Submitted:
15 July 2025
Posted:
15 July 2025
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Abstract
Background and objectives: Musculoskeletal disorders (MSDs) are the most common work-related diseases in Korea, yet nation-wide estimations of their occupational burden remain scarce. This study aimed to (1) assess the prevalence and distribution of MSD symptoms by body part; (2) construct a body-part–specific job exposure matrix (JEM) for ergonomic risk factors using representative national data; (3) validate the JEM through expert consensus; and (4) examine dose–response relationships be-tween exposure intensity and MSD symptoms. Materials and Methods: We analyzed data from 215,000 Korean workers across five waves (2006–2020) of the Korean Working Conditions Survey (KWCS). A JEM was created based on self-reported ergo-nomic exposures by occupational category. Expert review and agreement statistics were used to validate exposure estimates. Logistic regression was applied to evaluate associations between exposure levels and MSD symptoms. Results: Symptoms were re-ported in the upper extremities and neck (35.3%), back (20.3%), and lower extremities (24.6%), with over 40% of respondents experiencing symptoms in multiple body parts. The JEM showed strong agreement with expert ratings (κ ≥ 0.80 for upper body and back), and exposure intensity was positively associated with symptom prevalence, particularly in the upper body and back. Occupations such as crop growers and construction workers had high levels of both exposure and symptom burden. Conclusions: This study developed and validated the first body-part–specific ergonomic JEM for Korean workers using nationally representative data. Findings support data-driven prioritization of high-risk occupations and provide a foundation for future surveillance and prevention of work-related MSDs in Korea.
Keywords:
Exposure assessment
; Job classification
; Risk assessment
; ergonomic risk factors
; Exposure-response relationship
; Workplace risk evaluation
1. Introduction
Musculoskeletal disorders (MSDs) represent the most common occupational disease in Korea, accounting for more than 60% of compensated cases [1,2]. Despite increasing recognition of occupational diseases in recent years, disputes over the work-relatedness of MSDs persist. One reason for this is the inherent difficulty in quantifying ergonomic risk exposures that vary widely across job categories. MSDs are also influenced by multiple factors, including ergonomic, individual, and psychosocial characteristics, which further complicates occupational attribution [3].
A comprehensive understanding of MSD burden across job groups is essential for prioritizing high-risk occupations and informing preventive strategies. However, direct measurement of exposure in large populations is rarely feasible. As a solution, Job Expo-sure Matrices (JEMs) have emerged as practical tools for estimating exposure to occupational risk factors based on job classifications [4]. JEMs have been successfully constructed for a variety of hazardous agents such as asbestos [5,6,7], noise [8,9], job stress [10,11], and solvents [12,13].
Compared to chemical and physical hazards, MSDs pose greater challenges for JEM development, as they occur across nearly all industries and occupations. Moreover, the heterogeneous nature of MSDs by body part and the wide range of relevant ergonomic factors makes it difficult to define a single exposure pathway. Attempts to build MSD-specific JEMs began only in the 2010s. France developed the CONSTANCES JEM, consisting of 407 job codes and 27 occupational and ergonomic factors [14]. A Finnish JEM focused on physical effort, heavy lifting, and carrying for 40 job codes [15]. Similar matrices have been constructed in the Netherlands [16] and the United States using O*NET data [17]. Some JEMs have even been designed for specific MSD conditions, such as hip and knee osteoarthritis [18]. However, these JEMs often have limitations in geographic scope, occupational classification, or disease specificity.
In Korea, JEMs have been developed for selected chemical exposures like asbestos, benzene, and trichloroethylene, drawing up-on workplace measurement data. In contrast, no JEM has yet been constructed for ergonomic exposures related to MSDs, mainly due to the absence of nationwide exposure data across occupations. The Korean Working Conditions Survey (KWCS), conducted by the Occupational Safety and Health Research Institute (OSHRI) every three years since 2006, provides nationally representative data on ergonomic exposures and self-reported MSD symptoms. Despite this resource, previous studies using KWCS have either focused on selected job groups or limited anatomical regions, and no attempt has been made to build a nationwide JEM for MSDs.
Therefore, the objectives of this study were to estimate the prevalence and distribution of musculoskeletal disorder (MSD) symptoms across the Korean working population; to construct a body-part–specific Job Exposure Matrix (JEM) for ergonomic risk factors using data from the Korean Working Conditions Survey (KWCS); to validate the developed JEM through expert evaluation; and to examine the dose–response relationships between exposure intensity and MSD symptoms by body part.
2. Materials and Methods
2.1. Data sources and Study Population
The Materials and Methods should be described with sufficient details to allow The KWCS has been carried out six times since 2006. This survey was developed based on the European Working Conditions Survey, and it is conducted triennially to examine the overall working environment, including the type of work, employment, occupation, industry, exposure to risk factors, and employment stability, among workers aged 15 years or older in Korea. The first and second KWCS surveyed only 10,000 people, but 50,000 people have been surveyed since the third KWCS. In this study, data from the 2nd to 6th KWCSs were used. Data from the 1st KWCS, which used a different occupational classification system, has been excluded. A total of 210,500 people were finally selected as subjects, excluding people whose occupations were difficult to classify. The subjects included 9,991 participants of the 2nd KWCS, 49,957 participants of the 3rd KWCS, 49,905 participants of the 4th KWCS, 50,110 participants of the 5th KWCS, and 50,537 participants of the 6th KWCS.
2.2. Job Classification
In this study, the job classification was based on the Korean Standard Classification of Occupations (KSCO) developed by Statistics Korea. Initially, the KWCS data categorized occupations using either the unit group or the detailed occupational categories of the 6th KSCO. Subsequently, for this study, these classifications were updated to align with the unit group categories of the 7th KSCO, the updated version of which was published in 2017.
2.3. Musculoskeletal Risk Factors
To assess the risk factors related to work-related MSDs, questionnaire items about local vibrations among physical risk factors and ergonomic factors were used. To identify MS risk factors related to the upper extremities and neck, the questions included the following: ① Vibrations from hand tools or machines, ② Postures that cause fatigue or pain, and ③ Repetitive hand or arm movements. To identify Musculoskeletal risk factors associated with the lower back, the questions included the following: ① Lifting, pushing or carrying heavy objects, ② Posture that causes fatigue or pain, and ③ Lifting or moving people. The Musculoskeletal risk factors of the lower extremities were examined using questions related to ① Lifting, pushing, or moving heavy objects and ② Prolonged standing posture. The exposure intensity was measured on a 7-point scale. The duration of exposure to risk factors was classified as “high”, “moderate”, or “low” exposure. When the exposure encompassed the entire working hours or most or 3/4th of the working hours, the responses were classified as “high exposure”, and when the duration of exposure was 1/2, or 1/4th of the total working hours, the responses were classified as “moderate exposure”. When the subjects responded, “rarely exposed / never exposed”, these cases were categorized as “low exposure”.
2.4. Development and Validation of the Job Exposure Matrix (JEM)
To evaluate body part–specific ergonomic risk by occupation in the Korean workforce, a Job Exposure Matrix (JEM) was con-structed using questionnaire items from the KWCS. The items were selected to reflect exposure to musculoskeletal risk factors, with three items pertaining to the upper extremities and neck (hand–arm vibration, awkward postures, and repetitive movements), three for the lower back (heavy lifting, awkward postures, and moving people), and two for the lower extremities (heavy lifting and prolonged standing).
Individual-level exposure intensity was determined by combining the responses for each body part. If at least one item was rated as “high” (i.e., exposure for most or all of the working hours), the body part was classified as high exposure. If at least two items were rated as “moderate,” the region was classified as moderate exposure. All other combinations were considered low exposure. These individual responses were then aggregated by job category. For each occupation and body part, if 60% or more of workers were classified as having high exposure, the occupation was assigned a high exposure level for that region. Similarly, if 60% or more were classified as low exposure, the occupation was assigned a low exposure level; all remaining cases were assigned moderate exposure.
This occupation-based classification of exposure levels for each anatomical region constituted the JEM. The JEM was used as an analytic tool to examine occupational patterns of exposure and their association with musculoskeletal symptom prevalence.
To assess the validity of this JEM, two ergonomics experts independently evaluated the exposure intensity for each body part by job category. The experts were provided with the relevant KWCS survey items, KSCO job titles, and job descriptions. Discrepancies between the two assessments were resolved through consensus discussion. Agreement between the expert consensus ratings and the JEM-based estimates was assessed using Cohen’s kappa coefficient. For the upper extremities and neck, as well as the lower back, the level of agreement was high (κ ≥ 0.80), supporting the validity of the JEM classification. For the lower extremities, the level of agreement was moderate, indicating relatively greater uncertainty in this anatomical region [19].
2.5. Relationship Between Exposure and MSD Symptoms
MS symptoms were examined based on responses to questions about the presence or absence of upper extremity and neck pain, low back pain, and lower extremity pain [20]. Although the original KWCS dataset included 210,500 respondents from the 2nd to 6th waves, 2,502 participants were excluded due to missing or unclassifiable occupational codes or incomplete responses to key variables. The final analytical sample consisted of 207,998 individuals. Logistic regression analysis was performed to determine whether there were an exposure-response relationships between exposure intensity by job category and MS symptoms by body parts.
2.6. Statistical Analysis
Statistical analysis was conducted using SAS version 9.4 (SAS Institute Inc., Cary, NC, USA), and the k2 test, t-test, logistic regression analysis, and Cohen’s kappa coefficient analysis were performed.
3. Results
3.1. General Characteristics of the Subjects
The general characteristics of the subjects are shown in Table 1. The 40-49- and 50-59-year age groups accounted for the largest proportion of the subjects. The mean age of the subjects was 48.4 years, and the mean ages of the males and females were 48.1 years and 48.8 years, respectively.
3.2. Distributions of Exposure Intensity by Question
The results of exposure intensity for each question in the questionnaire are shown in Table 2. The standing posture and repetitive hand or arm movements were associated with the highest intensity of exposure, while hand tool or machine vibrations, and activities involving lifting, pushing, or moving heavy objects, were linked to lower levels of high-intensity exposure.
3.3. Distributions of Exposure Intensity by Body Parts
In terms of the exposure intensity of body parts, the greatest amount of high-intensity exposure was to the upper extremities, followed by the neck, lower extremities, and lower back in descending order (Table 3).
3.4. Agreement Between Expert Ratings and JEM-Based Classification
The level of agreement was high (κ ≥ 0.80) for the upper extremities and neck, as well as for the back, supporting the consistency between expert judgment and JEM-based exposure estimates. Agreement for the lower extremities was lower (κ = 0.79), indicating variability or uncertainty in exposure classification for this body part (Table 4).
3.5. Distribution of MSD Symptoms by Exposure Level
Appendix Table S1 presents the overall distribution of musculoskeletal disorder (MSD) symptoms and ergonomic exposure intensity across all 207,998 participants. Among them, 35.3% reported symptoms in the upper extremities and neck, 20.3% in the back, and 24.6% in the lower extremities. A total of 16.8% of participants had a composite MSD score of 1, while 15.5% had a score of 2, and 10.8% reported symptoms in all three body parts (composite score = 3).
Table 5 presents the distribution of work-related musculoskeletal disorder (MSD) symptoms among occupations with the maxi-mum ergonomic exposure score (i.e., total score = 6, comprising 2 points each for all three body parts). These occupations were ranked by the proportion of workers reporting MSD symptoms in all three body parts (symptom score = 1 per region; total score = 3), representing the most severe multi-site burden. The highest prevalence of multi-region MSD symptoms was observed among Crop Growers (32.9%), followed by Agriculture, Forestry and Fishery Related Elementary Workers (31.7%) and Fishery Related Workers (31.1%). Construction-related occupations such as Construction Related Technical Workers (25.8%) and Construction and Mining Laborers (18.6%) also exhibited high proportions of workers with MSD symptoms across all three body parts. Other occupational groups with relatively high symptom prevalence included Cleaners and Sanitation Workers (22.6%), Livestock and Stockbreeding Related Workers (19.9%), and Ship Workers (18.2%). Notably, even among occupations with lower prevalence rates (e.g., Pipe and Sheet Metal Makers, 6.8%), all included workers were exposed to the highest level of ergonomic risk.
3.6. Association Between Exposure Intensity and Musculoskeletal Pain
Table 6 presents the results of logistic regression analyses. In the upper extremities and neck, compared to workers with low exposure, those with medium exposure had 1.57 times higher odds of reporting musculoskeletal pain (95% CI 1.53–1.61), and those with high exposure had over three times the odds (OR = 3.06, 95% CI 2.99–3.14). In the back, the odds of reporting pain were 1.51 times higher for medium exposure (95% CI 1.47–1.55) and 2.28 times higher for high exposure (95% CI 2.21–2.36), compared to the low exposure group. In contrast, for the lower extremities, medium exposure was not positively associated with pain (OR = 0.93, 95% CI 0.90–0.97), whereas high exposure was significantly associated with increased pain (OR = 1.41, 95% CI 1.37–1.45). These results indicate a strong dose–response relationship between exposure intensity and musculoskeletal pain in the upper body and back, but a more attenuated or inconsistent pattern in the lower extremities.
4. Discussion
Our findings reveal that MSD symptoms are highly prevalent, with 35.3% of participants reporting symptoms in the upper extremities and neck, 20.3% in the back, and 24.6% in the lower extremities. Notably, over 40% of respondents experienced symptoms in two or more body regions, highlighting the considerable burden of MSDs in the Korean workforce. When comparing these results to the European Working Conditions Survey (EWCS), it becomes apparent that the burden of MSDs is not unique to Korea. The EWCS reports that 43% of European workers experience back pain, 41% report pain in the shoulders, neck, or upper limbs, and 29% report pain in the lower limbs [21, 22]. Both KWCS and EWCS consistently identify MSDs as the most prevalent work-related health problem, and multi-site symptoms are common in both populations. However, certain differences are also evident. While the prevalence of upper limb and neck symptoms is similar between Korea and Europe, back pain appears to be more frequently reported in Europe. Lower extremity symptoms, although less common, still affect a significant proportion of workers in both regions. These findings underscore the global nature of MSDs and the need for comprehensive prevention strategies tailored to the specific pat-terns observed in each country [23].
The development and validation of the Korean JEM represent a significant advancement in the assessment of ergonomic risk factors. The JEM was constructed based on self-reported ergonomic exposures by occupational category, with validation achieved through expert consensus and high inter-rater agreement (κ ≥ 0.80 for upper extremity and back exposures). This approach is conceptually similar to JEMs developed in France (CONSTANCES JEM), Finland, and the Netherlands. All of these matrices utilize large, nationally representative surveys and standardized occupational codes, relying primarily on self-reported exposure to physical and ergonomic risk factors, and are validated through expert review and statistical agreement measures [14,15,16,17].
Despite these shared features, there are notable differences between the Korean JEM and its international counterparts. The French CONSTANCES JEM, for example, includes 27 physical exposures and is stratified by gender, while the Korean JEM focuses on region-specific exposures and employs a simpler classification system. European JEMs often use more granular occupational codes and in-corporate psychosocial and organizational factors, whereas the Korean JEM currently emphasizes physical ergonomic risks. Interestingly, the agreement between expert ratings and JEM-based classification is slightly higher in the Korean JEM for upper body and back exposures compared to some European JEMs, suggesting robust validity for the Korean model.
High-risk occupational groups reveals that both the KWCS and EWCS identify manual labor occupations—such as agriculture, construction, and manufacturing—as having a particularly high burden of MSDs. In Korea, crop growers, agricultural/forestry/fishery workers, construction laborers, cleaners, and ship workers are among the groups with the highest prevalence of multi-site symptoms, with some groups reporting over 30% of workers affected. Similarly, in Europe, agriculture, construction, manufacturing, and health care sectors are recognized as high-risk, with comparable patterns of multi-site and severe MSD symptoms. Despite these similarities, the prevalence rates within occupational groups may differ due to variations in work organization, ergonomic standards, and reporting practices. For instance, some European countries report higher overall MSD prevalence, which may reflect differences in survey methodology or cultural factors influencing symptom reporting [21,22].
In Korea, over 60% of compensated occupational diseases are MSDs [1,2], yet there are wide regional and inter-expert discrepancies in recognition decisions. These inconsistencies are partly due to the absence of standardized exposure benchmarks. The JEM developed in this study addresses this gap by providing consistent, occupation-specific estimates of ergonomic risk. As such, it can support Korea’s presumption-based system for occupational MSDs and reduce variability in adjudication outcomes. Furthermore, the JEM offers a quantitative framework for OEM physicians, labor authorities, and policymakers to base their decisions on uniform reference points.
The strengths of this study include the use of a large, nationally representative dataset and the construction of a body-part–specific JEM tailored to the Korean occupational context. The inclusion of over 200,000 participants across multiple waves of the KWCS enhances the generalizability of the findings. The body-part -specific approach of the JEM allows for targeted ergonomic interventions and policy recommendations.
However, certain limitations must be acknowledged. The reliance on self-reported exposures and symptoms may introduce recall and reporting bias, a limitation shared with other JEMs. Additionally, the KWCS survey questions may not fully capture biomechanical loads or task-specific risks, particularly for lower extremity exposures. Occupational mis-classification is also possible due to variation in job titles and codes, and the cross-sectional design limits causal inference between exposure and MSD outcomes
To enhance the utility and accuracy of the JEM, future research should incorporate additional dimensions, including psychosocial and organizational stressors. Developing a JEM with more granular occupational classifications—such as 4-digit or 5-digit KSCO codes—could further improve exposure precision. Longitudinal validation using clinical diagnosis, medical claims, or compensation records is also needed to assess predictive validity. In addition, updated JEMs using future waves of KWCS data would ensure its applicability in a rapidly changing labor market.
5. Conclusions
This study presents the first nationwide estimation of musculoskeletal disorder (MSD) burden across occupational groups in Korea using data from the Korean Working Conditions Survey (KWCS). By constructing and validating a body-region–specific Job Exposure Matrix (JEM), we quantified ergonomic exposure intensities and demonstrated their association with MSD symptom prevalence. The JEM showed high agreement with expert assessments and revealed dose–response relationships for several body regions. Furthermore, we identified specific occupations with both high exposure intensity and high symptom burden, providing a data-driven basis for targeting future preventive efforts. These findings lay the groundwork for improving occupational MSD surveillance and prioritizing high-risk groups for intervention.
Supplementary Materials
The following supporting information can be downloaded at the website of this paper posted on Preprints.org, Table S1: Intensity of exposure to musculoskeletal risk factors by occupation and area according to the order of the 7th KSCO Korean job title.
Author Contributions
Conceptualization, Y.K. and D.K.; methodology, Y.K. and D.K.; validation, S-Y.K. and Y-H.L.; formal analysis, E-S.L. and Y-J.K.; data curation, M-H.K. and Y-H.L.; visualization, E-S.L. and Y-J.K.; supervision, Y.K.; funding acquisition, Y.K.; Writing - original draft, E-S.L. and Y.K.; Writing - review & editing, D.K. and S-Y.K. All authors have read and agreed to the published version of the manuscript.
Funding
This research was supported by 2-year Research Grant of Pusan National University (2025). The funders were not involved in the study design, analysis, interpretation of data, writing, or submission of this manuscript. Authors declare there were no conflicts of interest.
Institutional Review Board Statement
Ethical review and approval were waived for this study due to KWCS data were open with anonymity (IRB No. 55-2024-108 and 22 August 2024).
Informed Consent Statement
Not applicable.
Data Availability Statement
The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author/s.
Acknowledgments
We thank Safety and Health Policy Research Department (Occupational Safety and Health Research Institute) for offering raw-data of KWCS (Korean Working Conditions Survey). The paper's contents are solely the responsibility of the author and do not necessarily represent the official vies of the OSHRI.
Conflicts of Interest
The authors declare no conflicts of interest.
Abbreviations
| MSDs | Musculoskeletal disorders |
| JEM | Job Exposure Matrix |
| CONSTANCES JEM | Cohorte des consultants des Centres d’examens de santé JEM |
| KWCS | The Korean Working Conditions Survey |
| OSHRI | The Occupational Safety and Health Research Institute |
| KSCO | The Korean Standard Classification of Occupations |
Appendix Table S
Table S1. Intensity of exposure to musculoskeletal risk factors by occupation and area according to the order of the 7th KSCO Korean job title.
References
- Ministry of Employment and Labor. The status of industrial accident and disease in 2021.
- Cha, E.W.; Jung, S.M.; Lee, I.H.; Kim, D.H.; Choi, E.H.; Kim, Y.K.; Kim, I.A.; Lee, K.J.; Kang, Y.W.; Kim, H.G.; Kim, Y.K. Approval status and characteristics of work-related musculoskeletal disorders among Korean workers in 2020. Ann Occup Environ Med. 2022, 34, e31. [Google Scholar] [CrossRef] [PubMed]
- Lim, H.W.; Rho, Y.M.; Lee, W.C. The construction of job exposure matrix. J Korean Soc Occup Environ Hyg. 2001, 11, 161–168. Available online: https://koreascience.kr/article/JAKO200120567258418.page.
- Choi, S.J.; Kang, D.M.; Park, D.U.; Lee, H.H.; Choi, B.K. Developing asbestos job exposure matrix using occupation and industry specific exposure data (1984-2008) in Republic of Korea. Saf Health Work. 2017, 8, 105–115. [Google Scholar] [CrossRef] [PubMed]
- Kamiya, H.; Peters, S.; Sodhi-Berry, N,; Reid, A.; Gordon, L.; Klerk, N.; Brims, F.; Musk, A.W.; Franklin, P. Validation of an asbestos job-exposure matrix (AsbJEM) in Ausralia: exposure-response relationship for malignant mesothelioma. Ann Work Expo Health. 2019, 63, 719-728. [CrossRef]
- Asbestos exposure data of the Netherlands. Available online: https://www.asbestkaart.nl (accessed on 1 October 2019).
- Kang, D.M.; Jung, S.M.; Kim, Y.J.; Kim, J.Y.; Choi, S.J.; Kim, S.Y.; Kim, Y.K. Reconstruction of the Korean asbestos job exposure matrix. Saf Health Work. 2021, 12, 74–95. [Google Scholar] [CrossRef] [PubMed]
- Stokhom, Z.A.; Erlandsen, M.; Schlunssen, V.; Basinas, I.; Bonde, P.J.; Peters, S.; Brandt, J.; Vestrgaard, J.M.; Kolstad, H.A. A quantitative general population job exposure matrix for occupational noise exposure. Ann Work Expo Health. 2020, 64, 604–613. [Google Scholar] [CrossRef] [PubMed]
- Neitzel, R.L.; Andersson, M.; Eriksson, H.; Toren, K.; Andersson, E. Development of job exposure matrix for noise in the Swedish soft tissue paper industry. Ann Work Expo Health. 2018, 62, 195–209. [Google Scholar] [CrossRef] [PubMed]
- Milner, A.; Niedhammer, I.; Chastang, J.F.; Spittal, M.J.; LaMontagne, A.D. Validity of a job-exposure matrix for psychosocial job stressors: Results from the household income and labour dynamics in Australia survey. PLoS One. 2016, 11, e0152980. [Google Scholar] [CrossRef] [PubMed]
- Niedhammer, I.; Chastang, J.F.; Levy, D.; David, S.; Degioanni, S.; Theorell, T. Study of the validity of a job-exposure matrix for psychosocial work factors: results from the national French SUMER survey. Int Arch Occup Environ Health. 2008, 82, 87–97. [Google Scholar] [CrossRef] [PubMed]
- Gomez, M.R.; Cocco, P.; Desemeci, M.; Stewart, P.A. Occupational exposure to chlorinated aliphatic hydrocarbons: job exposure matrix. Am J Ind Med. 1994, 26, 171–183. [Google Scholar] [CrossRef] [PubMed]
- Sadhra, S.S.; Kurmi, O.P.; Chambers, H.; Lam, K.B.; Fishwick, D. Development of an occupational airborne chemical exposure matrix. Occup Med. 2016, 66, 358–364. [Google Scholar] [CrossRef] [PubMed]
- Evanoff, B.A.; Yung, M.; Buckner-Petty, S.; Andersen, J.H.; Roquelaure, Y.; Deschatha, A.; Dale, A.M. The CONSTANCES job exposure matrix based on self-reported exposure to physical risk factors: development and evaluation. Occup Environ Med. 2019, 76, 398–406. [Google Scholar] [CrossRef] [PubMed]
- Ervasti, J.; Pietiläinen, O.; Rahkonen, O.; Lahelma, E.; Kouvonen, A.; Lallukka, T.; Mänty, M. Long-term exposure to heavy physical work, disability pension due to musculoskeletal disorders and all-cause mortality: 20-uear follow-up introducing Helsinki health study job exposure matrix. Int Arch Occup Environ Health. 2019, 75, 337–345. [Google Scholar] [CrossRef] [PubMed]
- Madsen, I.E.H.; Gupta, N.; Budtz-Jørensen, E.; Bonde, J.P.; Framke, E.; Flachs, E.M.; Petersen, S.B.; Svane-Petersen, A.C.; Holtermann, A.; Rugulies, R. Physical work demands and psychosocial working conditions as predictors of musculoskeletal pain: a cohort sutyd comparing self-reported and job exposure matrix measurements. Occup Environ Med. 2018, 75, 752–758. [Google Scholar] [CrossRef] [PubMed]
- Dale, A.M.; Ekenga, C.C.; Buckner-Petty, S.; Merlino, L.; Tshiese, M.S.; Bao, S.; Meyers, A.S.; Harris-Adamson, C.; Kapellusch, J.; Eisen, E.A.; Gerr, F.; Hegmann, K.T.; Silverstein, B.; Garg, A.; Rempel, D.; Zeringue, A.; Evanoff, B.A. Incident CTS in a large pooled cohort study: associations obtained by a job exposure matrix versus associations obtained from observed exposures. Occup Environ Med. 2018, 75, 501–506. [Google Scholar] [CrossRef] [PubMed]
- Rubak, T.S.; Svendsen, S.W.; Andersen, J.H.; Haahr, J.P.L.; Kryger, A.; Jensen, L.D.; Frost, P. An expert-based job exposure matrix for large scale epidemiologic studies of studies of primary hip and knee osteoarthritis: the lower body JEM. BMC Musculoskeletal Disord. 2014, 15, 204. [Google Scholar] [CrossRef] [PubMed]
- Park, C.U.; Kim, H.J. Measurement of inter-rater reliability of systematic review. Hangyang Med Rev. 2515, 35, 44–49. [Google Scholar] [CrossRef]
- Cho, Y.H. Data resource profile: the Korean Working Conditions Survey (KWCS). Ann Occup Environ Med. 2023, 35, e49. [Google Scholar] [CrossRef] [PubMed]
- Eurofound. Fifth European Working Conditions Survey (EWCS) (2017); EU-OSHA (2019). Available online: https://www.eurofound.europa.eu/en/surveys/european-working-conditions-surveys-ewcs (accessed on 7 July 2025).
- European Agency for Safety and Health at Work. Work-related musculoskeletal disorders: prevalence, costs and demographics in the EU. Available online: https://osha.europa.eu/sites/default/files/Work_related_MSDs_prevalence_costs_and_demographics_in_EU_summary.pdf (accessed on 7 July 2025).
- Park, J.; Lee, N. First Korean Working Conditions Survey: a comparison between South Korea and EU countries. Ind Health. 2009, 47, 50–54. [Google Scholar] [CrossRef] [PubMed]
Table 1.
General characteristics of the subjects.
| Age | Gender | Total | p value | |
|---|---|---|---|---|
| Male | female | |||
| <30 | 9,825 (9.23%) | 10,452 (10.05%) | 20,277 (9.63%) | <0.01* |
| 30 ≤ age < 40 | 22,115 (20.77%) | 17,929 (17.23%) | 40,044 (19.02) | |
| 40 ≤ age < 50 | 26,721 (25.10%) | 26,694 (25.66%) | 53,415 (25.38%) | |
| 50 ≤ age <60 | 24,589 (23.10%) | 25,925 (24.92%) | 50,514 (24.00%) | |
| 60 ≤ age | 23,217 (21.81%) | 23,033 (22.14%) | 46,250 (21.97%) | |
| Total | 106,467 (100%) | 104,033 (100%) | 210,500 (100%) | |
| Mean (SD) | 48.10 (±14.03) | 48.80 (±14.50) | 48.44 (±14.30) | <0.01** |
* k2 test;** t-test
Table 2.
Distributions of exposure intensity by survey items.
| Question | High exposure | Medium exposure |
Low exposure | p value |
|---|---|---|---|---|
| Vibration from hand tools, machines, etc. | 17,377 (8.26%) | 33,581 (15.95%) | 159,542 (75.79%) | <0.01* |
| Postures that cause fatigue or pain |
38,072 (18.09%) | 70,259 (33.38%) | 102,169 (48.54%) | |
| Lifting, pushing, or moving heavy objects | 19,563 (9.28%) | 65,269 (31.01%) | 125,695 (59.71%) | |
| Standing posture | 64,982 (30.87%) | 77,776 (36.95%) | 67,742 (32.18%) | |
| Repetitive hand or arm movements |
52,584 (39.23%) | 59,879 (28.45%) | 68,037 (32.32%) |
* k2 test;
Table 3.
Distributions of exposure intensity by body parts.
| Body parts | High exposure | Medium exposure |
Low exposure | p value |
|---|---|---|---|---|
| Upper extremity and neck |
93,082 (44.22%) | 35,627 (16.92%) | 87,791 (38.86%) | <0.01* |
| Back | 33,373 (15.85%) | 64,746 (30.76%) | 112,381 (53.39%) | |
| Lower extremity | 69,774 (33.15%) | 74,661 (35.47%) | 66,065 (31.38%) |
* k2 test
Table 4.
Cohen and Fleiss kappa coefficient between JEM and 2 ergonomists.
| Body parts | JEM and Ergonomist 1α |
JEM and Ergonomist 2α |
JEM and results of consensusα |
|---|---|---|---|
| Upper extremity and neck |
0.93 | 0.87 | 0.93 |
| Back | 0.89 | 0.89 | 0.96 |
| Lower extremity | 0.83 | 0.74 | 0.79 |
∝ Cohen’s kappa coefficient
Table 5.
High risk occupations with maximum ergonomic exposure (score = 6) ranked by the prevalence of MSD symptoms in all three body parts.
Table 5.
High risk occupations with maximum ergonomic exposure (score = 6) ranked by the prevalence of MSD symptoms in all three body parts.
| KSCO | Occupation | Total | Symptoms in all 3 body parts | ||
|---|---|---|---|---|---|
| 1-digit code | 3-digit code | n | n | % | |
| 6 | 611 | Crop Growers | 18,702 | 6,150 | 32.9 |
| 9 | 991 | Agriculture, Forestry and Fishery Related Elementary Workers |
665 | 211 | 31.7 |
| 6 | 630 | Fishery Related Workers | 525 | 163 | 31.1 |
| 7 | 782 | Construction Related Technical Workers | 442 | 114 | 25.8 |
| 9 | 941 | Cleaners and Sanitation Workers | 7,469 | 1,691 | 22.6 |
| 6 | 613 | Livestock and Stockbreeding Related Workers | 502 | 100 | 19.9 |
| 7 | 781 | Construction Structure Related Technical Workers |
61 | 12 | 19.7 |
| 6 | 620 | Forestry Related Workers | 78 | 15 | 19.2 |
| 9 | 910 | Construction and Mining Laborers | 2,082 | 387 | 18.6 |
| 8 | 876 | Ship Workers and Related Workers | 11 | 2 | 18.2 |
| 7 | 784 | Mining and Civil Engineering Related Technical Workers |
84 | 14 | 16.7 |
| 6 | 612 | Horticultural and Landscape Workers | 435 | 64 | 14.7 |
| 7 | 741 | Die and Mold Makers, Metal Casting Workers and Forge Hammersmiths | 177 | 25 | 14.1 |
| 9 | 921 | Loading and Lifting Elementary Workers | 479 | 67 | 14.0 |
| 7 | 783 | Construction Finishing Related Technical Workers | 2,265 | 301 | 13.3 |
| 9 | 930 | Production Related Elementary Workers | 1,708 | 211 | 12.4 |
| 7 | 772 | Broadcasting and Telecommunications Equipment Related Fitters and Repairers |
1,609 | 192 | 11.9 |
| 7 | 743 | Welders | 976 | 97 | 9.9 |
| 8 | 841 | Metal Casting and Metal Processing Related Operators | 383 | 38 | 9.9 |
| 7 | 751 | Automobile Mechanics | 2,004 | 173 | 8.6 |
| 8 | 891 | Wood and Paper Related Machine Operators | 328 | 28 | 8.5 |
| 8 | 854 | Transportation Vehicle and Machine Related Assemblers | 2,240 | 189 | 8.4 |
| 7 | 792 | Plumbers | 565 | 46 | 8.1 |
| 7 | 730 | Wood and Furniture, Musical Instrument and Signboard Related Trade Occupations | 491 | 38 | 7.7 |
| 7 | 752 | Transport Equipment Mechanics | 324 | 23 | 7.1 |
| 7 | 762 | Electricians | 1,169 | 81 | 6.9 |
| 7 | 742 | Pipe and Sheet Metal Makers | 44 | 3 | 6.8 |
Table 6.
Results of logistic regression between exposure intensity and musculoskeletal pain.
| Body parts | variables | ORγ | 95% CI |
|---|---|---|---|
| Upper extremity and neck | Medium vs low | 1.57 | 1.53-1.61 |
| High vs low | 3.06 | 2.99-3.14 | |
| Back | Medium vs low | 1.51 | 1.47-1.55 |
| High vs low | 2.28 | 2.21-2.36 | |
| Lower extremity | Medium vs low | 0.93 | 0.90-0.97 |
| High vs low | 1.41 | 1.37-1.45 |
ɣ Age and gender were adjusted
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