Morbidity

The overall incidence rate and prevalence of upper extremity musculoskeletal disorders are not known; however, reports from insurance companies, clinics, and work sites suggest that these disorders approach epidemic proportions and are a major cause of lost work in some settings. Studies by Zollinger and by Conn suggested that tendinitis was a major cause of lost work and insurance claims. In studies of medical clinic records for two separate military groups assigned to manual agricultural work in Great Britain, tendinitis was found to have developed in approximately 30% of workers within several months. Reed and Harcourt reported that 70 cases of tenosynovitis accounted for 0.54% of all visits at a U.S. industrial clinic located in the Midwest. Thompson and colleagues reported that 466 of 544 peritendinitis and tenosynovitis patients seen from 1941 to 1950 at a British hospital and outpatient service were manual workers and agricultural workers.

Upper extremity musculoskeletal disorders affect workers in a wide variety of occupations. Barnhart and colleagues used a cross-sectional study to examine the relationship between repetitive work and CTS among ski manufacturing workers. The jobs at the assembly plant were classified as repetitive or nonrepetitive, and health data were collected on 173 workers. Health data were collected using a self-administered questionnaire, a physical examination, and electrophysiologic testing. Three different case definitions were used to determine the presence of CTS. For workers in repetitive jobs, CTS was present in one or both hands in 15.4%, but among workers in nonrepetitive jobs, the rate was 3.1%.

A cross-sectional investigation was conducted to compare the prevalence of musculoskeletal disorders among supermarket cashiers and other supermarket workers. The ergonomic evaluation of the workstations showed that the supermarket cashiers had repetitive jobs with awkward postures. A logistic regression analysis found a significantly higher odds ratio (OR) for the rate of shoulder- and hand-related musculoskeletal disorders among the cashiers compared with other supermarket workers.

Workers from both strenuous and nonstrenuous manual jobs in a meat-processing company ( n = 715) participated in a cross-sectional study to determine the incidence of tenosynovitis or peritendinitis and epicondylitis. Nonstrenuous manual jobs were positions such as supervisors, executives, salespeople, and accountants. The strenuous manual jobs included job titles such as packer, sausage maker, and meat cutter. The rate of tenosynovitis or peritendinitis and epicondylitis was as high as 21.4 cases per 100 person-years for strenuous jobs (the rate ranged from 5.2 to 21.4 cases per 100 person-years) and as low as 0.7 cases per 100 person-years for the nonstrenuous jobs (the rate ranged from 0.7 to 1.1 cases per 100 person-years).

Hagberg and colleagues reviewed 21 studies describing the prevalence of CTS in various occupational groups. The prevalence of CTS in the different occupational groups ranged from 0.6% to 61%. The job titles with the highest rates included grinders, butchers, grocery store workers, frozen food factory workers, and platers. Jobs that require repetitive use of the hands and forceful gripping accounted for at least 50% and as much as 90% of all the CTS cases.

Latko and colleagues completed a cross-sectional study of the relationship between repetitive work and the prevalence of upper limb musculoskeletal disorders and discomfort. Repetition and other ergonomic exposure risk factors were rated on a 10-point scale where 0 corresponded to no stress and 10 corresponded to maximum stress. Three hundred fifty-two industrial workers from three companies participated in the study. Medical examinations and questionnaires were completed by all study participants. Repetition was found to be significantly associated with the prevalence of reported discomfort (OR = 1.17 per unit of repetition), tendinitis in the distal upper extremity (OR = 1.23 per unit of repetition), and symptoms consistent with CTS (OR = 1.16 per unit of repetition).

Roquelaure and colleagues estimated the incidence of CTS in a general population to determine the proportion of cases that could be attributed to work. This was a 3-year study and was conducted in Maine and Loire regions of France among people aged 20 to 59 years old. Study participants were recruited by treating physicians after the diagnosis of CTS was made. Data were obtained from study participants using a self-administered questionnaire that contained questions regarding medical, surgical, and employment history. A total of 1168 cases (1644 wrists) were affected by CTS and included in this study. The data from this study show a higher incidence of CTS in the working than the nonworking population. In addition, the attributable fraction of work among the exposed persons (AFE) in the development of CTS was significant for blue collar workers (women, AFE = 66.6%, and men, AFE = 76.4%) and for lower grade white-collar workers (women, AFE = 60.5%). The prevalence of upper extremity musculoskeletal disorders in the working population of France’s Pays de la Loire region was assessed during the period 2002 to 2003. Study participants were recruited from the clinics of occupational physicians who had attended a training program to standardize the physical examination. Workplace exposures were assessed using a self-administered questionnaire. More than 50% of the 2685 study participants experienced nonspecific musculoskeletal symptoms in the preceding 12 months and approximately 30% experienced symptoms in the past week. In addition, the prevalence of clinically diagnosed musculoskeletal disorders was high. Approximately 13% of participating workers experienced at least one musculoskeletal disorder, and a high percentage of the cases could be classified as probably work related (95% in men and 89% in women younger than age 50, and 87% in men and 69% in women older than age 50).

The American Conference of Governmental Industrial Hygienists (ACGIH) threshold limit values (TLVs) for hand activity level (discussed later) have been used in epidemiological studies to assess the prevalence of symptoms or disease among workers in the three exposure categories. The Italian study was conducted among 3578 blue-collar industrial workers. Workplace exposure was determined by ergonomics professionals using the ACGIH TLVs, and medical outcomes were determined by occupational physicians (baseline and 12-month follow-up) using interviews, physical examinations, and nerve conduction studies. There was a threefold increase in the risk of CTS in industrial workers who performed jobs with exposure above the ACGIH TLVs, compared with industrial workers who performed jobs with exposure below the action limit. A cross-sectional study was conducted by American researchers to assess the validity of the ACGIH TLVs with respect to symptoms and musculoskeletal disorders among 908 industrial and clerical workers. Workplace exposure was determined by ergonomics professionals, and medical outcomes were determined by health care professionals using physical examinations, self-administered questionnaires, and nerve conduction studies. In this study, symptoms did not significantly vary based on TLV category and the prevalence of symptoms, and disorders were substantial in jobs that were below the ACGIH TLV action limit (acceptable zone). However, elbow/forearm tendinitis and CTS were associated with TLV category.

Several literature reviews to examine the epidemiologic evidence of work-related musculoskeletal disorders have been completed. Bernard and colleagues from the National Institute of Occupational Safety and Health concluded that “a substantial body of credible epidemiologic research provides strong evidence of an association between MSDs (musculoskeletal disorders) and certain work-related physical factors when there are high levels of exposure and especially in combination with exposure to more than one physical factor.” Based on the peer-reviewed literature, Punnett and Wegman reported that “there is an international near-consensus that musculoskeletal disorders are causally related to occupational stressors, such as repetitive and stereotyped motions, forceful exertions, non-neutral postures, vibration, and combinations of these exposures.” Palmer and colleagues reviewed literature related to CTS and its relation to occupation. They concluded that there was reasonable and/or substantial evidence that physical workplace factors were related to the development of CTS. The National Research Council concluded that (1) there is a strong association between high levels of physical work factors and the incidence of reported pain, injury, loss of work, and disability; (2) there is strong biological evidence to believe that there is a relationship between the incidence of musculoskeletal disorders and workplace risk factors; and (3) research clearly demonstrates that interventions can reduce the incidence of musculoskeletal disorders among workers who are exposed to high levels of workplace risk factors.

The Bureau of Labor Statistics of the U.S. Department of Labor reports the incidence rate of musculoskeletal disorders involving days away from work among full-time workers ( Fig. 139-2 ). The government record keeping and reporting rules changed in 2001. Consequently, it is difficult to compare current data with historical data. The incidence rate of musculoskeletal disorders has decreased slightly between 2002 (55.3 cases/10,000 workers) and 2006 (39 cases/10,000 workers) (see Fig. 139-2 ). However, musculoskeletal disorders are a leading cause of work absences and accounted for 30% of the injuries and illnesses with days away from work in both 2005 and 2006. The estimated annual costs associated with work-related musculoskeletal disorders vary. However, experts agree that a reasonable figure is approximately $50 billion annually.

The incidence rate (cases per 10,000 workers) of musculoskeletal disorders for U.S. workers.

A conceptual model for the pathogenesis of work-related musculoskeletal disorders has been developed. This model contains sets of cascading exposure, dose, capacity, and response variables, such that the response at one level can act as a dose at the next level. Because there are currently no dose–response data relating occupational risk factors and the incidence of upper extremity musculoskeletal disorders, systematic job analysis is necessary to identify the risk factors before one can develop interventions.

Disability Associated With Work-Related Musculoskeletal Disorders

Disability associated with work-related musculoskeletal disorders is a problem for employers, workers, society, and families. Musculoskeletal disorders are the leading cause of workplace absences. In addition, workplace disability duration of 160 days for workers with CTS in Washington State has been reported. The symptoms associated with work-related musculoskeletal disorders are often not completely resolved for many injured workers. Researchers reported that workers’ compensation claimants with upper extremity musculoskeletal disorders continued to have persistent symptoms that interfered with work (53%), sleep (44%), and home/recreation activities (64%) up to 4 years after injury. The cost to employers for disability associated with work-related musculoskeletal disorders is great. These authors estimate the direct cost of workers’ compensation costs associated with musculoskeletal disorders to be $20 billion. Less than half of work-related musculoskeletal disorders are reported, so the costs associated with disability are considerably greater.

Many conceptual models have been developed to show the interaction between the various factors that affect disability and return to work. Historically, three different perspectives have influenced the development of these models and include biomedical, biopsychosocial, and social construction. More recently, the Institute of Medicine and the World Health Organization developed integrative models that include many of the salient features of other models. The integrative models include factors relating to both the workplace and the person. The aspects that affect the workplace include external loads, organizational factors, and the social context. The aspects of the person (individual factors) identified in this model include biomechanical loading (internal loads and physiologic responses), internal tolerances (mechanical strain and fatigue), and outcomes (pain, discomfort, impairment, disability).

Job Documentation

Before ergonomic stresses can be identified, one must document what the worker does. This entails the following:

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  The work objective

  
  
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  The work standard

  
  
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  The work method

  
  
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  Workplace layout

  
  
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  Work equipment

  
  
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  Materials

Repeated and Sustained Exertions

Repetitiveness of work is one of the most commonly cited risk factors of upper extremity musculoskeletal disorders. As early as 1927, Obolenskaja and Goljanitzki talked about hand motions per minute and per shift as factors of tendinitis. In 1934, Hammer defined repetitiveness in terms of the manipulations per hour. Later, in 1979, Kuorinka and Koskinen defined repetitiveness in terms of the number of parts handled per year. Armstrong and colleagues and Silverstein and colleagues defined repetitiveness in terms of fundamental cycles to relate physiologic measures to work measures.

A repetitive job can be defined as simply a task in which the worker performs the same acts or motions over and over again. Examples of repetitious jobs include entering data into a computer, assembling products on an assembly line, washing windows, and loading parts into a press or onto a conveyor belt ( Box 139-3 ). Sustained exertions are found whenever some worker body part must maintain the same position throughout each work cycle or for prolonged time periods. Static upper extremity positions are often identified in data entry work in which the arms are positioned over the keyboard for a large percentage of the work day or in manufacturing assembly tasks in which the worker holds the power tool in his or her hand for most of the work day.

Box 139-3

Examples of Repetitive Exertions

Job documentation information often can be used to evaluate the ergonomic risk factors. Specifically, for analyzing the repetitiveness of a job, various methods can be used. For many jobs, the number of exertions per part can be calculated from the work method. The total number of exertions per unit time then can be computed from production information such as standard times or records of parts produced. For example, as part of the assembly of a door-locking mechanism, the repetition of the job was calculated as the number of elements in the work method multiplied by the number of panels per hour ( Table 139-1 ).

The work method may or may not indicate whether the hand is in use. Consequently, one must observe the worker performing the job. The observer then can rate the repetition of the job using the 10-point scale depicted in Figure 139-3 . The use of this rating scale makes it possible to compare jobs that may have dramatically different quantities of work elements. In addition to observer ratings, workers may rate their perception of the effort required to keep up with jobs. Visual analog scales can be used as a standardized method to assess workers’ perceptions. The analyst must not suggest how the worker should respond.

Ten-point visual analog scale used to assess repetition.

(From ACGIH. 2006 Threshold Limit Values for Chemical Substances and Physical Agents and Biological Exposure Limits. Cincinnati, OH: American Conference of Governmental Industrial Hygienists, 2006; Latko WA, Armstrong TJ, Foulke JA, et al. Development and evaluation of an observational method for assessing repetition in hand tasks. Am Ind Hyg Assoc J. 1997;58:278–285.)

Forceful Exertions

Virtually all hand activities involve the exertion of force to propel or stabilize the fingers and wrist against gravity, inertia, and external loads. These forces are produced by the contractile proteins in muscles and transmitted through myofascial sheaths, tendons, bones, and ligaments. These forces require the expenditure of energy and result in elastic and viscous deformation of tissues. Some investigators have observed that the risk of upper extremity musculoskeletal disorders increases with the force of exertion. There is not yet agreement about what constitutes excessive force, and the effect of reducing force cannot be predicted. It should be safe to assume that reducing force probably will have a greater effect if the reduction is applied throughout the work cycle than if it is applied only occasionally. Steps for reducing force should be considered if upper extremity musculoskeletal disorders have been reported for a given job.

Several methods can be used to assess the job force requirements. Force requirements can be identified through observation, or one can use elaborate instrumentation to estimate the force exerted by workers. The methods that can be used to estimate job force requirements include the following:

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  Observation

  
  
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  Rankings (worker and observer)

  
  
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  Ratings (worker and observer)

  
  
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  Direct measurement

  
  
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  Calculation

  
  
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  Electromyography

  
  
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  Identification and ranking of forceful elements

The forceful elements of a job can be identified from the work methods analysis performed in the job documentation. Exertions are required to move, lift, lower, push, pull, slide, connect, secure, use a hand tool, or hold objects against gravity or against reaction forces (see examples in Box 139-4 ). In many cases, information about the tools, materials, and tasks can be used to estimate the minimum force requirements or at least to rank order tasks and tools in terms of their force requirements. For example, holding a 5-kg tool probably will require more force than holding a 2-kg tool. Similarly, all things being the same, tightening bolts to 100 N-m will require more force than to 50 N-m. In addition, moving an object will require more effort than reaching or grasping an object.

Box 139-4

Examples of Forceful Exertions

Analysis of Force Patterns

The analysis of hand force exerted during the entire work cycle can be characterized by identifying the start and stop times of work tasks and estimating or measuring the amount of force exerted by the hands (percentage of maximal voluntary contraction [MVC]) during each task. Three examples of this are shown in Figure 139-4 . These examples correspond to the examples shown in Box 139-3 . For the worker positioning the food bars, the greatest force occurs when holding and positioning several food bars. The force exerted by the window washer varies based on the stroke (up vs. down) and the task (wash, dry with squeegee, wipe spots with towel). The greatest force occurs while washing the windows and using the squeegee horizontally.

A, The amount of estimated force exerted (percentage of maximal voluntary contraction) for the worker getting and positioning food bars (see Box 139-3 for a picture of the job). B, The amount of estimated force exerted (percentage of maximal voluntary contraction) for the worker washing windows (see Box 139-3 for a picture of the job). C, The amount of estimated force exerted (percentage of maximal voluntary contraction) for computer data entry (see Box 139-3 for a picture of the job). Each force peak corresponds to pressing a key.

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