Reliability and construct validity of the modified Finnish version of the 9-item patient health questionnaire and its associations within the biopsychosocial framework among female health-care workers with sub-acute or recurrent low back pain

This study contains cross-sectional baseline data from the NURSE-RCT (NCT01465698) [19‐22] and data from a small test-retest repeatability study (n = 64) among volunteer participants of the NURSE-RCT. The inclusion criteria of the RCT were women aged 30 to 55 years, had worked at their current job for at least 12 months, and intensity of LBP was at least 2 on the Numeric Rating Scale (scale 0–10) during the past 4 weeks. The exclusion criteria were prior serious back injury (fracture, surgery, disc protrusion); chronic LBP defined by a physician or self-report of continuous LBP for 7 months or more; disease or symptoms that limit participation in moderate intensity neuromuscular exercise; regular engagement in neuromuscular-type exercise more than once a week; pregnant or recently delivered. In total, 439 women responded to the screening questionnaire. Of these, 56% (n = 245) met the inclusion criteria and 11% (n = 26) refused to participate in the baseline measurements. The main back-related reasons for exclusion were intensity of LBP of less than 2 on the Numeric Rating Scale (22%) and having had continuous LBP for more than 7 months (12%) [19].

The test-retest data on selected questionnaire items, including PHQ-9-mFIN, were collected from sub-studies 2 and 3 of the NURCE-RCT in the fall of 2014 as part of the participants 24-month (sub-study 2) and 12-month (sub-study 3) follow-up measurements performed at the UKK Institute, Tampere, Finland (see Fig. 1 and Table 1 of the study protocol) [19]. The participants first filled out the standard NURSE-study questionnaire [19] at home (1st measurement) 1 week before attending the follow-up measurements conducted at the UKK Institute. The participants then filled out a repeatability questionnaire (2nd measurement) during the follow-up measurement session at the UKK institute. All participants provided their written informed consent to participate in the study to a research secretary at the beginning of the baseline measurements. The study protocol of NURSE-RCT is available at the following address: https://​www.​ncbi.​nlm.​nih.​gov/​pmc/​articles/​PMC5117067/​pdf/​bmjsem-2015-000098.​pdf [19]. The Regional Ethics Committee of the Expert Responsibility area of Tampere University Hospital (ETL code R08157) approved the study protocol.

Descriptive data are presented as percentages for categorical variables and mean values with standard deviation or 95% confidence intervals (CI) for continuous variables. The internal consistency of the items of the PHQ-9-mFIN was assessed by Cronbach’s α coefficient. A commonly used rule for describing internal consistency when using Cronbach’s alpha is: α ≥ 0.9 = excellent, α ≥ 0.8 = good, ≥ 0.7 = acceptable, α ≥ 0.6 = questionable, α ≥ 0.5 = poor, α < 0.5  = unacceptable [33]. The 1-week test-retest repeatability of the total score (0–27) of the PHQ-9-mFIN was assessed by Pearson correlation and Intraclass Correlation Coefficient (ICC). ICC was calculated using a 2-way mixed effects model and assuming absolute agreement. The test-retest scores in the form of a scatter plot are presented in Fig. 1.

The construct validity of the PHQ-9-mFIN was assessed against the RAND 36, a validated Finnish questionnaire [23], with Spearman correlation (non-normally distributed data) and one-way analysis of variance (ANOVA) using Sidak-adjusted p-values for multiple comparisons between groups (normally distributed data). Associations between the categorized PHQ-9-mFIN and biopsychosocial factors were tested with Kruskall-Wallis H due to non-normal distributions. In this study, the internal consistency and construct validity were defined and tested according to the COSMIN checklist Box A and Box F [16]. All statistical analyses were conducted by KT using SPSS statistics software, version 25 (IBM, Chicago, IL).

Of the nine questions in the PHQ-9-mFIN (see Table 1) questionnaire, “Feeling yourself lonely” (question 8) had the highest proportion of scores of 2 and 3 indicating a higher level of depressive symptoms (20.7 and 11.9%, respectively), followed by “Feeling bored or having little interest in doing things” (question 7; 22.6 and 6.0%), and “Lack of enthusiasm for doing anything” (question 1; 18.3 and 6.0%). The highest proportion of zero scores (no depressive symptoms) was detected for the questions “Have trouble getting to sleep or staying asleep” (question 3; 64.2%) and “Feeling hopeless about the future” (question 9; 63.8%). The mean value of the PHQ-9-mFIN in the present study population was 7.4 (range, 0 to 27).

The internal consistency of the PHQ-9-mFIN, assessed by Cronbach’s α, was 0.82. The Pearson’s test-retest repeatability correlation (n = 64) over the 1-week test-retest interval was 0.73 and ICC was 0.73 (95% CI: 0.58 to 0.82). The scatter plot (Fig. 1) indicates that the repeatability is lowest between the scores from 3 to 7 and highest from 9 up to the highest possible (i.e., 27).

The correlations (Spearman) of the Physical and Mental component items and their summary scales of the RAND 36-Item Health Survey [23] with PHQ-9-mFIN were much higher for the Mental components (range, − 0.40 to − 0.67) and their summary scale (− 0.64) when compared to those of the Physical components (range, − 0.08 to − 0.43, summary − 0.22), see Table 2.

Of the Physical components (see Table 3), Bodily pain had the lowest mean score of 63.0. However, the differences between the levels of depressive symptoms (PHQ-9-mFIN: None 0–4, Mild 5–9, at least Moderate ≥10) were small (range, 61.3 to 64.5) and statistically non-significant. Conversely, there was a clear stepwise association (p < 0.001) between the levels of depressive symptoms and General health (range 59.1 to 78.8), i.e., those with a Moderate level in PHQ-9-mFIN had the poorest health. Physical functioning had the highest mean score of 85.5, indicating good physical functioning in the present study population. However, the differences between the three levels of depressive symptoms were statistically significant (p < 0.001). The Physical summary score (mean 72.9) showed a small (range, 67.8 to 77.6) graded association (p = 0.002) between the levels of depressive symptoms. The mean Physical summary score in the None-symptoms group was lower than that of the mean Mental summary score (77.6 vs. 87.5).

Descriptive results of the study population within the biopsychosocial framework based on the level of depressive symptoms measured with the PHQ-9-mFIN are presented in Table 4. The proportion of female health-care workers with at least moderate symptoms (score ≥ 10) was 28% (n = 61) as was the percentage of those with no depressive symptoms (scores 0–4; n = 61).

The mean intensity of LBP during the past 4 weeks measured with VAS was at a clinically meaningful level of 40 mm [24] among those with moderate depressive symptoms and at the lowest level (i.e., 30 mm) among those with no symptoms (p = 0.039). There were stepwise associations (p ≤ 0.003) between the level of depressive symptoms and the number of musculoskeletal pain sites [25], lumbar exertion after workdays [26], recovery after work days during the past 4 weeks [27], neuromuscular fitness in modified push-ups test [28, 29], Work Ability Score [30], and fear of pain [32] related to work, but not that related to physical activity. The effort-reward imbalance (0.2–5), an indicator of work stress [31], slightly increased with the level of depressive symptoms (p = 0.014).

Cronbach’s α of 0.82 indicates that the internal consistency of the PHQ-9-mFIN is good and in line with the results of previous studies using the original PHQ-9 in primary care patients in Latvia [39] (Latvian version α = 0.79; Russian version α = 0.81) and Thailand (α = 0.79) [40] as well as among the general population in China (α = 0.86) [41] and Hong Kong (α = 0.82) [42].

The correlation coefficient of 0.73 indicates acceptable repeatability for the 1-week test-retest interval. Three earlier studies with a 2-week test-retest interval reported similar (0.76) [40, 42] and higher (0.86) [41] correlations. The scatter plot presented in Fig. 1 further shows that the repeatability is higher when the depressive symptom score is at least 9 (i.e., close to the moderate level of ≥10) or when the score is very low, from 0 to 3, indicating no depressive symptoms.

The original PHQ-9 assesses symptoms during the past 2 weeks. We chose to use the 1-week time-frame, as it was the time duration during which the participants wore accelerometers for “objective” assessment of physical activity [43] and sedentary behavior [44]. Furthermore, “Subjective” questionnaire data on physical activity and/or exercise are also usually collected for a 1-week period. Because physical activity and exercise are recommended treatments for moderate depression [45] as well as for recurrent LBP [46], we chose to collect data on both for a period of 1 week.

As expected, the correlations of the Physical component subscales (range, ─0.08 to ─0.43) and their mean Summary score (─0.22) of the RAND-36 with PHQ-9-mFIN were much lower than those of the Mental component subscales (range, ─0.40 to ─0.67, Summary ─0.64). When compared to previous studies among the general population [41, 47], the correlations of the Mental scores with PHQ-9-mFIN in the present study were somewhat higher, indicating a strong association between the two.

The results on the associations between the Physical and Mental component scores of the RAND-36 with the level of depressive symptoms according to PHQ-9-mFIN, using the original cut-off points for None (0─4), Mild (5─9), and Moderate (≥10) depression [13], indicated reduced HRQoL (i.e., scores < 70 out of 0─100) in the RAND-36 component items Bodily Pain, regardless of the level of depressive symptoms and General health, Vitality, and Mental health among those with at least a moderate level of symptoms. Thus, the present study group of female health-care workers with subacute or recurrent LBP who engaged in strenuous physical work for the back suffered from Pain (mean 63.0) regardless of whether they had depressive symptoms or not. Those with at least moderate symptoms lacked Vitality (i.e., were tired, mean 46.3), and their General health (mean 59.1) and Mental health (mean 64.1) were reduced when compared with optimal levels.

The main interest for assessing the associations was to find possible biopsychosocial risk factors for adverse future events among the female health-care workers engaged in strenuous physical work and experiencing recurrent LBP with or without depressive symptoms. Among patients with recurrent LBP, depressive symptoms are expected to have an adverse effect on the prognosis [8].

In our previous cross-sectional study among the present study population, work-related Fear-Avoidance Beliefs (p < 0.001), lumbar exertion (p = 0.003), depressive symptoms (p = 0.01), and recovery after work (p = 0.03) best explained work ability [21]. Multi-site musculoskeletal pain has also been associated with poor physical work ability among health-care workers. Indeed, the magnitude of the association is likely to increase with a higher number of pain sites [48]. In Finland, co-occurrence of musculoskeletal pain and depressive symptoms is strongly related to poor self-rated physical work ability [49].

A clear dose-response relationship has been reported between increasing levels of depressive symptoms and the risk for long-term sickness absence (LTSA) [50]. Furthermore, the adverse effect of non-clinical depressive symptoms manifested at relatively low scores [50]. In Finland, musculoskeletal pain, but not depression, is associated with thoughts of early retirement [49]. Among Danish health-care workers, depressive symptoms and the number of musculoskeletal pain locations were associated with an increased risk of LTSA in those individuals who did not have comorbid symptoms [51].