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Psychosocial Risk Factors and Musculoskeletal Symptoms among White and Blue-collar Workers at Private and Public Sectors
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Research Article Psychosocial Risk Factors and Musculoskeletal Symptoms among White and Blue-collar Workers at Private and Public Sectors
Leticia B Januario1, Mariana V Batistao1, Helenice JCG Coury1, Ana Beatriz Oliveira1, Tatiana O Sato1
Annals of Occupational and Environmental Medicine 2014;26:20-20.
DOI: https://doi.org/10.1186/s40557-014-0020-5
Published online: July 25, 2014

1Physical Therapy Department, Physical Therapy Post Graduate Program, Rodovia Washington Luís km 235, São Carlos 13565-905, Brazil

• Received: April 30, 2014   • Accepted: July 10, 2014

Copyright © 2014 Januario et al.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

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  • Objectives
    The aim of this study was to evaluate musculoskeletal and psychosocial perception and compare these conditions regarding the type of job (white or blue-collar) and the type of management model (private or public).
  • Methods
    Forty-seven public white-collar (PuWC), 84 private white-collar (PrWC) and 83 blue-collar workers (PrBC) were evaluated. Job Content Questionnaire (JCQ) and Utrecht Work Engagement Scale (UWES) were applied to evaluate psychosocial factors. Nordic Musculoskeletal Questionnaire (NMQ) was used to assess musculoskeletal symptoms. Pressure Pain Threshold (PPT) was measured to evaluate sensory responses.
  • Results
    According to JCQ, all groups were classified as active profile. There was a significant association between work engagement and workers’ categories (p < 0.05). PrWC workers had the highest scores for all the UWES domains, while PrBC had the lowest ones. PPT showed that PrBC workers had an increased sensitivity for left deltoid (p < 0.01), and for both epicondyles (p < 0.01), when compared to the other groups. PrWC workers had an increased sensitivity for both epicondyles than PuWC (right p < 0.01; left, p = 0.05). There was no significant association in the report of symptoms across the groups (p > 0.05).
  • Conclusion
    This study showed differences in psychosocial risk factors and musculoskeletal symptoms in workers engaged in different types of jobs and work organization. Personal and work-related characteristics, psychosocial factors and PPT responses were different across workers’ group. Despite all, there was no significant difference in reported symptoms across the groups, possibly indicating that the physical load is similar among the sectors.
  • Resumo

    Objetivos

    O objetivo deste estudo foi avaliar a percepção musculoesquelética e psicossocial e comparar essas condições em relação ao tipo de trabalho (de escritório ou industrial) e o tipo de modelo de gestão (público ou privado).

    Métodos

    Quarenta e sete trabalhadores de escritório em cargos públicos (PuWC), 84 trabalhadores de escritório em cargos privados (PrWC) e 83 trabalhadores industriais de uma empresa privada (PrBC) foram avaliados. O Job Content Questionnaire (JCQ) e a Utrecht Work Engagement Scale (UWES) foram aplicados para avaliar os fatores psicossociais. O Questionário Nórdico de Sintomas Osteomusculares (NMQ) foi usado para avaliar os sintomas musculoesqueléticos. O limiar de dor à pressão (PPT) foi medido para avaliar as respostas sensoriais.

    Resultados

    De acordo com JCQ, todos os grupos foram classificados como perfil ativo. Houve uma associação significativa entre o engajamento de trabalho e categorias de trabalhadores (p < 0,05). Os trabalhadores PrWC tiveram as maiores pontuações para todos os domínios da UWES, enquanto os PrBC tiveram os menores. Os resultados do PPT mostraram que trabalhadores do grupo PrBC apresentaram maior sensibilidade no deltóide esquerdo (p < 0,01) e em ambos os epicôndilos (p < 0,01), quando comparados com os outros grupos. Os PrWC apresentaram maior sensibilidade para ambos os epicôndilos do que PuWC (p < 0,01 na direita; p = 0,05 para esquerda). Não houve associação significativa do relato de sintomas com os grupos (p > 0,05).

    Conclusão

    Existe diferença nos fatores de risco psicossociais e sintomas musculoesqueléticos em trabalhadores envolvidos em tipos de trabalho e sistemas organizacionais diferentes. Apesar disso, não houve associação significativa no relato de sintomas entre os grupos, podendo indicar que a demanda biomecânica é semelhante em todos os setores investigados.
Work Related Musculoskeletal Disorders (WRMDs) are one of the most prevalent occupational diseases all over the world. It is responsible for absenteeism, early retirement and disabilities [1]-[5]. According to epidemiologic data provided in 2012 by the Brazilian Social Security Ministry, 720,629 cases of work related accidents and disorders, including WRMDs, were registered in Brazil [6]. Official Brazilian government data do not specify the number of workers who suffered from WRMSDs. The problem is even bigger when considering that almost half of the Brazilian workers are not formally registered in the Social Security Ministry, doing their jobs as informal workers.
Particularly, the neck-shoulder region is exposed to low-level monotonous workload for prolonged periods of time during activities such as office work and industrial repetitive tasks [7],[8].
This overload is associated with many other risk factors, such as high work pace, repetitive and stereotyped movements, maintenance of awkward postures or static seated position, besides temperature, illumination and vibration exposure [7],[9],[10]. The prolonged exposure to these risk factors [11], associated with psychosocial factors [8] and job organization [12], also influences the onset and persistence of WRMDs.
Different levels of exposure are found on workplaces according to the management model and the characteristics of the working activity. When comparing private and public work sectors in Brazil, it is clearly seen that public sector has some particularities, such as: difficulty to promote ergonomics due to inadequate equipment, lack of direct hierarchy, high incidence of strikes, difficulty of career advancement and employment stability [13],[14]. Even though those characteristics are based on the Brazilian reality, this public management model found is similar with other western countries [15],[16]. Bach and Della Rocca [17] reported that the main reason for implementing changes in a Swedish public sector has been to reduce costs instead of promoting better workplaces. Fjell and co-workers [16] have also highlighted another negative issue - the decisions of public authorities can change according to elections outcomes. Therefore, political chiefs can have direct influence on budgets and organizational systems [16].
Biomechanical exposure might be also different among jobs. Even though both white and blue-collar workers perform monotonous and repetitive tasks, each type of job has its particularities. In general, blue-collar workers perform tasks in standing posture, and have more possibilities to adopt other postures, even though the work pace is controlled by the machine or other workers. On the other hand, white-collar workers have more constrained posture, and perform computer-based tasks, requiring seated position and demanding high level of knowledge and attention; one positive feature is the fact that white-collar workers have flexible working rhythm [18],[19].
Thus, the knowledge on risk factors for WRMDs in different jobs, considering management model and working activities is crucial to support preventive actions. In order to contribute with information on this matter, the aim of the present study is to evaluate both musculoskeletal and psychosocial perception among blue-collar and white-collar workers, and compare their condition regarding the type of management model (private or public sector) and the type of job (white-collar or blue-collar).
Description of work sectors and subjects
This cross-sectional study was conducted at a public University and a factory of office supplies, both located at countryside of São Paulo, Brazil. The public university has approximately 888 workers performing administrative tasks. They are distributed among secretaries, and management sectors. They perform office work combined and public attendance. Therefore, their tasks consist of writing e-mails and documents; browsing the web; checking and entering data into spreadsheets; talking on the phone; meeting students or staff; signing documents; moving from one workstation to another to communicate with co-workers and photocopying.
At the factory of office supplies, approximately two thousand workers perform industrial and administrative work. Two sectors were approached in this study. Workers from these sectors are grouped in manufacturing cells, and are responsibly for supplying the machine, supervising the production, inspecting products, and packing. Those tasks involve repetitive manual activities with low levels of muscular contractions and maintenance of awkward postures throughout the workday, characteristics of blue-collar job. The private administrative tasks are similar to the ones described to the university employees.
Two hundred and fourteen workers were recruited to participate in the study. Forty-seven (44.4 ± 8.4 years old) were public white-collar workers (PuWC); 84 (39.0 ± 8.0 years old) were private white-collar workers (PrWC); and 83 (37 ± 8 years old) were private blue-collar workers (PrBC). PuWC were recruited from a list of administrative workers provided by the Human Resource Department. They were randomly contacted by phone calls until a sample of 50 subjects was reached. Three workers, who missed any evaluation, were excluded from the final sample. At the factory, all PrWC and PrBC from two production sectors were invited to participate. Those who participated in all assessments were included in the study.
The study was approved by the Ethics Committee on Human Research of the Federal University of Sao Carlos (Process #352/2010 and #356/2010).
Instruments and equipment
The evaluation was composed by the application of questionnaires and measurement of the pressure pain threshold. Psychosocial factors were evaluated through the Job Content Questionnaire (JCQ) and the Utrecht Work Engagement Scale (UWES). The JCQ was translated and validated to Brazilian Portuguese [20].
The JCQ correlates the domains of demand and control in order to classify the worker in one of the following domains: active (high demand and high control); passive (low demand and high control); high strain (high demand and low control); low strain (low demand and high control). The domains were classified as high or low according to the median value obtained to each group. The same procedure was applied to classify the social support domain.
The UWES is a questionnaire developed to assess the level of engagement, vigor, dedication and absorption that each subject has in relation with his/her work. Therefore, it requires the worker about the positive aspects of its working activities instead of burnout like most of the available psychosocial questionnaires. There are not current studies validating the UWES to the Brazilian Portuguese, but a translation is provided by the authors [21]. The Cronbach’s α showed good internal consistency for all subitems used on UWES-17 questions (vigor 0.82, dedication 0.89, absorption 0.83, total score 0.93) [21].
The Nordic Musculoskeletal Questionnaire (NMQ) was used to evaluate musculoskeletal symptoms [22]. A Brazilian version of the questionnaire was applied [23]. The pressure pain threshold (PPT) was measured using a mechanical pressure algometer (Pain Diagnosis and Treatment Inc, Great Neck, NY, USA). This device consists of a round rubber disc (1 cm2) attached to a pressure gauge, that displays values in kilograms. Both right and left trapezius muscle were tested at half-away between the midline and lateral border of the acromion. The deltoid muscles were tested at the midpoint between the acromion and its insertion [24],[25], and the lateral epicondyles were bilaterally tested [26]. The reference site was located 2 cm below the upper border of the sternum, in the midline.
The subject was evaluated on seated position. The algometer was placed perpendicular to the body surface, at a constant pressure of 1kgf/cm2/s. The pressure was interrupted when the subject recognized that the pressure sensation became a pain sensation. Three measurements were performed for each point, with intervals of 30 seconds between them. The mean value, in Kgf, of each point was described as the pain threshold.
Data analysis
Descriptive analysis including proportion, means, standard deviations and confidence intervals was performed. Data of demographic and personal characteristics were checked for normality and homogeneity of variance through Shapiro Wilks and Levene tests, respectively. Since the assumptions were not attended, the comparison between groups was performed through nonparametric Kruskall-Wallis test. Groups were compared for the categorical dependent variables resulting from the questionnaires (NMQ, JCQ and UWES) by the Chi square association test. Pressure Pain Threshold (PPT) was compared across groups through MANOVA (normality and homogeneity of variance were also checked, and the assumptions were attended). When significant differences were found, univariate tests (one-way ANOVA) identified the significant variables, and Tukey post-hoc test was applied to identify group differences. Logistic regression was applied to identify factors associated with symptoms (age, gender, body mass index, educational level, and JCQ). The stepwise method was used to include variables in the model. The data analysis was performed in SPSS (version 20.0) and the alpha level was set at 5%. There were some missing data; therefore the number of valid cases analyzed is shown in the tables.
Personal and work-related characteristics of PrWC, PrBC and PuWC, and the total sample are presented in Table 1. Data show that PuWC were older than the workers from both private sectors (white-collar, p < 0.01; blue-collar, p < 0.01). The private white-collar workers (PrWC) were lighter (p = 0.04) and taller (p < 0.01) than PuWC. On the other hand, PrWC were also heavier (p < 0.01), shorter (p < 0.01) and had a greater Body Mass Index - BMI (p = 0.01) than PrBC.
Table 1
Personal and demographic characteristics for the groups and the total sample
  PrWC (n = 84) PrBC (n = 83) PuWC (n = 47) Total (n = 214) p-value
Age - years (mean [SD]) 39.1(8.3) 36.9(8.1) 43.4(8.4) 39.4(8.6) 0.000
Weight - kg (mean [SD]) 78.6(12.9) 68.3(13.8) 73.6(15.9) 73.5(14.6) 0.000
Height - meters (mean [SD]) 1.7(0.1) 1.7 (0.1) 1.6 (0.1) 1.7(0.1) 0.000
BMI - kg/m2 (mean [SD]) 26.5(3.5) 24.9(4.0) 26.4(5.4) 25.6(4.9) 0.006
Gender (n[%])          
Male 51(60.7) 20(24.1) 9(19.1) 80(37.4) 0.000
Female 33(39.3) 63(75.9) 38(80.9) 134(62.6)
Scholarity (n[%])          
Incomplete Elementary School 0(0.0) 4(4.8) 0(0.0) 4(1.9) 0.000
Complete Elementary School 0(0.0) 2(2.4) 0(0.0) 2(0.9)
Incomplete High School 0(0.0) 5(6.0) 1(2.1) 6(2.8)
Complete High School 3(3.6) 61(73.5) 2(4.3) 66(30.8)
Technical Education 1(1.2) 7(8.4) 4(8.5) 12(5.6)
Incomplete University Graduation 11(13.1) 4(4.8) 2(4.3) 17(7.9)
Complete Graduation 26(31.0) 0(0.0) 10(21.3) 36(16.8)
Post-graduation 43(51.2) 0(0.0) 28(59.6) 71(3.2)
Age that started work (mean [SD]) 15.5(3.7) 17.2(4.1) 16.7(3.6) 16.(3.9) 0.016
Sickness absence (n[%]) 40(47.6) 56(67.5) 16(34.0) 112(52.3) 0.000
Smoke (n[%]) 5(6.0) 4(4.8) 2(4.3) 11(5.1) 0.902
Marital status (n[%])          
Single 14(16.7) 17(20.5) 8(17.0) 39(18.2) 0.635
Married 64(76.2) 57(68.7) 32(68.1) 153(71.5)
Divorced 2(2.4) 5(6.0) 3(6.4) 10(4.7)
Living with partner 4(4.8) 4(4.8) 3(6.4) 11(5.1)
Widower 0(0.0) 0(0.0) 1(2.1) 1(0.5)
Physical Activity 26(31.3) 26(31.3) 20(43.5) 72(34.0) 0.305
The sample size is indicated for each group.
Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.
There were more female workers in the public white-collar sector and private blue-collar sector, and more male workers in the private white-collar sector. The majority of PuWC and PrWC have completed post-graduation studies. On the other hand, most of the PrBC have completed high school. The variables marital status (p = 0.63), smoke (p = 0.90) and physical activity (p = 0.30) have not shown association with groups. PrWC have started working earlier than the PrBC (p < 0.01) and PuWC (p = 0.04). PrBC had higher prevalence of sickness absence than the other workers (p < 0.01).
Data of the Utrecht Work Engagement Scale (UWES) are presented in Table 2. Table 3 shows results of the Job Content Questionnaire (JCQ), and Table 4 shows data of the Nordic Musculoskeletal Questionnaire (NMQ) for symptoms reported for the previous 7 days.
Table 2
Utrecht Work Engagement Scale (UWES) data from the groups
  PrWC (n = 84) PrBC (n = 82) PuWC (n = 47) p-value
  n (%) 95% CI n (%) 95% CI n (%) 95% CI
Vigor              
Very low 0(0.0) 0.0-4.4 2(2.9) 0.7-0.9 1(2.1) 0.4-11.1 0.002
Low 1(1.2) 0.2-6.4 14(20.3) 10.5-26.6 6(12.8) 6.0-25.2
Medium 25(29.8) 21.0-40.2 23(33.3) 19.5-38.6 16(34.0) 22.2-48.3
High 43(51.2) 40.7-61.6 18(26.1) 14.4-32.1 21(44.7) 31.4-58.8
Very high 15(17.9) 11.1-27.4 12(17.4) 8.6-23.9 3(6.4) 2.2-17.2
Dedication              
Very low 0(0.0) 0.0-4.4 4(4.9) 1.9-11.9 2(4.3) 1.2-14.2 0.013
Low 6(7.1) 3.3-14.7 15(18.3) 11.4-28.0 8(17.0) 8.9-30.1
Medium 29(34.5) 25.2-45.2 27(32.9) 23.7-43.7 18(38.3) 25.8-52.6
High 32(38.1) 28.4-48.4 13(15.9) 9.5-25.3 16(34.0) 22.2-48.3
Very high 17(20.2) 28.4-48.4 10(12.2) 6.8-21.0 3(6.4) 2.2-17.2
Absorption              
Very low 0(0.0) 0.0-4.4 4(4.9) 1.9-11.9 0(0.0) 0.0-7.6 0.000
Low 2(2.4) 0.7-0.8 16(19.5) 12.4-29.4 4(8.5) 3.4-19.9
Medium 22(29.8) 18.0-36.5 22(26.8) 18.4-37.3 24(51.0) 37.2-64.7
High 43(51.2) 40.7-61.6 18(22.0) 14.4-32.1 15(31.9) 20.4-46.2
Very high 17(20.2) 13.0-30.0 9(11.0) 5.9-19.6 4(8.5) 3.4-19.9
Engagement              
Very low 0(0.0) 0.0-4.4 3(3.7) 1.3-10.2 1(2.1) 0.4-11.1 0.002
Low 2(2.4) 0.7-0.8 14(17.1) 10.5-26.6 6(12.8) 6.0-25.2
Medium 25(29.8) 21.0-40.2 26(31.7) 22.6-42.4 19(40.4) 27.6-54.7
High 47(56.0) 45.3-66.1 19(23.2) 15.4-33.4 18(38.3) 25.8-52.6
Very high 10(11.9) 6.6-20.5 7(8.5) 4.2-16.6 3(6.4) 2.2-17.2
Number of cases (%). 95% confidence interval (CI 95%). and statistical results (Qui-Square test) are presented.
Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.
Table 3
Results of the Job Content Questionnaire from private and public workers
  PrWC (n = 84) PrBC (n = 83) PuWC (n = 47) p-value
  n (%) 95% CI n (%) 95% CI n (%) 95% CI
Passive 14(16.7) 10.2 - 26.1 4(4.8) 1.9 - 11.7 5(10.6) 4.6 - 22.6 0.046
Low strain 20(23.8) 16.0 - 33.9 22(26.5) 18.2 - 36.9 11(23.4) 13.6 - 37.2
High strain 21(25.0) 17.0 - 35.2 7(8.4) 4.1 - 16.4 10(21.3) 12.0 - 34.9
Active 29(34.5) 25.2 - 45.2 37(44.6) 34.4 - 55.3 21(44.7) 31.4 - 58.8
Number of cases (%). 95% confidence interval (CI 95%). and statistical results (chi square test) are presented.
Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.
Table 4
Results of the 7 days symptoms for private and public workers
  PrWC (n = 60) PrBC (n = 63) PuWC (n = 47) p-value
  n (%) 95% CI n (%) 95% CI n (%) 95% CI
Neck 25(41.7) 30.1 - 54.3 17(27.0) 17.6 - 39.0 13(27.7) 16.9 - 41.8 0.159
Shoulder 20(33.3) 22.7 - 45.9 14(22.2) 13.7 - 33.9 13(27.7) 16.9 - 41.8 0.387
Upper back 16(26.7) 17.1 - 39.0 10(15.9) 8.9 - 26.8 10(21.3) 12.0 - 34.9 0.342
Elbow 5(8.3) 3.6 - 18.1 04(6.3) 2.5 - 15.2 03(6.4) 2.2 - 17.2 0.892
Lower back 17(28.3) 18.5 - 40.8 11(17.7) 10.0 - 28.6 18(38.3) 25.8 - 52.6 0.056
Wrist/Hand 6(10.0) 4.7 - 20.1 7(11.1) 5.5 - 21.2 11(23.4) 13.6 - 37.2 0.098
Number of cases (%), 95% confidence interval (CI 95%), and statistical results (chi square test) are presented.
Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.
There was a significant association between the three work groups and the JCQ profiles. All three groups had more workers with the active profile – high demand and high control (PrWC - 34.5%; PrBC – 44.6%; PuWC – 44.7%). The secondly most prevalent profile for PrBC and PuWC was the low strain - low demand and high control (26.5% and 23.4% respectively), while the PrWC were classified as high strain profile - high demand and low control (25%).
Results of the UWES indicate association between workers categories and work engagement (p < 0.01), absorption (p < 0.01), dedication (p = 0.01), and vigor (p < 0.01) - Table 3. PrWC had the highest scores for all the domains, while PrBC had the lowest ones.
Both private sectors had high levels of self report symptoms on neck region. However, no association between symptoms report and group was found (p = 0.16). Even though this association has not been significant, the p-value found when considering the reported pain for the lower back was 0.05. Both white-collar sectors (PuWC and PrWC) had higher prevalence of reported pain in the lower back in the last 7 days than the blue-collar group.
Data of Pressure Pain Threshold (PPT) are shown in Figure 1. The ANOVA showed no significant difference across groups for the sternum PPT (p = 0.18). However, significant differences were found in MANOVA for the other regions (p < 0.01). One-way ANOVA showed differences for the left deltoid, right and left epicondyles. For the left deltoid, the PrBC had significant lower pain threshold than the PrWC (Figure 1, p < 0.01). For the epicondyles, the PrBC (right and left epicondyle, p < 0.01) and PrWC (right epicondyle, p < 0.01; left epicondyle, p = 0.05) had significant lower pain threshold than the PuWC.
Figure 1
Pressure Pain Threshold (PPT) data for private (white-collar and blue-collar) and public white-collar sector for right and left trapezius, right and left deltoid and right and left lateral epicondyle and sternum.
s40557-014-0020-5-1.jpg
Logistic regression showed JCQ explained 8% of low back symptoms (R2 = 0.08; β = 0.34; standard error = 0.16; p = 0.03). The odds ratio was 1.4 and the 95% CI was 1.0 to 1.9.
The current study showed differences regarding psychosocial indicators and musculoskeletal symptoms among workers engaged in different types of jobs and work organization. PuWC were older and highly educated than the others groups. PrBC had higher levels of sickness absence. Considering psychosocial factors, all sectors had most of workers classified as active profiles (JCQ) and good work engagement (UWES). Both private sectors had higher prevalence of reported pain on neck region and both white-collar sectors had higher prevalence of reported pain on lower back region according to NMQ. At last, the PPT showed that PrBC had an increased sensitivity for left deltoid and both epicondyles compared to the other workers, and PrWC had an increased sensitivity for both epicondyles compared to PuWC.
According to Marconi [27] a high level of scholarity is required from individuals working at public careers. This requirement occurs during the hiring process for specialized white-collar work tasks. This process allows the subject to be hired on a high job position and get employment stability. However, this leads to a difficulty of career advancement. A study comparing the public and private working population showed that most of public workers are between 41 and 50 years old, and that the job turnover was very low at public administration sectors during 1995 - about 0.4% [27].
The majority of workers evaluated in this study presented active profiles for psychosocial factors according to the demand-control model (JCQ), independently of the sector evaluated. According to Karasek and Theörell [28], the active profile generates a motivational work environment, been considered as a positive profile. However, others studies that evaluated the effects of psychosocial factors on both physical and mental health have found an association between the active and high strain profiles with physical and mental illness, due to the high demand found in both profiles [29]. The worker can respond to increased work demands with a cascade of physiological changes that, if repeatedly evoked, can contributes to the development, exacerbation, and/or maintenance of work-related symptoms [30]. The secondly most frequent profile observed through the JCQ was the low strain, particularly for PrBC and PuWC. The high strain profile was the secondly most prevalent for the PrWC. In this last profile, the low control leads to adverse health effects, like psychological stress, burnout, production of cortisol and adrenalin, self-report irritation and symptoms at the upper limb region [29],[31].
A different and more recent approach to assess psychosocial factors is the evaluation of work engagement. Our results indicated highest work engagement (for both the total score and the three separated dimensions) for private white-collar workers - PrWC, while private blue-collar workers – PrBC, had the lowest work engagement levels compared to the other groups. Despite that, PrBC had work engagement score at medium level, indicating a positive feature. Once the majority of workers were classified as active profile according to JCQ (high control and demand), the good work engagement identified may be consistent with a previous prospective study of the Finnish Public Health Care Personnel. According to previous studies, job control is positively and significantly associated with positive levels of work engagement [32],[33]. This result must be carefully applied to interpret our data since any correlation analysis has been applied. The highest level of work engagement identified among PrWC workers can be partially explained by the job characteristics, since white-collar workers are more engaged than blue-collar workers [21].
These psychosocial indicators may have influenced on the musculoskeletal symptoms, since the PrWC showed greater prevalence (although without statistical significance) of pain in neck, shoulder, upper back and elbow. Regression analysis also reinforces these results, as JCQ explained low back symptoms. Griffiths and co-workers [34] evaluated 934 white-collar workers and have found a significant association between job demands and musculoskeletal symptoms, especially for the neck. However, it is important to consider the ergonomics of the workplace can have an important contribution to the development of musculoskeletal symptoms.
The high prevalence of self-reported pain in all groups (particularly for neck, lower back, shoulders, upper back and wrist/hands) and absence of significant association between groups and pain complaints may suggest that both administrative and blue-collar workers are exposed to potential risk factors for the development of musculoskeletal disorders, independently of the management model. Besides this, confounders variables (age, gender and educational level) were not associated with symptoms. In general, the prevalence of self-reported musculoskeletal symptoms reported in this study agrees with the literature. Nomura et al. [35] evaluated 185 private white-collar workers and observed high levels of self-reported low back pain, and high psychosocial demand through the JCQ. Choobineh et al. [36] evaluated 871 white-collar workers and 313 blue-collar workers of an Iranian petrochemical company. They reported that the most prevalent symptoms among white-collar workers were found in lower back and neck, which agrees with results reported here. On the other hand, the knee was the body region with highest prevalence of symptoms besides the lower back. Griffiths and coworkers [34] have found similar prevalence of self-reported symptoms when evaluating public white-collar workers in Australia.
The body sites with the highest levels of self-reported complaints were both the neck and lower back. This can be explained by the characteristics of the job, such as prolonged exposure to a low-level, monotonous and repetitive workload, associated with awkward postures - mostly in seated position. The neck-shoulder region is specially affected by these characteristics according to the Cinderella hypothesis - submaximal contractions involves a fraction of the motor-units (MUs) available and the recruitment pattern are likely to be stereotyped [37]. Since the recruitment follows the principle of size-ordered MUs, small type I fibers are continuously activated during prolonged and monotonous tasks [7],[8],[38]. The continuous overload on these type I fibers impairs the proper muscle recovery, leading to a harmful process that can cause pain and symptoms.
Considering the lower back region, the literature points out the high prevalence of symptoms among white-collar workers, regardless the management model [37],[39]-[41]. Choobineh et al. [36] compared the self-report of musculoskeletal symptoms of the past 12 months among blue-collar workers, white-collar workers, and workers performing both activities. They reported no differences between groups for complaints on shoulders, elbow, wrists/hands, upper back, lower back, hips/thighs, knees, and ankles/feet. However, they found that workers performing both activities had higher prevalence of symptoms for neck (37.1%) than white-collar (32.5%) and blue-collar workers (24.6%) separately [36].
The evaluation of PPT showed differences between groups for the left deltoid and both right and left epicondyles. PPT measurements are relevant in working populations with musculoskeletal disorders [15],[42]-[46]. PrBC had lower PPT when compared with PrWC (left deltoid) and PuWC (right and left epicondyles). These workers had also a significant higher sickness absence report than the other workers. We have not had access to information about the reason of the sickness absence, difficulting the interpretation of the results. However, a study investigating the work-related sickness absence in United Kingdom found lower prevalence for manufacturing sectors (51%) and higher prevalence for public administrative sectors (71%) than the ones found in our study [16].
Differences between PrWC and PuWC were also found. PrWC had a significant lower PPT for both right and left epicondyles than PuWC. Private white-collar workers have also presented higher prevalence of sickness absence than the white-collar workers from the public sector. Binderup and coworkers [35] found similar results when evaluating 29 cleaners. They found a relationship between long-term sickness absence and a lower level of PPTs in the neck-shoulder region.
Lower values of PPTs have been associated with frequency of forearm and shoulder symptoms [41]. Nielsen and coworkers [43] evaluated 70 female white-collar workers and found that participants with trapezius myalgia had a lower PPT, when compared with healthy controls. Binderup and coworkers [42] found a negative correlation between the mean PPTs of the cervico-thoracic region and the self-reported pain in neck, dominant shoulder and upper back within the last 7 days among cleaners. In our study, the PrWC group presented low PPT on the epicondyles combined to a higher prevalence of elbow symptoms. On the other hand, this behavior was not seen among PrBC. Private blue-collar workers presented low PPT on both deltoid and epicondyles and a relatively low prevalence of symptoms on those regions. However, we may not discard the hypotheses of these workers being on an initial phase of some musculoskeletal disorder. In a longitudinal study of initially asymptomatic blue-collar workers, Madeleine and coworkers [44] found that low PPTs are already seen in those workers who developed musculoskeletal symptoms 6 months later, reflecting the cumulative and chronic nature of the WRMDs.
This study has some limitations such as: the cross-sectional design limits the cause-effect understanding and the lack of biomechanical exposure measurements. Despite that, the results contribute to improve knowledge on this field of expertise, allowing to understand the behavior of psychosocial factors, musculoskeletal symptoms and sensory responses across sectors with different organizational aspects but exposed to a monotonous and repetitive workload.
The present study showed differences in psychosocial indicators and musculoskeletal symptoms in workers engaged in different types of jobs and work organization. Personal and work-related characteristics, psychosocial factors and PPT responses were different across workers’ group. The majority of workers have a high psychosocial load, particularly the private white-collar workers. Despite this, all sectors showed a good work engagement, although the results of the private white-collar group have been better than the other ones.
The blue-collar workers had an increased sensitivity, by means of the PPT, for left deltoid and both epicondyles compared to the other workers. Moreover, the private white-collar workers had an increased sensitivity for both epicondyles compared to the public ones. The low PPT may have reflected on the sickness absence of the white-collar and blue-collar private workers, and on musculoskeletal symptoms only for the private white-collar workers. Despite all, there was no significant difference in reported symptoms across the groups, possibly indicating that the physical load is overall similar among the sectors.
ANOVA: Analysis of variance
cm: centimeter
JCQ: Job Content questionnaire
kgf: kilogram-force
MANOVA: Multivariate analysis of variance
MU: Motor unit
NMQ: Nordic musculoskeletal questionnaire
PrBC: Private blue-collar workers
PrWC: Private white-collar workers
PPT: Pressure pain threshold
PuWC: Public white-collar workers
s: seconds
UWES: Utrecht work engagement scale
The authors declare that they have no competing interests.
All authors made substantive intellectual contributions to this study to qualify as authors. LBJ, HJCGC, ABO and TOS participated in the design, approval, and collection. LBJ, HJCGC, ABO, MVB and TOS participated in the analysis, interpretation of data and writing of this study. All authors reviewed the final version, gave the final approval of the version to be published, and agreed to be accountable for all aspects of the work in order to ensure that questions related to the accuracy or integrity of any part of the work will be appropriately investigated and resolved.
Authors would like to offer special thanks to FAPESP Proc. 2013/02149-1, CNPq Proc. 557752/2009-4.
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      Psychosocial Risk Factors and Musculoskeletal Symptoms among White and Blue-collar Workers at Private and Public Sectors
      Ann Occup Environ Med. 2014;26:20-20.   Published online July 25, 2014
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    Psychosocial Risk Factors and Musculoskeletal Symptoms among White and Blue-collar Workers at Private and Public Sectors
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    Figure 1 Pressure Pain Threshold (PPT) data for private (white-collar and blue-collar) and public white-collar sector for right and left trapezius, right and left deltoid and right and left lateral epicondyle and sternum.
    Psychosocial Risk Factors and Musculoskeletal Symptoms among White and Blue-collar Workers at Private and Public Sectors
     PrWC (n = 84)PrBC (n = 83)PuWC (n = 47)Total (n = 214)p-value
    Age - years (mean [SD])39.1(8.3)36.9(8.1)43.4(8.4)39.4(8.6)0.000
    Weight - kg (mean [SD])78.6(12.9)68.3(13.8)73.6(15.9)73.5(14.6)0.000
    Height - meters (mean [SD])1.7(0.1)1.7 (0.1)1.6 (0.1)1.7(0.1)0.000
    BMI - kg/m2 (mean [SD])26.5(3.5)24.9(4.0)26.4(5.4)25.6(4.9)0.006
    Gender (n[%])     
    Male51(60.7)20(24.1)9(19.1)80(37.4)0.000
    Female33(39.3)63(75.9)38(80.9)134(62.6)
    Scholarity (n[%])     
    Incomplete Elementary School0(0.0)4(4.8)0(0.0)4(1.9)0.000
    Complete Elementary School0(0.0)2(2.4)0(0.0)2(0.9)
    Incomplete High School0(0.0)5(6.0)1(2.1)6(2.8)
    Complete High School3(3.6)61(73.5)2(4.3)66(30.8)
    Technical Education1(1.2)7(8.4)4(8.5)12(5.6)
    Incomplete University Graduation11(13.1)4(4.8)2(4.3)17(7.9)
    Complete Graduation26(31.0)0(0.0)10(21.3)36(16.8)
    Post-graduation43(51.2)0(0.0)28(59.6)71(3.2)
    Age that started work (mean [SD])15.5(3.7)17.2(4.1)16.7(3.6)16.(3.9)0.016
    Sickness absence (n[%])40(47.6)56(67.5)16(34.0)112(52.3)0.000
    Smoke (n[%])5(6.0)4(4.8)2(4.3)11(5.1)0.902
    Marital status (n[%])     
    Single14(16.7)17(20.5)8(17.0)39(18.2)0.635
    Married64(76.2)57(68.7)32(68.1)153(71.5)
    Divorced2(2.4)5(6.0)3(6.4)10(4.7)
    Living with partner4(4.8)4(4.8)3(6.4)11(5.1)
    Widower0(0.0)0(0.0)1(2.1)1(0.5)
    Physical Activity26(31.3)26(31.3)20(43.5)72(34.0)0.305
     PrWC (n = 84)PrBC (n = 82)PuWC (n = 47)p-value
     n (%)95% CIn (%)95% CIn (%)95% CI
    Vigor       
    Very low0(0.0)0.0-4.42(2.9)0.7-0.91(2.1)0.4-11.10.002
    Low1(1.2)0.2-6.414(20.3)10.5-26.66(12.8)6.0-25.2
    Medium25(29.8)21.0-40.223(33.3)19.5-38.616(34.0)22.2-48.3
    High43(51.2)40.7-61.618(26.1)14.4-32.121(44.7)31.4-58.8
    Very high15(17.9)11.1-27.412(17.4)8.6-23.93(6.4)2.2-17.2
    Dedication       
    Very low0(0.0)0.0-4.44(4.9)1.9-11.92(4.3)1.2-14.20.013
    Low6(7.1)3.3-14.715(18.3)11.4-28.08(17.0)8.9-30.1
    Medium29(34.5)25.2-45.227(32.9)23.7-43.718(38.3)25.8-52.6
    High32(38.1)28.4-48.413(15.9)9.5-25.316(34.0)22.2-48.3
    Very high17(20.2)28.4-48.410(12.2)6.8-21.03(6.4)2.2-17.2
    Absorption       
    Very low0(0.0)0.0-4.44(4.9)1.9-11.90(0.0)0.0-7.60.000
    Low2(2.4)0.7-0.816(19.5)12.4-29.44(8.5)3.4-19.9
    Medium22(29.8)18.0-36.522(26.8)18.4-37.324(51.0)37.2-64.7
    High43(51.2)40.7-61.618(22.0)14.4-32.115(31.9)20.4-46.2
    Very high17(20.2)13.0-30.09(11.0)5.9-19.64(8.5)3.4-19.9
    Engagement       
    Very low0(0.0)0.0-4.43(3.7)1.3-10.21(2.1)0.4-11.10.002
    Low2(2.4)0.7-0.814(17.1)10.5-26.66(12.8)6.0-25.2
    Medium25(29.8)21.0-40.226(31.7)22.6-42.419(40.4)27.6-54.7
    High47(56.0)45.3-66.119(23.2)15.4-33.418(38.3)25.8-52.6
    Very high10(11.9)6.6-20.57(8.5)4.2-16.63(6.4)2.2-17.2
     PrWC (n = 84)PrBC (n = 83)PuWC (n = 47)p-value
     n (%)95% CIn (%)95% CIn (%)95% CI
    Passive14(16.7)10.2 - 26.14(4.8)1.9 - 11.75(10.6)4.6 - 22.60.046
    Low strain20(23.8)16.0 - 33.922(26.5)18.2 - 36.911(23.4)13.6 - 37.2
    High strain21(25.0)17.0 - 35.27(8.4)4.1 - 16.410(21.3)12.0 - 34.9
    Active29(34.5)25.2 - 45.237(44.6)34.4 - 55.321(44.7)31.4 - 58.8
     PrWC (n = 60)PrBC (n = 63)PuWC (n = 47)p-value
     n (%)95% CIn (%)95% CIn (%)95% CI
    Neck25(41.7)30.1 - 54.317(27.0)17.6 - 39.013(27.7)16.9 - 41.80.159
    Shoulder20(33.3)22.7 - 45.914(22.2)13.7 - 33.913(27.7)16.9 - 41.80.387
    Upper back16(26.7)17.1 - 39.010(15.9)8.9 - 26.810(21.3)12.0 - 34.90.342
    Elbow5(8.3)3.6 - 18.104(6.3)2.5 - 15.203(6.4)2.2 - 17.20.892
    Lower back17(28.3)18.5 - 40.811(17.7)10.0 - 28.618(38.3)25.8 - 52.60.056
    Wrist/Hand6(10.0)4.7 - 20.17(11.1)5.5 - 21.211(23.4)13.6 - 37.20.098
    Table 1 Personal and demographic characteristics for the groups and the total sample

    The sample size is indicated for each group.

    Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.

    Table 2 Utrecht Work Engagement Scale (UWES) data from the groups

    Number of cases (%). 95% confidence interval (CI 95%). and statistical results (Qui-Square test) are presented.

    Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.

    Table 3 Results of the Job Content Questionnaire from private and public workers

    Number of cases (%). 95% confidence interval (CI 95%). and statistical results (chi square test) are presented.

    Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.

    Table 4 Results of the 7 days symptoms for private and public workers

    Number of cases (%), 95% confidence interval (CI 95%), and statistical results (chi square test) are presented.

    Private white-collar – PrWC, private blue-collar – PrBC, public white-collar – PuWC.


    Ann Occup Environ Med : Annals of Occupational and Environmental Medicine
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