Associations between excessive fatigue and pain, sleep, mental-health and work factors in Norwegian nurses

One way to define fatigue is, “The awareness of a decreased capacity for physical and/or mental activity due to an imbalance in the availability, utilization, and or restoration of resources needed to perform activity,” [1]. However, fatigue’s definition is not clearly agreed upon due to its complex and multidimensional nature [2]. Models of fatigue are many and vary from the neuromuscular [3] to biomathematical predictive models [4]. Fatigue may have physical/muscular [5] and/or mental components [6]. It may be acute or chronic [7], or warrant the diagnosis chronic fatigue syndrome [8]. In real world situations, it may be difficult to parse physical and mental fatigue, therefore for the purposes of this paper we examine fatigue using both physical and mental components together.

Fatigue has been listed as the number one condition associated with productivity loss at work and the third most costly when considering medical, drug and productivity costs together [9]. Fatigue’s estimated productivity loss costs $136.4 billion annually in the U.S. [10]. It is a common condition, reported by as many as one in five individuals [11] and one in four patients [12]. In a general adult population sample in Norway, fatigue was the most frequently reported symptom, 59.7% of participants reported some type of fatigue [13]. Worldwide, there is a 10% prevalence of chronic fatigue and a 1% prevalence of chronic fatigue syndrome [14].

Nursing shortages have long been a problem and have been referred to as a global crisis since 2002 [15]. As of 2018 there was an estimated shortfall of 5.9 million nurses worldwide, and a high proportion of nurses nearing retirement further threatens nursing workforce numbers [16]. It is thus vital to identify actionable and modifiable factors related to fatigue in nurses, as these can inform preventive and other measures to retain nurses.

Myriad factors associate with fatigue, but not all the relationships are fully understood. It is fairly well-documented that women have an increased risk of fatigue compared to men [17–21]. However, there are examples of studies that found no significant association between sex and excessive/pathological fatigue [22, 23]. Research on the relationship between fatigue and age is also inconsistent. It has been reported that older age is associated with greater fatigue [24, 25], that there is no statistically significant association [20, 22, 23] or that there is lower general and/or mental fatigue in older individuals [17–19]. A Danish study indicates that the risk of general fatigue significantly decreases as age increases for healthy adults, but that an inverse relationship exists for those with somatic disease [26].

Pain associates with fatigue in conditions like lupus [27], cancer [28] and arthritis [29], but research on its association with fatigue in general/working populations is limited and demands further exploration. A Dutch community study [30] and a study on Iranian office workers [31] both indicated associations between fatigue and pain. A Brazilian study, however, found no significant association between fatigue and musculoskeletal discomfort [32].

Persistent fatigue has been reported in 37% of community individuals with chronic regional pain compared to 47% - 64% of those with chronic widespread pain [30]. Therefore, clear associations between fatigue and pain in multiple regions together are potentially more likely than pain in individual regions. However, it is possible that pain in some regions may contribute to fatigue more than pain in others and identifying those regions may be of use for future interventions. Thus, measuring both pain by region and as a composite may be of use.

Sleep deprivation [33], poor sleep quality [17, 18, 34], insomnia and a wide range of other sleep disorders [35] are associated with fatigue. There may also be a relationship between excessive sleepiness and fatigue, although that is less clear. In a Canadian study on sleep-disordered patients, the majority of those with sleepiness also reported fatigue, whereas the majority of those with pathological fatigue did not report sleepiness [36]. Whereas, in a U.S study, daytime sleepiness in nurses was significantly associated with occupational fatigue [17]. Further, shift work disorder (SWD, a sleep disorder related to one’s work schedule that is characterized by sleepiness and insomnia) correlated positively with fatigue in crude but not adjusted analyses [37].

Depression and anxiety [38, 39] clearly associate with fatigue. Workplace factors that correlate with fatigue or chronic fatigue include quick returns (<11h between shifts) [22, 23, 40, 41], night work [40, 42] and shift work [21, 43].

The relationships between fatigue and pain, sleep factors, mental health and work-related factors may be complicated by the relationships these factors have with each other. For example, pain has also been associated with insomnia [44, 45], excessive sleepiness [44] and quick returns [45]. And, in a study on sick leave for chronic back pain, those reporting substantial fatigue had both higher intensity of pain and more symptoms of depression than those without substantial fatigue [46]. Pain, anxiety and depression, sleep factors and work factors are thus entwined in a complex web but are still often studied as discrete/incomplete entities. Even in a recent comprehensive paper on occupational fatigue that includes personal and work factors [17], depression, anxiety, insomnia and quick returns are not investigated despite findings showing that all these factors may explain or exacerbate fatigue in nurses. It is therefore of importance to determine if pain, sleep/sleep-disorders, mental-health and work variables associate with fatigue when they are controlled for the presence of each other as well as demographic factors.

The present study aims to determine the associations between excessive fatigue and pain, sleep factors, mental health, and work-related factors after adjusting for all variables in the model. To our knowledge this is the first study examining all these variables together in a working population. Our hypotheses were as follows: Compared to their counterparts; Nurses with greater pain severity will more likely have excessive fatigue (H1), nurses with sleep problems will more likely have excessive fatigue (H2), nurses with high levels of anxiety and depressive symptoms will more likely have excessive fatigue (H3), nurses with shift work, night work and quick returns will more likely have excessive fatigue (H4).

Nurses were between 31 and 69 years, mean age was 41.6 (SD = 8.2) years. The study sample included 1,202 women (90.4%) and 128 men (9.6%) (5 nurses had missing data on sex). This cohort worked on average 34.1 (SD = 6.2) hours per week. Descriptive statistics are presented in Table 1.

Table 2 illustrates the nurses’ health status. In total, 35.4% of the nurses reported excessive fatigue. Percentages of nurses reporting pain by body region ranged from 27% (stomach) to 70.7% (neck/shoulder/upper back), with only 7.1% of nurses reporting no pain at all. The majority (90%) slept 6–8 hours each night, the group on average slept 6.8 (SD = 0.8) hours per night. About one third of the group (30.9%) reported insomnia, 25.6% reported excessive sleepiness, 25.2% reported anxiety, 10.7% reported depression and 33.6% were categorized as having SWD.

The prevalence of excessive fatigue varied by age group in Chi-square analysis (p = 0.03) and was highest in nurses aged 50–59 years (Table 3). Prevalence of excessive fatigue was higher for nurses with pain in all pain groups, as well as nurses with sleep duration <6 hours, insomnia, excessive sleepiness, anxiety and depression. Differences between groups were statistically significant.

In the crude logistic regression analyses (Table 4) pain, sleep duration <6h, insomnia (including total insomnia score), sleepiness (both excessive sleepiness and total sleepiness score), anxiety (including total anxiety score), depression (including total depression score), SWD and number of quick returns in the past year were significantly associated with excessive fatigue, whereas demographics (age, sex, having kids at home, and average hours worked per week) and the remaining work variables (shift work, working nights and categorical quick returns) were not. Pain by body region scores had ORs for excessive fatigue ranging from 1.16 for neck (95% CI 1.12–1.20) and lower back (95% CI 1.11–1.20) regions to 1.31 (95% CI 1.23–1.40) for headache/migraine. The odds ratio for excessive fatigue was 1.66 (95% CI 1.53–1.80) for the MSI score. Nurses with sleep duration <6h, compared to nurses with normal sleep (6-8h), and nurses with insomnia, compared to those without insomnia, had more than three times the odds of excessive fatigue compared to their reference group (OR = 3.52, 95% CI 2.29–5.42, and OR = 3.32, 95% CI 2.60–4.24, respectively). Notably, nurses with anxiety had 4.88 times (95% CI 3.74–6.37) and nurses with depression 8.23 times (95% CI 5.39–12.57) the odds of reporting excessive fatigue. Nurses with SWD had a more than two-fold increased odds (OR = 2.21, 95% CI 1.74–2.80) of excessive fatigue.

All statistically significant findings from the crude analyses remained (pain, sleep duration <6h, insomnia, sleepiness, anxiety, depression, SWD and number of quick returns in the past year) when adjusting for age, sex, children at home, and average hours worked per week (Table 4, Model 1). When also adjusting for all continuous variables, sleep duration (categorical) and demographics, neck/shoulder/upper back, lower back and stomach pain severity scores were no longer significant, but arm/wrist/hand, hip/leg/knee/foot, headache/migraine pain severity remained statistically significant (Table 4, Model 2). Headache/migraine still had the highest OR for excessive fatigue of the pain variables in a single body region with an adjusted odds ratio (aOR) of 1.16 (95% CI 1.07–1.27). Sleep duration <6 hours (aOR 2.02 (95% CI 1.08–3.77)), insomnia score (aOR 1.05 (95% CI 1.03–1.08)), sleepiness score (aOR 1.11 (95% CI 1.06–1.17)), anxiety score (aOR 1.09 (95% CI 1.03–1.16)) and depression score (aOR 1.24 (95% CI 1.16–1.33) remained statistically significant in the final analysis, but number of quick returns in the past year was no longer significant. MSI was run in a separate logistic regression (identical to Model 2 except for the use of MSI instead of pain by body region variables) and remained statistically significant with an aOR of 1.27 (95% CI 1.13–1.42), not shown in Table 4.

Our study found that pain, sleep duration <6h, insomnia, sleepiness, anxiety, and depression were significantly related to excessive fatigue even after controlling for all other variables present in the model. SWD was also associated significantly with excessive fatigue. Of our hypotheses, H1 (nurses with greater pain severity will more likely have excessive fatigue), H2 (nurses with sleep problems will more likely have excessive fatigue), and H3 (nurses with high levels of anxiety and depressive symptoms will more likely have excessive fatigue) were supported. H4 (nurses with shift work, night work and quick returns will more likely have excessive fatigue), however, was unsupported based on the fully adjusted model (Model 2).

Unlike some studies [17–21], we found no significant relationship between excessive fatigue and female sex. However, our findings correspond with previous studies in our SUSSH cohort where sex was not significantly associated with excessive fatigue [22, 23]. Our analyses found no significant relationship between excessive fatigue and age, which corroborates some [20, 22, 23] of the conflicting previous research. The current study supports the relationships between excessive fatigue and pain [30, 31], short sleep duration [33], insomnia [35] and anxiety and depression [38, 39].

We had no a priori hypotheses of which body regions may associate or not associate with fatigue. Because the measure we used offered both regional as well as global scores for pain we felt that both warranted investigation. Our results indicate the importance of pain in in relation to excessive fatigue, even in a presumably healthy cohort. The exact implications of the results of pain by body region must be interpreted with caution, however. That neck/shoulder/upper back, lower back and stomach pain were no longer significant in Model 2, but arm/wrist/hand, hip/leg/knee/foot, headache/migraine pain remained significant may be due to loss of power due to the study sample decreasing when all variables were included, or to potential/real differences in how pain in those regions affects a nurse’s fatigue.

Some of the results were imprecise with broad confidence intervals due to few nurses within each category of predictor and outcome–these results should be interpreted with caution. Our category for long sleep duration (>8h), for example, included a very small number of nurses reporting sleep >8h (n = 21) which affected the statistical power. Additionally, a healthy worker effect [64] may also be present, as long sleep is often associated with poor health [65]. Our findings on sleepiness corroborate Farag et al.’s study wherein fatigue was significantly associated with increased daytime sleepiness [17].

We found no significant relationship between excessive fatigue and several shift work-related factors, unlike other studies from Taiwan [43] and Sweden [21]. This contrasting finding may potentially be explained by the fact that the SUSSH nurses had already been followed for 10 years in 2018, and nurses who tolerated shift work poorly may have changed work schedules or careers by this point. In contrast to a previous study [40], we found no significant relationship between excessive fatigue and working nights in our group. This may be explained by operationalization differences. Åkerstedt et al. focused on work-related fatigue assessed with the question “do you feel that your work schedule causes fatigue (yes/no)” [40]. Excessive fatigue as measured in our cohort was not specific to the work schedule and therefore may have missed a relationship between work schedule-related fatigue and night work. Additionally a study by Øyane et al. found current night work to be associated with chronic fatigue [42]. However, that this latter study found no association between cumulative nights worked within the last year and chronic fatigue [42] is in line with our findings. Additionally, we expected that age would be an important confounder in the relationships between excessive fatigue and nights or quick returns, but we did not see evidence of this in the present study.

The present results corroborate a previous study in our cohort of nurses wherein number of quick returns in the past year was associated with excessive fatigue in crude, but not adjusted analyses [22]. However, these findings contradict other past studies [23, 40]. That Åkerstedt et al. [40] found a significant relationship between quick returns and fatigue in adjusted analyses may be due to the different operationalization of fatigue discussed with regard to night work, or other methodological differences. For example, Åkerstedt et al. adjusted analyses for age, gender, socioeconomics, and physically intensive work [40] but not for pain, sleep, mental-health or work schedule factors. Flo et al. [23] also used SUSSH data (from 2009 and 2010) and found that the number of quick returns in 2009 predicted pathological fatigue (operationalized in the same manner as excessive fatigue in our study) in 2010, and a reduction in quick returns from 2009 to 2010 was protective against pathological fatigue in 2010 [23]. It may be that those in our cohort who tolerated quick returns were more likely to continue working and therefore were overrepresented after nearly a decade of follow-up. Alternately, the cross-sectional nature of the present study may have missed a possible longitudinal relationship. Further longitudinal studies are needed to elucidate the relationship between fatigue and quick returns.

The current study found a significant association between excessive fatigue and SWD in both crude analyses and analyses adjusted for demographics. This is in line with a study from the first SUSSH wave (2008/2009) [37]. Our study did not include SWD in the final model (Model 2), because insomnia and excessive sleepiness, two variables included in the final model, are included in the criteria for SWD (participants were asked if their work schedule overlapped with normal sleep hours and if that caused insomnia and/or excessive sleepiness due to reduced amount of sleep). Therefore, associations between SWD and the other variables could not be explored in the fully adjusted model.

Pain by body area as well as MSI, sleep duration <6h, insomnia, sleepiness, anxiety, depression, SWD and number of quick returns in the past year were associated with having excessive fatigue. Similar findings were seen after controlling for age, sex, children at home and average hours worked. Associations were found between excessive fatigue and pain severity (arm/wrist/hand, hip/leg/knee/foot, and headache/migraine), sleep duration <6h, insomnia, sleepiness, anxiety and depression in the final fully adjusted model (Model 2), where all variables plus demographics were included.

Future research should include objective/clinical measures of fatigue, pain, sleep, mental health and work factors from objective recordings as well as health and employee registries. Longitudinal studies which can elucidate the temporal relationship between the variables in question will also help advance the field. Studies on quick returns and night work in seasoned versus inexperienced nurses may help illuminate the association or lack of association between excessive fatigue and these factors. Other factors that may be associated with fatigue should be explored, including stress, burnout, nutrition, and diseases. Further research is also necessary on what factors lead to chronically fatigued nurses, and on workplace strategies to reduce excessive fatigue in nurses and prevent nurse absence and turnover. Priorities should include interventions for nurses with headaches/migraines, high MSI pain severity, sleep duration <6 hours, insomnia, sleepiness, anxiety, depression and SWD. Schedule changes and other low-risk interventions (such as mediation for pain) may be explored for efficacy against excessive fatigue.

Data contain potentially sensitive and indirectly identifiable information. Due to ethical regulations in Norway, such data are not allowed to be shared publicly. The Regional Committee for Medical Research Ethics in Western Norway (contact: rek-vest@uib.no) set the ethical regulations for this project. Data are available upon reasonable request. Requests may be sent the Bergen Sleep and Chronobiology Network (BeSCN) (post@psysp.uib.no) or to a member of the project leader group. Please see the SUSSH web page for contact information for the group leaders (www.uib.no/en/rg/sc/120919/survey-shift-work-sleep-and-health-sussh↗). Author-generated code for this study is available in the supporting information (S13 File. Syntax).

The SUSSH study group received a small grant for practical administration by the Norwegian Nurses Organization (Norsk Sykepleierforbund, www.nsf.no↗). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.