summary of LWWS2 Design and Methods
The LWWS brief psychosocial intervention on depression was described previously (Kirkness et al., 2017; Mitchell et al., 2009); however, the methods are summarized here for clarity on the interaction of depression, fatigue, and sleep disturbance. The parent LWWS2 study (Kirkness et al., 2017) was conducted with the formal approval of the University of Washington Human Subjects Committee and registered as a clinical trial. Recruitment occurred from May 2010 to December 2014, and the trial ended in December 2015, when the last follow-up was completed. This preplanned secondary analysis examining the effect of brief psychosocial/behavioral therapy aimed at poststroke depression on fatigue and sleep-wake disturbance was part of the original analysis plan.
A total of 414 stroke survivors who were within 4 months of an ischemic or hemorrhagic stroke consented to be screened with demographics, the National Institutes of Health Stroke Scale (NIHSS), and the Geriatric Depression Scale (GDS). The GDS is commonly used in depression screening, regardless of age, because it is less sensitive to general physical illnesses than other depression screens (Sivrioglu et al., 2009). Higher scores on the GDS indicate greater severity of depression (0-9, normal; 10-19, mildly depressed; 20-30, severely depressed). In addition, stroke survivors received a two-item fatigue-screening assessment based on case definition by Lynch et al. (2007): "Since your stroke have you experienced fatigue, a lack of energy, or an increased need to rest every day or nearly every day? Has this fatigue led to difficulty taking part in everyday activities?" (p. 543).
All of those screened with clinically important depressive symptoms (GDS score of 11 or greater, indicating depression) were eligible to participate in the randomized trial of a brief behavioral intervention. Inclusion and exclusion criteria are described in Figure 1. A total of 133 participants met the inclusion criteria, and 100 community-dwelling stroke survivors consented to be randomized to a 6-week brief psychosocial-behavioral intervention by telephone, in person, or through usual care. Advanced practice nurses delivered a 1-hour intervention per week for 6 weeks either in person or by telephone over the course of six sessions. Participants in the telephone and in-person arms were taught,
[horizontal ellipsis]about the relationship of depression and stroke, that depressive symptoms are observable and modifiable behaviors and that these behaviors can be changed through observation and interaction. Participants were helped to identify activities that they found pleasant to do and to build these into their daily activities. Problem solving approaches were used to tailor this treatment to the circumstances of each participant and the challenges each faced in stroke recovery. (Kirkness et al., 2017, p. 4)
Participants in the usual-care group received an American Stroke Association booklet about stroke and depression and had their regular appointments with their primary provider. Antidepressant medication was recommended to all participants.
Clinical depression was confirmed with the Diagnostic Interview and Short Hamilton (Freedland et al., 2002). Randomization was adaptive with balance achieved on age, gender, severity of stroke, and severity of depression. Depression (the 17-item Hamilton Rating Scale for Depression [HRSD]), fatigue (the PROMIS seven-item scale), sleep disturbance (the PROMIS eight-item sleep scale), and wake disturbance (the PROMIS eight-item wake scale) were measured at entry, 8 weeks, 21 weeks, and 12 months posttreatment. The psychometrics of the depression measures were previously described (Kirkness et al., 2017; Mitchell et al., 2009). Next, we provide detail on the PROMIS measures.
The PROMIS system is one of the National Institutes of Health roadmap initiatives designed to improve the reporting of chronic condition outcomes in clinical research. The PROMIS provides a bank of standardized and validated items to assess key symptoms for a range of child and adult chronic conditions (Buysse et al., 2010; Cella et al., 2016). Short forms of seven to eight items were based on a set of calibrated items that quantify a particular symptom with standardization (T scores) referenced to the general population.
The severity and quality of fatigue was measured over the 12-month course of the study by the PROMIS short forms. The T scores represent a standardization of the raw sum scores, such that a score of 50 with a standard deviation of 10 indicates the average level of fatigue for the general adult population (Katzan et al., 2018).
The seven-item Fatigue Scale measures perceived tiredness, exhaustion, lack of energy, and impact on function in the past 7 days (Cook et al., 2012). The eight-item Sleep Disturbance Scale focuses on perceptions of quality, depth, and restoration associated with sleep, perceived difficulties getting to sleep or staying asleep, and perceptions of the adequacy of and satisfaction with sleep in the past 7 days (Buysse et al., 2010). The eight-item Sleep-Related Impairment Scale (wake disturbance) measures level of waking alertness, sleepiness, and function in the context of sleep-wake over the past 7 days (Buysse et al., 2010). The short forms for sleep and wake disturbance and for fatigue have been fully tested for psychometric stability and, in some cases, for what constitutes a clinically meaningful difference (Buysse et al., 2010; Cook et al., 2012; Katzan et al., 2018; Yost et al., 2011). Developers of the patient-reported outcome instruments have emphasized the need for a metric that make the scores interpretable from the patient point of view. The minimally important difference or minimal clinically important difference (MCID) has been defined as "a difference in score that is large enough to have implications for a patient's treatment or care" (Yost et al., 2011, pp. 507-508).
Statistical Analysis
In this analysis, we report descriptive data in frequencies with mean and median, as appropriate. Because the mean and median for T scores were very close to each other, we used the median to calculate MCID, which is increasingly considered most relevant for patient-reported outcomes. This difference in score is large enough to have implications for patient treatment or care (Angst et al., 2017; Jaeschke et al., 1989). The MCID for the seven-item fatigue T score is 3-5 points (Yost et al., 2011). No MCID has been firmly established for sleep measures; however, some authors have estimated MCID using 0.5 standard deviation for the T score (Bryant et al., 2018). Fatigue, sleep disturbance, and wake disturbance across usual care, by telephone, and in-person groups were also compared with inferential statistics, using repeated-measures analysis of variance. Statisticians and leading researchers are increasingly supporting less reliance on traditional levels of statistical "significance" and greater use of clinically interpretable measures of the importance of findings (Hayat et al., 2019). Correlational analysis among the T scores for sleep and wake disturbance and fatigue and HRSD total scores at all four time points were conducted.
Results
Screening Sample Fatigue and Depression
Fatigue and depression were evaluated for the 414 people who were screened for the intervention study, using the GDS, NIHSS, and the two-item fatigue screen. The screening tools contained no sleep questions. Demographics and relevant clinical features of those screened and those enrolled appear in Table 1. These are reported here to establish the comparability of the population to those reported in prior literature for symptom sequelae of stroke.
Of the 314 who were screened only and not entered in the trial, 76% were fatigued, with 52% of those fatigued enough to interfere with daily activities. Depression (GDS score of 11 or greater) was a factor in fatigue for those who entered the intervention (n = 100), with 96% of those reporting fatigue and 85% reporting severe fatigue. Of those with GDS of less than 11 (n = 314), 46% were severely fatigued, suggesting a prevalence independent of depression. This outcome is consistent with findings from the Nottingham Fatigue Without Depression Study (Hawkins et al., 2017).
Those who were screened only were somewhat older, on average, than those who entered the trial (mean of 66.4 years vs. 60.3 years), had a less severe stroke (NIHSS score of 2.5 vs. 3.4), and had more men than in the intervention group (63% vs. 50%). Other demographics and stroke characteristics were quite similar for those screened only and those enrolled in this study.
Depression, Fatigue, and Sleep Over Time in the Intervention Study
We were able to follow those with GDS scores of 11 or greater and who entered the main study with clinical depression (n = 100). The demographics and clinical characteristics of those participants at entry to the intervention study are also shown in Table 1. The groups were roughly 50% men and women, with an average age of 60 years. The majority were married and living with a spouse or partner. The majority were White. Up to 14% of participants reported more than one race. The mean NIHSS score was 3.4, indicating mild stroke, and 85% had ischemic stroke. The mean HRSD score was 18.5 (moderate depression). More than 70% had a personal history of depression prior to their stroke. When they entered in the trial, 47% of all participants were taking antidepressant medications, such as selective serotonin reuptake inhibitors, monoamine oxidase inhibitors, or tricyclic antidepressants. On average, participants across all three groups perceived themselves as 62% recovered from the stroke.
Of the participants in the intervention study, 96% experienced fatigue, with 85% of them fatigued enough to interfere with daily activities (screening fatigue item), 93% did not feel full of energy (GDS fatigue item), 41% reported moderate, and 59% reported severe fatigue on the HRSD fatigue severity item. These levels of fatigue did not differ across the three randomization groups at baseline.
Demographics and clinical characteristics were very similar across the two intervention groups and the usual care group (Table 2). As shown in Table 3, at entry to the study, all groups had an average fatigue PROMIS T score of ~56, with a standard deviation of 6.3 (median = 55-56). The participants with pleasant events, self-identified events that gave the participants pleasure (e.g., gardening, taking a walk, and viewing art), experienced a decrease in fatigue after the cognitive-behavioral intervention. However, the usual-care group continued at the same level of fatigue throughout the year of follow-up. The intervention groups had a greater decrease in fatigue, but the levels did not achieve the MCID of 3 points by 12 months posttreatment (Table 4), although the telephone intervention group reduced at the median level by nearly 3 points (2.7). The difference at 12 months did not reach a .05 level of significance with conventional inferential statistics (Table 3). No apparent differential perceptions of recovery emerged across groups (data not shown).
Sleep disturbance T scores decreased roughly by 2 points in the combined intervention groups and remained essentially constant in the usual-care group over time (Table 3). However, wake disturbance improved by more than 4 points in the intervention groups, suggesting an MCID, and worsened in the usual-care group (Table 4). Again, conventional inferential statistics did not show significance at the .05 level between intervention and control groups.
Because fatigue and sleep-wake disturbances are a component of the multiple symptoms that comprise clinical depression, it is possible that our findings simply reflect the reduction in overall depression found in our main study measured in another way. If so, we should expect to see a strong correlation between the T scores, as measured by PROMIS scales, and the overall depression score, as measured by the Hamilton Scale. Correlational analysis among the T scores for sleep and wake disturbance, fatigue, and HRSD total scores at all four time points showed only modest correlations at any point beyond entry (data not shown). Another approach might have been to do mediation and moderation analysis with Hamilton changes as it affected sleep, wake, and fatigue scores. However, these analyses presuppose a statistically significant difference in the depression score, which was not the case.
Discussion
Findings indicate that fatigue, sleep disturbance, and wake disturbance are prevalent over the 12 months after stroke. Our brief psychosocial/behavioral therapy for poststroke depression decreased fatigue, sleep disturbance, and wake disturbance over time. The improvement in wake disturbance from the baseline and 12 months suggests an MCID.
The few studies that reported fatigue over time poststroke indicated either an increase in fatigue (measured by the Fatigue Severity Scale) during the first year or a small decrease after 1 year (Naess et al., 2012). The stability in our usual-care control group was similar to Lerdal et al. (2012), who also used the Fatigue Severity Scale and found no substantial variation over 18 months in severity of fatigue poststroke. Duncan et al. (2015) reported a decreasing number of poststroke patients who met the case definition of fatigue over a 1-year period; however, Duncan et al. did not measure severity of fatigue.
A few recent reports have described improvement in fatigue with targeted cognitive-behavioral therapy, which has many similarities to the intervention we used. Zedlitz et al. (2012) showed improvement in fatigue with a 12-week cognitive therapy program linked to focused activity. Their treatment included people up to 3 years poststroke. Similarly, Nguyen et al. (2019) reported similar improvements with a cognitive-behavioral intervention for poststroke fatigue and sleep disturbance. A very small feasibility study with a cognitive-behavioral intervention for poststroke insomnia also showed improvement in sleep and daytime sleepiness (Herron et al., 2018). Thus, our findings suggest that a brief psychosocial behavioral intervention for depression may also improve symptoms of fatigue and sleep-related impairment in some cases in MCID.
Strengths and Limitations
This study has limitations in that, even though preplanned, it is a secondary analysis of symptoms embedded in but not targeted by the primary intervention. It has a small sample size taken from one geographic region. It is also possible that improvement in fatigue, sleep disturbance, and wake disturbance over time may have been mediated or moderated by improved depression after the intervention, or vice versa. However, because the sleep and fatigue severity items in the Hamilton comprised only 2 of 17 items and because correlations in scores were quite low, this seems unlikely.
Strengths include a longitudinal design and measurement of these distressing symptoms over a 12-month period in the first year poststroke. Furthermore, the standardized patient-reported outcome measures allow direct comparison with other studies using PROMIS measures. Wake disturbance improved in the intervention groups, indicating an MCID. The use of MCID provides a clinically meaningful alternative to traditional statistical significance.
Implications for Clinical Practice and Future Research
The prevalence of fatigue, sleep disturbance, and wake disturbance underscore a need for provider sensitivity to recognize fatigue and sleep disturbance in stroke survivors, as well as the umbrella condition of depression. These symptoms may impede stroke survivors' ability to manage stroke care, such as rehabilitation, which could lead to rehospitalization. Rehabilitation nurses need to assess fatigue, sleep-wake disturbance, and depression early after stroke and provide support for stroke survivors. Targeted interventions focusing on fatigue, sleep-wake disturbance, and depression, such as cognitive-behavioral intervention (Herron et al., 2018; Nguyen et al., 2019; Zedlitz et al., 2012) and psychoeducation (Ostwald et al., 2014), may improve not only these symptoms but also stroke recovery. In a clinical trial, a nurse-led cognitive-behavioral intervention reduced cancer-related fatigue in persons with ovarian cancer during and after chemotherapy (Zhang et al., 2018). Rehabilitation nurses could play a pivotal role in providing interventions targeting fatigue, sleep, and depression for stroke survivors and improving their health. The suggested improvement of fatigue and some sleep-related symptoms with psychosocial-behavioral interventions indicate a need to replicate this study with a larger sample size and longitudinal designs that encompass longer periods. These findings suggest that interventions focused on fatigue and sleep and wake disturbances early following stroke may have the potential to prevent negative longer term health outcomes.
Conflict of Interest
The authors had National Institutes of Health funding related to the topic of this article but do not have any conflict of interest with respect to this analysis.
Funding
The clinical trial was funded by a grant from the National Institute of Nursing Research, National Institutes of Health (R01NR007755), to Catherine J. Kirkness and Pamela H. Mitchell (multiple principal investigators). Eeeseung Byun is currently funded by the National Institute of Nursing Research, National Institutes of Health (K23NR017404). Clinical Trial Registration: URL: https:/register.clinicaltrials.gov; unique identifier: NCT1133106; registered 5/26/2010.
Some data regarding fatigue and sleep were reported at the Council for the Advancement of Nursing Science State of the Science Meeting, Washington DC, September 2014 and the American Stroke Association International Stroke Conference, Los Angeles, CA, January 2018.
Key Practice Points
* Fatigue, sleep disturbance, and wake disturbance are prevalent over the 12 months poststroke.
* Brief psychosocial/behavioral therapy for poststroke depression may decrease fatigue, sleep disturbance, and wake disturbance.
* Targeted interventions focusing on fatigue, sleep and depression may improve these symptoms as well as stroke recovery, and rehabilitation nurses could play a pivotal role in providing these interventions.
References
Angst F., Aeschlimann A., Angst J. (2017). The minimal clinically important difference raised the significance of outcome effects above the statistical level, with methodological implications for future studies. Journal Clinical Epidemiology, 82, 128-136. [Context Link]
Baylor C., Yorkston K. M., Jensen M. P., Truitt A. R., Molton I. R. (2014). Scoping review of common secondary conditions after stroke and their associations with age and time post stroke. Topics in Stroke Rehabilitation, 21(5), 371-382. [Context Link]
Benjamin E. J., Muntner P., Alonso A., Bittencourt M. S., Callaway C. W., Carson A. P., Chamberlain A. M., Chang A. R., Cheng S., Das S. R., Delling F. N., Djousse L., Elkind M. S. V., Ferguson J. F., Fornage M., Jordan L. C., Khan S. S., Kissela B. M., Knutson K. L.American Heart Association Council on Epidemiology and Prevention Statistics Committee and Stroke Statistics Subcommittee. (2019). Heart disease and stroke statistics-2019 Update: A report from the American Heart Association. Circulation, 139(10), e56-e528. [Context Link]
Brodtmann A., van de Port I. G. L. (2013). Fitness, depression, and poststroke fatigue: Worn out or weary?Neurology, 81(18), 1566-1567. [Context Link]
Bryant A. L., Deal A. M., Battaglini C. L., Phillips B., Pergolotti M., Coffman E., Foster M. C., Wood W. A., Bailey C., Hackney A. C., Mayer D. K., Muss H. B., Reeve B. B. (2018). The effects of exercise on patient-reported outcomes and performance-based physical function in adults with acute leukemia undergoing induction therapy: Exercise and quality of life in acute leukemia (EQUAL). Integrative Cancer Therapies, 17(2), 263-270. [Context Link]
Buysse D. J., Yu L., Moul D. E., Germain A., Stover A., Dodds N. E., Johnston K. L., Shablesky-Cade M. A., Pilkonis P. A. (2010). Development and validation of patient-reported outcome measures for sleep disturbance and sleep-related impairments. Sleep, 33(6), 781-792. [Context Link]
Cella D., Lai J.-S., Jensen S. E., Christodoulou C., Junghaenel D. U., Reeve B. B., Stone A. A. (2016). PROMIS fatigue item bank had clinical validity across diverse chronic conditions. Journal Clinical Epidemiology, 73, 128-134. [Context Link]
Cook K. F., Bamer A. M., Roddey T. S., Kraft G. H., Kim J., Amtmann D. (2012). A PROMIS fatigue short form for use by individuals who have multiple sclerosis. Quality of Life Research, 21(6), 1021-1030. [Context Link]
Cumming T. B., Packer M., Kramer S. F., English C. (2016). The prevalence of fatigue after stroke: A systematic review and meta-analysis. International Journal of Stroke, 11(9), 968-977. [Context Link]
Deng L., Sun X., Qiu S., Xiong Y., Li Y., Wang L., Wei Q., Wang D., Liu M. (2017). Interventions for management of poststroke depression: A Bayesian network meta-analysis of 23 randomized controlled trials. Scientific Reports, 7(1), 16466. [Context Link]
Duncan F., Lewis S. J., Greig C. A., Dennis M. S., Sharpe M., MacLullich A. M. J., Mead G. E. (2015). Exploratory longitudinal cohort study of associations of fatigue after stroke. Stroke, 46(4), 1052-1058. [Context Link]
Feigin V. L., Forouzanfar M. H., Krishnamurthi R., Mensah G. A., Connor M., Bennett D. A., Moran A. E., Sacco R. L., Anderson L., Truelsen T., O'Donnell M., Venketasubramanian N., Barker-Collo S., Lawes C. M., Wang W., Shinohara Y., Witt E., Ezzati M., Naghavi M.the GBD Stroke Experts Group. (2014). Global and regional burden of stroke during 1990-2010: Findings from the Global Burden of Disease Study 2010. Lancet, 383(9913), 245-254. [Context Link]
Feigin V. L., Krishnamurthi R. V., Parmar P., Norrving B., Mensah G. A., Bennett D. A., Barker-Collo S., Moran A. E., Sacco R. L., Truelsen T., Davis S., Pandian J. D., Naghavi M., Forouzanfar M. H., Nguyen G., Johnson C. O., Vos T., Meretoja A., Murray C. J.GBD 2013 Stroke Panel Experts Group. (2015). Update on the global burden of ischemic and hemorrhagic stroke in 1990-2013: The GBD 2013 Study. Neuroepidemiology, 45(3), 161-176. [Context Link]
Freedland K. E., Skala J. A., Carney R. M., Raczynski J. M., Taylor C. B., Mendes De Leon C. F., Ironson G., Youngblood M. E., Krishnan K. R. R., Veith R. C. (2002). The Depression Interview and Structured Hamilton (DISH): Rationale, development, characteristics, and clinical validity. Psychosomatic Medicine, 64(6), 897-905. [Context Link]
Hawkins L., Lincoln N. B., Sprigg N., Ward N. S., Mistri A., Tyrrell P., Worthington E., Drummond A. (2017). The Nottingham Fatigue After Stroke (NotFAST) Study: Results from follow-up six months after stroke. Topics in Stroke Rehabilitation, 24(8), 592-596. [Context Link]
Hayat M. J., Staggs V. S., Schwartz T. A., Higgins M., Azuero A., Budhathoki C., Chandrasekhar R., Cook P., Cramer E., Dietrich M. S., Garnier-Villarreal M., Hanlon A., He J., Hu J., Kim M. J., Mueller M., Nolan J. R., Perkhounkova Y., Rothers J., Ye S. (2019). Moving nursing beyond p < .05. Nursing Outlook, 67(5), 509-510. [Context Link]
Hermann D. M., Bassetti C. L. (2016). Role of sleep-disordered breathing and sleep-wake disturbances for stroke and stroke recovery. Neurology, 87(13), 1407-1416. [Context Link]
Herron K., Farquharson L., Wroe A., Sterr A. (2018). Development and evaluation of a cognitive behavioural intervention for chronic poststroke insomnia. Behavioural and Cognitive Psychotherapies, 46(6), 641-660. [Context Link]
Hinkle J. L., Becker K. J., Kim J. S., Choi-Kwon S., Saban K. L., McNair N., Mead G. E.American Heart Association Council on Cardiovascular and Stroke Nursing and Stroke Council. (2017). Poststroke fatigue: Emerging evidence and approaches to management: A scientific statement for healthcare professionals from the American Heart Association. Stroke, 48(7), e159-e170. [Context Link]
Jaeschke R., Singer J., Guyatt G. H. (1989). Measurement of health status. Ascertaining the minimal clinically important difference. Controlled Clinical Trials, 10(4), 407-415. [Context Link]
Johnson K. G., Johnson D. C. (2010). Frequency of sleep apnea in stroke and TIA patients: A meta-analysis. Journal of Clinical Sleep Medicine, 6(2), 131-137. [Context Link]
Katzan I. L., Thompson N. R., Uchino K., Lapin B. (2018). The most affected health domains after ischemic stroke. Neurology, 90(16), e1364-e1371. [Context Link]
Kim B.-R., Lee J., Sohn M. K., Kim D. Y., Lee S.-G., Shin Y. I., Oh G.-J., Lee Y.-S., Joo M. C., Han E. Y., Kim Y. H. (2017). Risk factors and functional impact of medical complications in stroke. Annals of Rehabilitation Medicine, 41(5), 753-760. [Context Link]
Kirkness C. J., Cain K. C., Becker K. J., Tirschwell D. L., Buzaitis A. M., Weisman P. L., McKenzie S., Teri L., Kohen R., Veith R. C., Mitchell P. H. (2017). Randomized trial of telephone versus in-person delivery of a brief psychosocial intervention in poststroke depression. BMC Research Notes, 10(1), 500. [Context Link]
Koo D. L., Nam H., Thomas R. J., Yun C. H. (2018). Sleep disturbances as a risk factor for stroke. Journal of Stroke, 20(1), 12-32. [Context Link]
Kouwenhoven S. E., Gay C. L., Bakken L. N., Lerdal A. (2013). Depressive symptoms in acute stroke: A cross-sectional study of their association with sociodemographics and clinical factors. Neuropsychological Rehabilitation, 23(5), 658-677. [Context Link]
Kutlubaev M. A., Hackett M. L. (2014). Part II: Predictors of depression after stroke and impact of depression on stroke outcome: An updated systematic review of observational studies. International Journal of Stroke, 9(8), 1026-1036. [Context Link]
Lagogianni C., Thomas S., Lincoln N. (2018). Examining the relationship between fatigue and cognition after stroke: A systematic review. Neuropsychological Rehabilitation, 28(1), 57-116. [Context Link]
Lerdal A., Lee K. A., Bakken L. N., Finset A., Kim H. S. (2012). The course of fatigue during the first 18 months after first-ever stroke: A longitudinal study. Stroke Research and Treatment, 2012: 126275. [Context Link]
Lynch J., Mead G., Greig C., Young A., Lewis S., Sharpe M. (2007). Fatigue after stroke: The development and evaluation of a case definition. Journal of Psychosomatic Research, 63(5), 539-544. [Context Link]
Mandliya A., Das A., Unnikrishnan J. P., Amal M. G., Sarma P. S., Sylaja P. N. (2016). Post-stroke fatigue is an independent predictor of poststroke disability and burden of care: A path analysis study. Topics in Stroke Rehabilitation, 23(1), 1-7. [Context Link]
Menon D., Sukumaran S., Varma R., Radhakrishnan A. (2017). Impact of obstructive sleep apnea on neurological recovery after ischemic stroke: A prospective study. Acta Neurological Scandinavica, 136(5), 419-426. [Context Link]
Mitchell P. H., Veith R. C., Becker K. J., Buzaitis A., Cain K. C., Fruin M., Tirschwell D., Teri L. (2009). Brief psychosocial-behavioral intervention with antidepressant reduces poststroke depression significantly more than usual care with antidepressant. Living Well With Stroke: Randomized, controlled trial. Stroke, 40(9), 3073-3078. [Context Link]
Moran G. M., Fletcher B., Calvert M., Feltham M. G., Sackley C., Marshall T. (2013). A systematic review investigating fatigue, psychological and cognitive impairment following TIA and minor stroke: Protocol paper. Systematic Reviews, 2, 72. [Context Link]
Nadarajah M., Goh H. T. (2015). Post-stroke fatigue: A review on prevalence, correlates, measurement, and management. Topics in Stroke Rehabilitation, 22(3), 208-220. [Context Link]
Naess H., Lunde L., Brogger J. (2012). The effects of fatigue, pain, and depression on quality of life in ischemic stroke patients: The Bergen Stroke Study. Vascular Health and Risk Management, 8, 407-413. [Context Link]
Nguyen S., Wong D., McKay A., Rajaratnam S. M. W., Spitz G., Williams G., Mansfield D., Ponsford J. L. (2019). Cognitive behavioural therapy for poststroke fatigue and sleep disturbance: A pilot randomised controlled trial with blind assessment. Neuropsychological Rehabilitation, 29(5), 723-738. [Context Link]
Ostwald S. K., Godwin K. M., Cron S. G., Kelley C. P., Hersch G., Davis S. (2014). Home-based psychoeducational and mailed information programs for stroke-caregiving dyads post-discharge: A randomized trial. Disability and Rehabilitation, 36(1), 55-62. [Context Link]
Park D. I., Choi-Kwon S. (2018). Poststroke sleep disorders: An executive summary. Journal Neuroscience Nursing, 50(6), 314-317. [Context Link]
Pearce S. C., Stolwyk R. J., New P. W., Anderson C. (2016). Sleep disturbance and deficits of sustained attention following stroke. Journal of Clinical Experimental Neuropsychology, 38(1), 1-11. [Context Link]
Sivrioglu E. Y., Sivrioglu K., Ertan T., Ertan F. S., Cankurtaran E., Aki O., Uluduz D., Ince B., Kirli S. (2009). Reliability and validity of the Geriatric Depression Scale in detection of poststroke minor depression. Journal of Clinical Experimental Neuropsychology, 31(8), 999-1006. [Context Link]
Suh M., Choi-Kwon S., Kim J. S. (2014). Sleep disturbances after cerebral infarction: Role of depression and fatigue. Journal of Stroke and Cerebrovascular Disease, 23(7), 1949-1955. [Context Link]
Tang W. K., Grace Lau C., Mok V., Ungvari G. S., Wong K. S. (2015). Insomnia and health-related quality of life in stroke. Topics in Stroke Rehabilitation, 22(3), 201-207. [Context Link]
Wang L., Tao Y., Chen Y., Wang H., Zhou H., Fu X. (2016). Association of post stroke depression with social factors, insomnia, and neurological status in Chinese elderly population. Neurological Sciences, 37(8), 1305-1310. [Context Link]
Whitehead L. C., Unahi K., Burrell B., Crowe M. T. (2016). The experience of fatigue across long-term conditions: A qualitative meta-synthesis. Journal of Pain and Symptom Management, 52(1), 131-143.e1. [Context Link]
Yost K. J., Eton D. T., Garcia S. F., Cella D. (2011). Minimally important differences were estimated for six patient-reported outcomes measurement information system-cancer scales in advanced-stage cancer patients. Journal Clinical Epidemiology, 64(5), 507-516. [Context Link]
Zedlitz A. M. E. E., Rietveld T. C. M., Geurts A. C., Fasotti L. (2012). Cognitive and graded activity training can alleviate persistent fatigue after stroke: A randomized, controlled trial. Stroke, 43(4), 1046-1051. [Context Link]
Zhang Q., Li F., Zhang H., Yu X., Cong Y. (2018). Effects of nurse-led home-based exercise & cognitive behavioral therapy on reducing cancer-related fatigue in patients with ovarian cancer during and after chemotherapy: A randomized controlled trial. International Journal of Nursing Studies, 78, 52-60. [Context Link]