Applied Radiology

Ms. Baker , Ms. Coffin , and Ms. Murphey are Ergonomic Consultants with Sound Ergonomics, LLC, Kenmore WA. Ms. Baker is a member of the Ultrasound Program at Bellevue Community College, Bellevue, WA. Ms. Coffin is the Ultrasound Program Director at Dona Ana Community College, Las Cruces, NM.

Occupational injuries account for up to 60% of all workplace illnesses, according to the United States Department of Labor, costing businesses $20 billion per year. ^1,2 Work-related musculoskeletal disorders (WRMSD), injuries caused by or aggravated by workplace activities, have been described in a number of professions over the years. They have only recently been identified in sonographers, and studies indicate the incidence of sonographer WRMSDs are increasing. The areas most often involved are: the shoulder (76%), neck (74%), and wrist (59%). ³ Knowing this information, it is important
to consider ultrasound equipment design features in addressing the risk factors for WRMSD. Surveys among sonographers in America, Canada, Australia, and the United Kingdom have shown that more than 80% are scanning in pain and 20% have been forced to give up their profession as a result of their injury. ^3,5

Symptoms

Symptoms of WRMSD can occur after months or years of overuse and have been staged according to symptom reversibility and outcome. Stage 1 includes aching and tiredness that subside with overnight rest and do not cause any reduction in work performance. Stage 2 entails recurrent aching and tiredness that do not subside with overnight rest. Symptoms occur earlier in the workday than Stage 1 symptoms and affect performance at work. Finally, Stage 3 symptoms include aching, fatigue, and weakness that result in reduced performance in work and leisure activities. Pain occurs with nonrepetitive movements. These symptoms disturb sleep and may last years. ⁴

Injury Prevention

Since WRMSD is caused by multiple factors, injury prevention requires solutions from many sources. The solutions for musculoskeletal injury can be broken down into three categories: engineering controls, administrative controls, and sonographer solutions.

Engineering Controls

Engineering controls eliminate the presence of risk factors in the workplace through design changes in the equipment. Ancillary equipment is just as important as the rest of the materials in the design of an ergonomic workstation for sonography. Examination tables should be height-adjustable and should have features to address the types of studies being performed, such as stirrups for obstetrical and gynecological work or dropout sections for cardiac scanning. A ceiling- or wall-mounted monitor should be provided for patient viewing. It is not possible for the sonographer to share his/her monitor with the patient and maintain neutral positioning of the neck. Picture archiving and communication systems (PACS) and other computer workstations should also utilize ergonomic guidelines. The computer tower should not hinder access to the keyboard in order to minimize reach requirements.

Adaptive equipment for sonographers includes cushions that support the forearm while scanning to reduce the workload of the neck and shoulder muscles. Prolonged abduction of the arm during scanning is extremely fatiguing and can lead to muscular overload and injury. Transducer cable holders are also available, which reduce torque on the wrist caused by transducer and cable weight.

Administrative Controls

Administrative controls reduce the worker's exposure to risk factors through changes in schedule and workload. Many sonographers do not get any breaks during the day, not even lunch. Sonographers need time for their muscles and tendons to recover between patients. Rotating sonographers' job and task assignments reduces the employee's contact with job hazards. Workload distribution is also important. The same sonographer should not be assigned to bedside studies for the day or assigned to rooms that do specific studies, especially those that are injury producing, such as endovaginal exams. A variety of work and equipment is necessary to allow for the utilization of different muscle groups, hence providing relief.

A reasonable flow of patients with sufficient time to complete the study and its associated paperwork is the most efficient system, and it reduces the risk of injury. Lighting should not be overlooked, as improper light levels and glare lead to poor postural alignment. Dimmer controls in scanning rooms should be easily accessible. Additionally, bedside studies can cause problems for lighting since most patient rooms are not dark enough to prevent glare on the monitor.

Sonographer Solutions

Sonographers can learn how to reduce their exposure to risk factors and to injury-producing actions through ergonomic education and training. The best equipment, if used poorly, will not create an ergonomically designed workstation. Sonographers must learn the risk factors, understand the importance of good postural alignment and examination techniques, and modify their work behaviors accordingly. Certain engineering controls can also be implemented with technique modifications on the part of the sonographer.

The Economics of Ergonomics

The cost of occupational injury to both the employer and the employee is phenomenal. The losses to the employer encompass not only the medical costs of an injury, but also the cost of replacement staff, Worker's Compensation, and loss of revenue. The loss of experienced professionals and a skilled, stable workforce affects productivity. The cost to the worker includes not only monetary hardship, but also the possibility of permanent injury, chronic pain, and loss of their professional career. Table 1 lists the costs of WRMSD and Table 2 lists the costs of investments in ergonomic protection in sonography. However, these costs cannot account for the value of the continuing productivity of a healthy, competent sonographer.

Ergonomics Considerations

There are a variety of ergonomic design elements included in many of the current ultrasound imaging systems on the market. Small platform footprints make it possible to optimize the position of the ultrasound equipment in relationship to the examination table, even in small exam rooms. Ultrasound systems are becoming lightweight and offer height-adjustable consoles, making it easier to obtain the best postural alignment to accommodate sitting or standing positions. Additionally, space under the console allows sonographers to position themselves close to the equipment, minimizing reach. Keyboard layouts providing a "home-based" design position the most commonly used controls in the center of the console to minimize hand motion. Control panels have also been designed with a wrist rest to support the carpal tunnel area. Transducer ports are being placed within a natural reach zone of the sonographer when sitting or standing, decreasing the reaching and bending required in changing transducers. Additionally, transducers and their cables are more flexible and lightweight, which is very important in reducing hand and wrist strain. Some systems also offer multiple options for foot support, which helps to reduce the risk of Achilles tendon problems.

Conclusion

It is now critical to consider ergonomics when designing workstations and purchasing equipment since dollars spent on improving the ergonomic design of the workstation have an excellent return on investment. This investment leads to improved performance of sonographers and improved employee well-being. Additionally, retaining well-trained staff maximizes the efficiency of the department workflow, accuracy, and utilization of interpreting physicians. Ergonomics provides the foundation for effective management and well-trained workers to perform at their best, thus increasing productivity and profits. *