Quality Measures for the Diagnosis and Non-Operative Management of Carpal Tunnel Syndrome in Occupational Settings

Abstract

Introduction: Providing higher quality medical care to workers with occupationally associated carpal tunnel syndrome (CTS) may reduce disability, facilitate return to work, and lower the associated costs. Although many workers’ compensation systems have adopted treatment guidelines to reduce the overuse of unnecessary care, limited attention has been paid to ensuring that the care workers do receive is high quality. Further, guidelines are not designed to enable objective assessments of quality of care. This study sought to develop quality measures for the diagnostic evaluation and non-operative management of CTS, including managing occupational activities and functional limitations. Methods: Using a variation of the well-established RAND/UCLA Appropriateness Method, we developed draft quality measures using guidelines and literature reviews. Next, in a two-round modified-Delphi process, a multidisciplinary panel of 11 U.S. experts in CTS rated the measures on validity and feasibility. Results: Of 40 draft measures, experts rated 31 (78%) valid and feasible. Nine measures pertained to diagnostic evaluation, such as assessing symptoms, signs, and risk factors. Eleven pertain to non-operative treatments, such as the use of splints, steroid injections, and medications. Eleven others address assessing the association between symptoms and work, managing occupational activities, and accommodating functional limitations. Conclusions: These measures will complement existing treatment guidelines by enabling providers, payers, policymakers, and researchers to assess quality of care for CTS in an objective, structured manner. Given the characteristics of previous measures developed with these methods, greater adherence to these measures will probably lead to improved patient outcomes at a population level.

Introduction

Minimizing disability, inappropriate time off work, and their economic sequellae remain major goals of occupational medicine. Several studies have demonstrated the clinical and financial benefits of ergonomic, disability management, and return-to-work interventions [1–3]. In many states, workers’ compensation systems have adopted guidelines to prevent workers from receiving treatments that appear unnecessary, may delay return to work, or may even be harmful. However, less attention has been paid to ensuring that injured workers receive the basic, essential medical care processes involved in making a correct diagnosis, alleviating symptoms, and addressing activities and functional limitations. Better quality medical care would benefit both workers and employers. In one randomized controlled trial in Spain, improving medical care for musculoskeletal conditions reduced time on temporary disability by 37%, the percentage of temporarily disabled workers going onto permanent disability by 50%, and total costs (including disability and medical care) by 37% [4]. Given the potential benefits to workers and employers, several provider organizations and payers would like to see quality assessment and improvement activities become more routine in occupational medicine.

Carpal tunnel syndrome (CTS) should be a key target for such activities because it is prevalent and costly, and because there is indirect evidence of quality deficits. CTS affects three out of every 10,000 full-time workers [5]. For each workers’ compensation claim for CTS, employers pay a median of $1,468 to $11,941 (inflated to 2009), depending on whether surgery is performed [6, 7]. Each worker with CTS experiences a cumulative loss of future earnings equal to $45,000 to $89,000 [8].

For patients with CTS, diagnostic evaluations and non-operative management are highly variable, which may indicate care is of inconsistent quality. Recommended history and physical examination elements are performed inconsistently [9, 10], and physicians differ in the criteria they use to diagnose CTS [11]. This variability in care appears to affect when patients receive a CTS diagnosis and how long they stay off work. A Washington State study found that half of workers’ compensation claims for CTS were initially filed for other conditions, and 20% of the time the CTS was not diagnosed until more than three months into the claim. Later diagnoses were associated with longer disability [6].

To evaluate quality of care for occupational disorders like CTS, specific quality measures are needed. Process-oriented quality measures identify basic, well-established care processes that patients should or should not receive under specific circumstances. The purpose of such measures is not to advance the standard of care but rather to make existing standards explicit and measurable. Although guidelines and measures can both help to standardize and improve care, guidelines cannot be used to measure quality (other similarities and differences between guidelines and measures are explored below). For an occupational condition, a set of quality measures should consider both medical and occupational issues, such as whether a patient’s symptoms are associated with occupational activities and how occupational activities should be modified. Existing sets of measures, such as one set for back pain, often neglect occupational considerations [12].

The objective of this study was to develop a set of quality measures that can be used to objectively assess the quality of the diagnostic evaluation and therapeutic management of CTS, with an emphasis on issues specific to occupational settings. We developed these measures using a variation of the well-established RAND/UCLA Appropriateness Method. A particular strength of this method is that it considers available literature but is able to overcome gaps in research evidence by rigorously synthesizing the experience of expert clinicians [13]. Randomized controlled trials do not exist for most health care processes [14], including for many aspects of care for CTS [15]. In such circumstances, syntheses of clinical expertise are a valid and important form of evidence. This is demonstrated by the fact that, in several studies addressing a variety of conditions, better adherence to measures developed using RAND/UCLA Appropriateness Method has been associated with improved patient outcomes [16–18].

Materials and Methods

Measure development is a three-step process: (1) developing draft measures by integrating guidelines and literature; and (2) refining and selecting measures, in this case using a variation of the RAND/UCLA panel method; and (3) testing the measures against a data source. We report the first two steps in this paper.

We also developed measures to assess the quality of electrodiagnostic testing [19], whether carpal tunnel release surgery is performed for appropriate indications [20], and the quality of peri-operative management; these measures are being reported elsewhere.

Developing Draft Measures

Developing draft measures was an iterative process involving collaboration among a rheumatologist, a physiatrist, two internists with expertise in quality measurement, and two hand surgeons, as well as a project advisory board that included five occupational medicine physicians.

First, we identified aspects of care relevant to improving quality for CTS (for example, the initial physical examination) using relevant clinical practice guidelines and other summary literature. We conducted a general literature search on CTS, updated a 2004 search for relevant guidelines by searching MEDLINE and the National Guidelines Clearinghouse, and accessed personal reference collections [21]. Team physicians reviewed the guidelines and literature, chose care processes that are likely to affect patient outcomes or that are widely recommended, then wrote draft measures.

Next, directed MEDLINE searches were conducted to identify evidence pertinent to the draft indicators. A reference librarian conducted the searches, and excluded case reports and animal studies. The searches included the terms carpal tunnel syndrome OR median neuropathy, with additional MeSH terms for specific subtopics: diagnosis (classification, severity, history, occupation, and tests), non-surgical treatment (therapy, drug therapy, rehabilitation), and return to work issues (disability, ergonomic, work). Team physicians sequentially reviewed titles, abstracts, and articles to assess relevance to each draft measure. Respectively, 1,635 citations were reviewed pertained to the diagnosis of CTS, 475 to non-surgical treatment, and 538 to return to work issues. Draft measures were refined, added, and deleted on the basis of search results.

Next, physicians summarized, for each draft measure, the evidence supporting the relationship between the care process and patient outcomes, emphasizing the highest quality evidence identified. Given most of the evidence was not high quality, we used a simplified classification scheme: level 1, randomized controlled trial; 2, observational study; and 3, case reports, case series and expert opinion. Where level 1 evidence was not available, the summary described a chain of evidence or clinical rationale.

Refining and Selecting Measures

Methods for refining and selecting quality measures were based on the RAND/UCLA Appropriateness Method, a multidisciplinary, two-round, modified-Delphi process that enables researchers to obtain a quantitative assessment that reflects the judgment of a group of experts. This method (explained below) has been used previously to develop quality measures for a wide variety of conditions and types of care. Additional background information and technical details about this method have been published previously [13, 22]. The method has reproducibility consistent with that of well-accepted diagnostic tests like screening mammography—i.e., separate panels examining the same topic have produced similar recommendations (kappas 0.51–0.83). Further, the measures developed using this method have been shown to have content, construct, and predictive validity, as evidenced by the fact that measures have been consistent with the results of subsequent randomized controlled trials or associated with improved patient outcomes. For example, panel judgments about the appropriateness of carotid endarterectomy were consistent with the findings of a subsequent randomized trial [23]. For arthroplasty of the knee and hip, adherence to measures addressing the appropriateness of surgery was found to be associated with improved quality of life [18]. For vulnerable elders, adherence to quality measures developed using this method was found to be associated with improved survival [16].

To select panelists for the current study, we asked U.S. specialty societies to recommend physicians who are leaders in each specialty, and then we reviewed curriculum vitae, interviewed candidates, and contacted references. The panel had eleven members: an occupational medicine physician, a neurologist, a physiatrist, a family physician, a physical therapist, four hand surgeons (one with primary board designation in plastic surgery and three in orthopedic surgery), and two orthopedists. We chose this balance of specialties because panelists rated many measures pertaining to carpal tunnel release surgery as well as the diagnostic evaluation and non-operative management. Panelists represented a variety of geographic locations, expertise, and both academic and community practice settings.

The first round of ratings involved having panelists rate the measures at home. Panelists received the evidence summaries, draft measures, ballots, and instructions. During the second round, panelists met in person and research team members moderated discussions of each draft measure, the evidence, and first-round ratings. We used a modified-Delphi panel method, rather than a consensus-panel method that forces agreement, to allow different attitudes to be expressed and contend with one another and true agreement or disagreement to emerge. Each panelist received a summary of the first-round ratings for each measure, including the median, standard error, his/her rating relative to the distribution, and the analytic interpretation. Panelists suggested modifications to definitions of key terms and measures; these were adopted when a majority voted to do so. After all opinions had been voiced for a measure, panelists marked private, equally weighted ballots.

For both rounds, panelists rated validity, feasibility, and importance on 9-point scales (9 = highest). Validity meant: (1) adequate scientific evidence or professional consensus exists to support a link between the performance of care specified by the measure and improved clinical outcomes; and (2) based on the panelists’ professional experience, health professionals with significantly higher rates of adherence to a measure would be considered higher-quality providers [13]. Panelists also rated measures for feasibility and importance to facilitate future users’ efforts to prioritize the measures. Feasibility meant the potential ability to evaluate adherence to the measure using medical records. Importance meant the magnitude of the potential effect on patient outcomes.

As is standard for this method, ratings interpretations included: valid = a median of 7–9 without disagreement; not valid = a median of 1–3 without disagreement; uncertain validity = a median of 4–6 or any median with disagreement. Disagreement was defined as three or more panelists rating in the 1–3 range and three or more in the 7–9 range [13]. Measures were considered potentially feasible if the median was 4 or above. There was no minimum threshold for importance because this variable was intended to help future users prioritize the measures.

Comparison with Occupational Medicine Guideline

An occupational medicine physician assessed how concordant each passing measure was with the current occupational medicine guideline from the American College of Occupational and Environmental Medicine (ACOEM) [24]. Observations were discussed with another physician who also compared the measures and guidelines.

Pilot Testing

After identifying measures meeting the validity and feasibility criteria, RAND/UCLA team members developed a detailed tool for scoring the measures. For each measure, an experienced research nurse and research associate defined relevant terms within the measures, the populations or care eligible for the measure (the denominator), and instances in which care can be considered to adhere to the measure (the numerator). Timeframes for eligibility and adherence were specified. The team also anticipated feasibility issues, such as data elements that may be difficult to find in medical records or that could require subjective judgments by abstractors, and developed specific instructions to resolve them.

Pilot testing enabled us to examine feasibility issues and preliminary rates of adherence to the measures. Feasibility issues included the ease which relevant patients can be identified, the availability of the medical records required to assess eligibility for and adherence to individual measures, and the clarity and usefulness of the scoring tool. The RAND/UCLA team pilot tested the measures and tool in a large workers’ compensation provider organization (Kaiser Permanente Northern California Regional Occupational Health) and in a large workers’ compensation insurance company (the California State Compensation Insurance Fund). Six nurses and one physical therapist (“abstractors”), who routinely perform claims reviews within each organization, underwent a two-day training in the use of the tool and scored several practice cases. Finally, they reviewed records for a small sample of patients who had been diagnosed CTS or conditions often confused with CTS. Patients were randomly selected by applying pre-specified criteria (time period and diagnostic category) to administrative databases maintained by the insurance company. The abstractors working for the insurance company reviewed clinical records routinely collected for claims processing. The abstractors working for the provider organization reviewed electronic medical records for each patient. During the training and pilot testing, abstractors provided feedback on the tool. The pilot test activities were approved by each of the institutional human subjects’ protection committees; informed consent was not required.

Results

There were 40 draft measures. During the second round of the rating process, 30 measures were modified, 9 measures did not meet validity criteria, one of these 9 was also judged infeasible, and the remainder passed (31/40 measures passed, 78%).

Final Measures

Nine final RAND/UCLA CTS measures (Table 1) emphasized the initial evaluation of patients with hand and forearm complaints; 11 considered non-operative treatments such as splinting, steroid injections, and other medications; and 11 pertained to addressing activities and functional limitations.

Table 1.

List of quality measures meeting validity and feasibility criteria

Measure title	Measure text
Measures for the initial evaluation of hand and forearm symptoms
1. New symptoms characteristic of CTS require detailed assessment	IF the progress notes document new paresthesias or numbness in the fingers, THEN at least two of the following should be noted at the initial evaluation of those symptoms: (1) a verbal or pictoral description of the location of any pain, numbness, or paresthesias (e.g., Katz hand diagram), (2) the quality of any pain, (3) the duration of any pain, numbness, or paresthesias, (4) onset of pain, numbness, or paresthesias
2. New symptoms characteristic of CTS should lead to suspicion	IF a patient complains of any of the following symptoms: Paresthesias, numbness, or tingling on 1st to 3rd fingers or palm THEN a suspicion of CTS should be documented in the medical record at the initial evaluation of those symptoms.
3. New hand or forearm pain requires evaluation for “red flags”	IF patient complains of new hand or forearm pain THEN the progress notes should document the presence or absence of at least one of the following “Red flags” at the same visit: (1) trauma, (2) deformity, including swelling, (3) fever
4. Symptoms inconsistent with CTS require evaluation	IF patient complains of hand or forearm pain and also has any of the following: (1) New fever, (2) New point tenderness, (3) New deformity, THEN at least one diagnosis other than CTS should be evaluated at this visit
5. New CTS diagnosis requires assessment of medical risk factors	IF the progress notes document a new diagnosis of CTS, THEN a history of at least one of the following risk factors should be documented during the first three visits: (1) Rheumatoid arthritis, (2) Diabetes mellitus, (3) Hypothyroidism, (4) Pregnancy, if female, (5) Chronic renal failure
6. New suspicion of CTS requires specific physical examination	IF the progress notes document that CTS is suspected THEN at least one of the following physical examination maneuvers should be documented at initial evaluation: (1) Testing for sensory abnormalities in median nerve distribution, (2) Testing for thenar muscle weakness, (3) Examination for thenar muscle atrophy
7. New suspicion of CTS requires evaluation for overweight	IF the progress notes document that CTS is suspected THEN height and weight, or a clinical judgment about the presence or absence of obesity/overweight, should be documented at initial evaluation
8. Imaging should be used selectively for suspected CTS	IF the progress notes document that CTS is suspected THEN MRI or ultrasound or CT should not be the initial test for diagnosis unless a structural lesion is suspected
9. Symptoms should be monitored after new diagnosis of CTS	IF patient is newly diagnosed with CTS during a visit THEN at each CTS-related visit during the first three months after presentation, patient should be asked about changes in at least one of the following: (1) Pain or paresthesias in the median nerve distribution, (2) Symptoms of weakness, such as dropping things, decreased grip strength, etc.
Measures for the non-operative treatment of CTS
10. Splints should be placed in neutral position	IF a patient with CTS is prescribed a splint, THEN the chart should document that the splint was positioned so that the wrist is neutral (neither extension >10 degrees or flexed)
11. An attempt at splinting should last at least six weeks	IF a patient with CTS is prescribed a neutral splint, THEN the split should be prescribed for at least six weeks
12. NSAIDs should not be used for CTS	IF a patient is diagnosed with CTS, THEN the patient should not be given NSAIDs to treat CTS symptoms
13. Muscle Relaxants should not be used for CTS	IF a patient is diagnosed with CTS, THEN the patient should not be given muscle relaxants to treat CTS symptoms
14. Opioids should not be used for CTS	IF a patient is diagnosed with CTS, THEN the patient should not be given opioids to treat CTS symptoms
15. Diuretics should not be used for CTS	IF a patient is diagnosed with CTS, THEN the patient should not be given diuretics to treat CTS symptoms
16. Steroid treatment requires discussion of risks	IF a patient with CTS is prescribed oral steroids or administered a steroid injection of the carpal tunnel, THEN the medical record should document that risks of the treatment were discussed
17. Discuss benefits of surgery when offering steroids to patients with severe CTS	IF a patient has severe CTS, THEN the patient should not be offered a steroid injection or oral steroids without also documentation that the possibility of surgery was discussed
18. Steroids for work-associated symptoms require follow-up	IF steroid injection is performed or oral steroids are prescribed for CTS symptoms that are thought to be work associated THEN physicians should document a follow-up call to or visit with the patient within 4 weeks
19. Limit steroid injections to 4	IF a steroid injection of the carpal tunnel is performed for CTS, THEN no more than 4 steroid injections should be performed total per hand, unless the provider documents that the patient has refused surgery
20. Lasers should not be used for CTS	IF patients are diagnosed with CTS, THEN low-level laser therapy should not be prescribed for or used in treatment
Measures for addressing activities and functional limitations potentially associated with CTS symptoms
21. New CTS diagnosis requires detailed occupational history	IF the progress notes document a new diagnosis of CTS, THEN at least one of the following pieces of history should be documented between the time of initial evaluation of the CTS symptoms and the second visit after the diagnosis: (1.) occupation including functional job duties, (2.) duration at given occupation, (3.) whether symptoms improve or worsen at work
22. New CTS diagnosis requires assessment of occupational factors	IF the progress notes document a new diagnosis of CTS, THEN during the first three visits, the presence or absence of at least one of the following factors should be documented for occupational settings: (1.) mechanical force, (2.) vibration, and (3.) frequent repetitive wrist movements
23. New CTS diagnosis requires assessment of non-occupational factors	IF the progress notes document a new diagnosis of CTS, THEN during the first three visits, the presence or absence of at least one of the following factors should be documented for non-occupational settings: (1.) mechanical force, (2.) vibration, and (3.) frequent repetitive wrist movements
24. Exacerbating activities should be identified when CTS limits functioning	IF a patient has a diagnosis of carpal tunnel syndrome and a provider documents that occupational or non-occupational functioning is limited by it THEN the provider should also document the specific job duties or non-occupational activities that are associated with symptoms
25. Rationale for work-association should be documented	IF a patient is diagnosed with CTS and is working outside the home THEN, by the first visit after the initial presentation, the medical record should document the provider’s opinion regarding the probability that that the CTS is work associated together with a rationale
26. Patients diagnosed with CTS should be educated about the condition	IF carpal tunnel syndrome is newly diagnosed THEN within the first four weeks, the provider should document that they educated the patient about at least one of the following: (1.) symptoms; (2.) treatments; (3.) prognosis; (4.) exacerbating factors; (5.) the rationale for a judgment of work-association; (6.) that unnecessary time off work may not benefit the patient; (7.) work-site or work-activity modifications; or (8.) other issues relating to their CTS
27. Exposures to vibration, force, and repetition should be minimized	IF a patient has a diagnosis of carpal tunnel syndrome and a provider documents exposure to any of the following: mechanical force, vibration, and frequent repetitive wrist movements THEN, during the same visit, the provider should document that they discussed activity modification with the patient
28. Work-associated CTS symptoms require prompt follow-up	IF a patient has CTS and symptoms are newly thought to be work associated THEN they should be seen for a follow-up visit within 4 weeks of initial evaluation
29. Work status should be monitored when CTS appears work associated	IF work associated carpal tunnel syndrome is newly diagnosed THEN the provider should document whether or not the individual is currently working at each CTS-related visit during the first three months
30. Return to work after CTS-related disability requires follow-up assessment	IF a patient diagnosed with CTS returns to work after being on temporary work associated disability for more than four weeks, THEN, within four weeks of returning to work, they should have a follow-up assessment at which the presence or absence of occupational functional limitations is documented
31. Prolonged CTS-related disability should trigger evaluation	IF a patient is off work for four or more weeks for carpal tunnel symptoms THEN the presence or absence of one of the following: (1.) alcohol or substance abuse, (2.) depression or anxiety, or (3.) other barriers to return to work, should be documented in the medical record by the next visit

Table 2 lists the title of each measure, validity and feasibility ratings, and the highest level of supporting evidence. For few, if any, of these measures was there a large randomized controlled trial or high-quality observational study directly examining the effect of the care described. Nevertheless, in each instance, there is convincing chain of evidence or clinical rationale that supports the practice. An “Appendix” provides the supporting rationale and a summary of the relevant literature.

Table 2.

Quality measures: measure titles, ratings, and evidence level*

Measure title	Validity		Feasibility		Importance	Evidence
	Median†	N (%) of Ratings >=7	Median†	N (%) of Ratings >=4	Median	level†
Initial evaluation of hand and forearm symptoms
1. New symptoms characteristic of CTS require detailed assessment	8 (2–9)	9 (82%)	8 (7–9)	11 (100%)	8 (6–9)	2
2. New symptoms characteristic of CTS should lead to suspicion	8 (7–9)	11 (100%)	8 (7–9)	11 (100%)	7 (5–8)	2
3. New hand or forearm pain requires evaluation for “red flags”	8 (1–9)	10 (91%)	8 (1–9)	10 (91%)	8 (1–9)	3
4. Symptoms inconsistent with CTS require evaluation	8 (6–9)	10 (91%)	8 (4–9)	11 (100%)	8 (5–9)	3
5. New CTS diagnosis requires assessment of medical risk factors	8 (1–9)	9 (82%)	8 (7–9)	11 (100%)	8 (5–9)	3
6. New suspicion of CTS requires specific physical examination	8 (5–9)	10 (91%)	8 (4–9)	11 (100%)	8 (5–9)	2
7. New suspicion of CTS requires evaluation for overweight	7 (5–9)	9 (82%)	7 (7–9)	11 (100%)	6 (2–9)	3
8. Imaging should be used selectively for suspected CTS	8 (7–9)	11 (100%)	8 (8–9)	11 (100%)	7 (3–9)	3
9. Symptoms should be monitored after new diagnosis of CTS	8 (7–8)	11 (100%)	8 (7–9)	11 (100%)	7 (4–8)	3
Non-operative treatment of CTS
10. Splints should be placed in neutral position	8 (7–9)	11 (100%)	8 (5–9)	11 (100%)	7 (4–9)	1
11. An attempt at splinting should last at least six weeks	7 (1–8)	8 (73%)	7 (1–8)	11 (100%)	7 (1–8)	1
Certain medications should not be used for CTS
12. NSAIDs	7 (4–8)	9 (82%)	7 (6–9)	11 (100%)	7 (3–9)	1
13. Muscle Relaxants	7 (6–9)	10 (91%)	8 (6–9)	11 (100%)	7 (3–9)	3
14. Opioids	8 (7–9)	11 (100%)	8 (7–9)	11 (100%)	7 (3–9)	3
15. Diuretics	8 (2–9)	11 (100%)	8 (7–9)	11 (100%)	7 (2–9)	1
16. Lasers should not be used for CTS	8 (7–9)	11 (100%)	8 (3–9)	10 (91%)	7 (1–9)	1
17. Discuss benefits of surgery when offering steroids to patients with severe CTS	8 (6–8)	10 (91%)	8 (6–9)	11 (100%)	8 (5–8)	1
18. Steroid treatment requires discussion of risks	8 (6–9)	10 (91%)	8 (7–9)	11 (100%)	6 (3–9)	3
19. Steroids for work-associated symptoms require follow-up	7 (6–9)	10 (91%)	8 (7–9)	11 (100%)	7 (5–9)	3
20. Limit steroid injections to 4	7 (4–9)	10 (91%)	8 (5–9)	11 (100%)	7 (3–9)	3
Addressing activities and functional limitations potentially associated with CTS symptoms
21. New CTS diagnosis requires detailed occupational history	7 (2–9)	9 (82%)	7 (7–9)	11 (100%)	6 (2–9)	3
22. New CTS diagnosis requires assessment of occupational factors	7 (5–9)	8 (73%)	8 (5–9)	11 (100%)	7 (5–9)	2
23. New CTS diagnosis requires assessment of non-occupational factors	7 (5–9)	8 (73%)	8 (5–9)	11 (100%)	7 (5–9)	2
24. Exacerbating activities should be identified when CTS limits functioning	7 (4–9)	6 (55%)	7 (6–9)	11 (100%)	7 (5–9)	3
25. Rationale for work-association should be documented	7 (4–8)	6 (55%)	6 (3–8)	9 (82%)	7 (4–9)	3
26. Patients diagnosed with CTS should be educated about the condition	7 (5–9)	6 (55%)	7 (4–9)	11 (100%)	7 (5–9)	3
27. Exposures to vibration, force, and repetition should be minimized	7 (3–9)	7 (64%)	7 (4–8)	11 (100%)	7 (4–9)	2–3
28. Work-associated CTS symptoms require prompt follow-up	8 (6–9)	10 (91%)	8 (5–9)	11 (100%)	8 (2–9)	3
29. Work status should be monitored when CTS appears work associated	7 (5–9)	9 (82%)	7 (5–9)	11 (100%)	7 (5–9)	3
30. Return to work after CTS-related disability requires follow-up assessment	7 (5–9)	6 (55%)	7 (6–9)	11 (100%)	6 (5–9)	3
31. Prolonged CTS-related disability should trigger evaluation	7 (6–9)	10 (91%)	7 (6–9)	11 (100%)	7 (6–9)	2–3

* The table lists measure titles. The actual text of the measures is provided in Table 1

^†Validity Ratings >=7 indicated panelists thought the measure was valid. Feasibility Ratings >=4 indicated panelists thought the measure was potentially feasible. Level of Evidence: 1 = randomized controlled trial, 2 = observational data, 3 = case series or expert consensus

Comparison with Occupational Medicine Guideline

Seventeen measures (55%) are fully concordant with the ACOEM guideline, five are somewhat concordant (16%), the ACOEM guideline did not address content within eight of the measures (26%), and one measure is discordant with the guideline (3%) (see Appendix for list) [24]. This last measure addresses the use of non-steroidal anti-inflammatory agents (NSAIDs) for CTS symptoms.

Pilot Testing

Regarding feasibility issues, the provider organization readily identified eligible patients using ICD-9 and CPT codes and had no difficulty determining eligibility for and adherence to the measures due to the organization’s electronic medical record system. However, the insurance company had some difficulty identifying eligible patients because it uses broad diagnostic categories rather than ICD-9 and CPT codes, and also assessing eligibility for some measures because its clinical records were incomplete. As to the scoring tool, the research team made many changes based on feedback from the seven abstractors. None of the measures were eliminated due to feasibility concerns.

Regarding preliminary rates of adherence, the pilot study included a total of 28 unique patients. Sixteen had been diagnosed with CTS and 12 with upper extremity disorders commonly confused with CTS. Twenty-four patients were eligible for one or more measures. Care was eligible for a measure a total of 559 times, and adhered to the measures 419 times (an overall adherence rate of 75%). Adherence rates were 66% for initial evaluation, 79% for non-operative treatment, and 81% for management of activities and functional limitations. These results illustrate the ability to assess quality of care for CTS and should not be considered representative of the care provided by these organizations.

Discussion

This paper describes a set of measures that can be used to objectively assess the quality of medical care for carpal tunnel syndrome, with an emphasis on issues specific to occupational settings. The measures address the diagnostic evaluation and non-operative treatment of CTS, including assessing causality and managing occupational activities and functional limitations.

Quality measures that focus on care processes, as these do, are sometimes confused with treatment guidelines because they share development methods and clinical content. However, quality measures and guidelines serve complementary functions (see Table 3). Quality measures are rigid, quantitative tools that distinguish higher and lower quality care after the care has already been provided, whereas guidelines offer information that practitioners may or may not use during real-time clinical decision-making. Measures effectively become mandatory when adherence to them is used to assign penalties or rewards, as payers often do in non-occupational settings. Measures, for this reason, describe basic standards rather than best practices, are silent when the appropriate approaches are uncertain, and are used to assess quality at the population level. Conversely, guidelines are generally designed to be flexible and advisory; therefore, they cannot be accurately or reliably used as quality assessment tools because they permit providers to use their experience when applying recommendations to individual patients and address situations in which there is uncertainty about the preferred approaches. Finally, measures are scored in a systematic, highly structured fashion to ensure consistent results [25]. Thus, although occupational medicine guidelines exist for CTS [24], quality measures are also needed.

Table 3.

Similarities and differences between process-oriented quality measures and clinical treatment guidelines

	Process-oriented quality measures	Clinical treatment guidelines
Definition	Criteria used to evaluate components of an encounter between a physician or another health care professional and a patient, and for which variations in adherence lead to differences in outcomes[36]	Systematically developed statements that assist practitioner and patient decisions about appropriate health care for specific clinical circumstances [37]
Developers	Non-profit entities, government bodies, specialty societies, researchers, payers	Non-profit entities, government bodies, specialty societies, researchers, payers
Development methods	Systematic literature reviews coupled with work by expert panels	Systematic literature reviews coupled with work by expert panels
Proprietary or publicly available	Either	Either
Specifies basic standards	Yes	Yes
Specifies best practices	No	Yes
Discusses areas of uncertainty	No	Yes
Mandatory or advisory	Effectively mandatory when used as a basis for assigning rewards and penalties [25]	Advisory [25]
Rigid or flexible	Rigid. Focus on selected situations for which there are clear “right” or “wrong” approaches [25]	Very flexible, intended to inform provider judgments and patient preferences [25]
Length	Measures are very concise and precisely written statements (1–2 sentences)	Guidelines can be long documents that include details about development methods, systems for classifying the evidence, summaries of research evidence, rationales for consensus-based recommendations, etc.
Supporting documentation	Often extensive to ensure consistent interpretation of the measures. Defines relevant terms, population eligible for the measure, conditions for satisfying the measure, instructions for interpreting the often variable information in clinical data sources, etc.	Not needed.
Users	Generally used by organizations (large provider organizations or payers), researchers, or representatives of government. Can be used by individual providers for self-assessment, such as during board recertification activities	Generally designed to be used by individual providers
Timing of use	Generally after care has been provided (retrospective)	Generally at the point of care (concurrent)
Target population	Carefully defined populations of patients relevant to individual measures or sets of measures	Patients in a broad category defined by the possibility that they may have or develop a particular condition, or may be a candidate for a particular treatment
Use is systematic or ad hoc	Highly systematic scoring of adherence to criteria. Often used to assess care for a population or sample thereof.	Ad hoc, not scored. Used to look up specific questions as they arise.
Prevalence of use in U.S. Healthcare system	Ninety percent of health plans for non-occupational settings participate in the HEDIS program [29]. Medicare assesses quality of care for all hospitals and nursing homes [28]. Quality measures are used in multiple other efforts to improve quality of care nationally.	Physicians do not consistently incorporate clinical guidelines into their decision making because of lack of knowledge, barriers to guideline implementation, and unfavorable attitudes toward guidelines [38]

As noted in the Introduction, both payors and workers have substantial interests in improving the quality of care for CTS due to the high prevalence and costs associated with the condition. Two studies have demonstrated that quality improvement programs promoting adherence to treatment guidelines can decrease time off work and reduce costs. A randomized controlled trial in Spain demonstrated that improving care for workers with musculoskeletal injuries, including CTS, can markedly affect disability and its costs, saving eleven U.S. dollars per dollar invested [4]. A smaller Washington State program produced similar results: disability costs were reduced by 30% by improving adherence to treatment protocols and encouraging providers to prescribe activity and plan for return to work [26]. The savings could be even greater if the costs associated with reduced worker productivity were considered, since CTS is a common cause of absenteeism [27]. Thus, improving quality of care for occupational disorders may represent a unique “win–win” for workers and employers, the two central stakeholders in workers’ compensation systems.

Efforts to monitor and improve quality of care have already become commonplace in other aspects of the United States healthcare system. Most hospitals are now required to publicly report performance with regards to acute myocardial infarction, heart failure, and pneumonia [28]. The National Committee on Quality Assurance’s Healthcare Effectiveness Data and Information Set (HEDIS) enables health plans to monitor and report the quality of the care their enrollees receive. Because 90% of health plans participate in the HEDIS program and employers consider HEDIS scores in healthcare purchasing decisions [29], health plans have financial incentive to improve quality of care. Comparable efforts to assess and improve care could be undertaken for occupationally associated disorders.

Provider organizations, payors, and others planning to use these measures will need detailed specifications to score them consistently. The research team has developed and pilot tested a comprehensive scoring tool that will support these efforts. This tool includes all of the measures, including those pertaining to electrodiagnosis and surgery. RAND will make the refined, final tool available for free on its website during the summer of 2010. Provider organizations may be in a better position to identify eligible patients and assess quality than payors are. We found this to be the case in our pilot study. Further, in non-occupational settings, providers typically perform these functions and report quality of care data to payers (with oversight and validation activities to ensure the integrity of the data).

Comparison with Occupational Medicine Guideline

Overall, we found substantial concordance between the RAND/UCLA CTS measures and the ACOEM guideline, a major occupational medicine guideline, although there are no table differences. The RAND/UCLA measures disapprove of NSAIDs for CTS because a randomized controlled trial showed no benefits and these medications increase the risks of gastrointestinal bleeding and myocardial infarction [30, 31], whereas the ACOEM guideline considers NSAIDs to be an appropriate option. Also, the ACOEM guideline addresses many important topics that, for reasons discussed above, the measures omit.

For example, no measure defines the optimal method for establishing a diagnosis of CTS. Many studies, guidelines, and commentators have wrestled with this issue. Certain approaches to history taking and physical examination have higher specificities for CTS, using positive electrodiagnostic tests as the gold standard. In turn, positive electrodiagnostic tests increase the probability that patients will respond to surgery [15]. However, as of yet, there appears to be no clear consensus as to the “correct” approach to synthesizing this information into a clinical diagnosis. Consequently, the quality measures address the diagnostic evaluation for CTS, but not the diagnosis itself.

While the ACOEM guideline will be useful for informing providers of the preferred means of caring for patients with occupational CTS, the RAND/UCLA measures can be used to assess quality of care and monitor the effectiveness of any improvement efforts. Individual providers can use these measures to evaluate the quality of the care they provide. Periodic retrospective chart review is a central component of the occupational and preventive medicine maintenance-of-certification processes [32, 33]. The RAND/UCLA CTS measures could be used in such reviews. Practices with multiple providers can evaluate quality for the practice and, if warranted, develop an infrastructure that supports improvement. Organizational efforts are particularly likely to be effective because they leverage the contributions of many individuals, and they enable systems to be established that make adherence simpler. Finally, payors of compensation claims might consider using these measures as a basis for referring patients to higher-quality providers, or as a basis for offering higher-quality providers greater remuneration.

Limitations

Quality measures do have limitations. Some important aspects of care for patients with CTS are not amenable to measurement. For example, patients can be sensitive about discussing potential barriers to returning to work, such as conflicts with supervisors, and some providers may conduct these discussions more effectively than others do. But many important aspects of care can be measured. Also, for each measure, unique clinical circumstances will warrant exceptions to the rule. Justifiable exceptions are not problematical so long as sample sizes are sufficient and exceptions are rare and randomly distributed among populations of patients.

These measures also have specific limitations. First, the literature examining these practices is rather limited, and most of the measures are based on expert consensus. Musculoskeletal disorders suffer for a lack of large, high-quality randomized controlled trials, and randomized controlled trials are not feasible for all aspects of care. In the past, this panel method has successfully overcome similar limitations to the literature for osteoarthritis, rheumatoid arthritis, arthroplasty of the knee and hip, and many other clinical situations [18, 34, 35]. Second, the panel included a higher proportion of surgeons than it would have if only diagnosis and non-operative treatment were considered. To mitigate this issue, we submitted the measures for each topic to relevant subspeciality journals in occupational medicine, neurology, and surgery, thereby ensuring that the measures undergo peer review by experts in these respective disciplines.

Third, the ultimate test of measures’ validity entails assessing whether better adherence is associated with better patient outcomes. In September 2010, we are planning to undertake a prospective study that will compare adherence to these measures with patients’ symptoms, functional status, time off work, and permanent disability ratings. We expect to find an association because associations have been found for previous sets of measures developed using the same methods. However, most quality measures in wide use today have yet to be been tested in this fashion.

In conclusion, this project has developed 31 measures that can be used to evaluate the quality of the care for CTS. These measures appear to be the first quality measures to address both medical and occupational issues; therefore, they lay the groundwork for quality assessment activities to be introduced in occupational settings. These measures could be useful in a variety of efforts to improve quality of care for patients with CTS, whether initiated by providers, medical groups, payors, or policymakers. Similar measures should be developed for other work-associated disorders.

Appendix: List of Measures, Rationales, and Summaries of Relevant Literature

Quality Measures for Initial Evaluation of Hand and Forearm Symptoms

History

The history plays a key role in assisting practitioners to make a correct diagnosis. Although data relating specific pieces of the history to improved patient outcomes is relatively limited, there are key components of the history that help to narrow the differential diagnosis and point toward or away from CTS. Typically, patients with CTS have symptoms of paresthesia and pain [39, 40]. Stevens et al. [39]. identified 100 patients with symptomatic electrodiagnostically confirmed CTS (159 hands) and found that the vast majority of them reported paresthesias (78, 93, and 96% in the thumb, index and middle finger respectively). Forty percent of them reported having pain in the hands [39]. Other important pieces of history that have been identified include the location of the pain, quality, duration, and onset [41–45].

The Katz hand diagram is a self-administered diagram where patients mark symptoms including pain, numbness, tingling and decreased sensation. By comparing the patient’s diagram against a classification system for symptoms, physicians then determine whether the symptoms reflect classic, probable, possible or unlikely CTS. In a cohort study, sensitivity was 80% and specificity was 90% compared to CTS as defined by nerve conduction studies, unequivocal response to corticosteroid injection or improvement in symptoms after surgical release [44]. Subsequent reviews have concluded that the Katz hand diagram is among the better diagnostic tests for CTS [46, 47].

Because CTS is commonly confused with other conditions that cause symptoms in the hand and forearm and an incorrect diagnosis can lead to delays in treatment [48], panelists felt that providers must recognize symptoms that may represent CTS early on. CTS is most probable when symptoms occur in the first through third digits or on the palm in the area of the thenar eminence [46].

Asking about and documenting “red flags,” including history of trauma, deformity and fever, assists with making a diagnosis. Because such historical information is inconsistent with CTS, their presence necessitates an investigation of other conditions. These elements of care are recommended by the American College of Occupational and Environmental Medicine Guidelines [49].

Asking patients about activities associated with CTS symptoms enables any exacerbating factors to be identified and mitigated; this is discussed in the section below. In addition, providers should ask patients whether they have certain systemic diseases that are risk factors for CTS because identifying the underlying disease may direct therapy to improve CTS symptoms in some patients. Non-occupational risk factors include connective tissue disease (like rheumatoid arthritis), diabetes, hypothyroidism, osteoarthritis of the wrist and carpal bones, and pregnancy. History of wrist fracture is also strongly associated with CTS, and identification of this risk factor would help focus treatment on correction of anatomic changes that may be causing CTS [50–54].

Physical Examination

Although providers employ many physical examination findings and tests to evaluate for CTS, the current panelists believed that an adequate physical examination would include at least one of the following: assessing thenar muscle strength, assessing sensibility in the median nerve distribution, and checking for thenar muscle atrophy.

Reviews have identified thumb abduction testing and testing for decreased sensitivity to pain in the median nerve territory compared with ipsilateral ulnar nerve territory, as having among the strongest evidence as good diagnostic tests [46, 47]. Thumb abduction was tested by Kuhlman et al. and found to have sensitivity and specificity of 66% and de Krom et al. found a sensitivity of 39% and specificity of 80% as compared to nerve conduction studies for the diagnosis of CTS [47, 53]. Testing for median nerve territory hypalgesia was evaluated by Golding et al. [55].; it had a low sensitivity of 15% but a good specificity of 93% as compared to nerve conduction studies [55]. Kuhlman et al. demonstrated a sensitivity of 51% and specificity of 85% as compared to nerve conduction studies [47]. Pooling the results of the last 2 studies produced a positive likelihood ratio of 31 (95% confidence interval 2.0–5.1) and negative likelihood ratio 0.7 (95% confidence interval 0.5–1.1). In contrast, widely performed tests like Phalen’s and Tinel’s actually have poor ability to predict the diagnosis of CTS as defined by nerve conduction studies [46]. Given studies evaluating the various maneuvers are somewhat limited, the panelists felt that any maneuvers assess thenar muscle strength and sensibility in the median nerve territory would be acceptable.

Thenar atrophy is not particularly sensitive or specific for CTS but it is important to document because it is a marker for more severe CTS. Indeed, our panelists defined severe carpal tunnel syndrome by the presence of thenar atrophy. Many surgeons consider the presence of thenar weakness or atrophy to be an indication for a surgical release. For example, new treatment guidelines from the American Academy of Orthopedic surgeons consider early surgery an option when patients have clinical evidence of median nerve denervation [56]. Studies are equivocal on whether this finding is with worse outcomes following carpal tunnel release [57–59].

In addition to the above physical examination maneuvers of the hand and wrist itself, determining whether the patient may be overweight or obese is important because several articles have linked increased body mass index with CTS [50, 60].

Imaging

Because nerve conduction studies have high degree of sensitivity and specificity for the diagnosis of CTS if performed per the American Association of Electrodiagnostic Medicine guidelines, they should be the primary test to assist with the diagnosis of CTS. Radiographs, MRI, and CT can be considered if space-occupying lesions or fractures are suspected; existing literature does not support the routine use of imaging tests for patients with CTS [41, 61, 62].

Follow-up

Panelists concluded that, during any follow-up visit in the three months after CTS is diagnosed, when symptoms and functional status are undergoing the most changes [63], patients should be asked about symptoms of pain, paresthesias and weakness in the median nerve distribution in order to assess how the patient is doing compared with their initial presentation. A significant proportion of patients treated with conservative therapy (non-surgical treatments) will progress and may need surgery [64–66]. They did not stipulate when follow-up visits must occur for patients without work-associated CTS; work-associated CTS is discussed below.

Quality Measures for Non-Operative Treatment

Splinting

A poorly made, positioned, or used splint can cause more problems than it solves. While many pre-fabricated splints come out of the box in a position of 20–30 degrees of wrist extension, this is not the position preferred for immobilization of the carpal tunnel structures. The provider must fabricate or reposition the splint to neutral. Use of a wrist splint in extension actually increases pressure within the carpal tunnel relative to use of splints in a neutral position [67].

Use of the splint for at least six weeks (or as long as symptoms persist) improves outcome (decreased pain, improved function) compared with less persistent, more intermittent use. Two randomized, controlled trials have examined the effectiveness of splinting and the timing of use associated with improvement. Werner randomized 112 autoworkers with possible, probable, and definite carpal tunnel syndrome (based upon presence of tingling, burning or pain in the distribution of the median nerve from hand diagram score) to treatment with ergonomic education alone or custom wrist splint worn at night for six weeks [68]. The splinted group had a significant reduction in wrist, hand, and/or finger discomfort and improvement in the Levine symptom severity scale. In a randomized study, Walker et.al. studied 30 hands of 21 veterans with electrodiagnostic demonstrated carpal tunnel syndrome and compared night-only versus full-time use of custom neutral wrist splint. The full-time use group reported more improvement than the overnight group on the Levine symptom severity scale, and such improvement was also noted in improved sensory distal latency in the full-time group [69].

Medications

The panelists concluded that diuretics, NSAIDs, opioids, and muscle relaxants are inappropriate therapies for CTS symptoms. Diuretics and NSAIDs provide no symptomatic relief to patients with CTS compared with placebo. Chang et.al. evaluated 73 patients with mild to moderate carpal tunnel syndrome confirmed electrodiagnostically and randomized them to receive placebo, a diuretic (trichlormethiozaide), an NSAID (tenoxicam-SR) or oral steroids (prednisolone) for four weeks. Patients who received diuretics, NSAIDs, or placebo had no change in their symptoms relative to baseline [70]. Given these findings and the risks of gastrointestinal bleeding and myocardial infarction, the risks of using NSAIDs outweigh the potential benefits for carpal tunnel syndrome [71]. There is no evidence that opioids, or muscle relaxants relieve carpal tunnel syndrome symptoms and the panelists noted that they too may harm patients.

Several studies demonstrate that locally injected or oral steroids appear to benefit patients with carpal tunnel syndrome [64, 70, 72–74]. One randomized, controlled trial demonstrated the two delivery modalities have similar efficacy [74]. However, due to the attendant risks of each, the panelists felt that offering these treatments to patients should be optional, not mandatory. Further, for all patients offered steroids, a full discussion of the benefits and risks of the steroid injections should occur prior to proceeding because the patient should be actively involved in his or her care. The principle of informed consent relies on the patient’s full understanding of benefits and risks of any medical treatment prior to it undertaking. Although the risks are not common, they include median nerve injury, (digital flexor) tendon rupture, bleeding, infection, and reflex sympathetic dystrophy [75, 76].

For patients with severe CTS, a randomized, controlled trial demonstrated that steroid injections do not have lasting benefits and surgery is more effective. Thus providers should discuss the possibility of surgery as an alternative to steroid injections. Gelberman et al. demonstrated that for patient with severe CTS, only 4 patients out of 32 had complete relief of symptoms at 18 months after steroid injection as compared with 7 out of 18 in the mild to moderate CTS group [77]. A more recent study demonstrates that outcomes are superior with release than with splinting [78]. The data on whether steroid injections or surgery is superior in improving CTS symptoms among patients without thenar atrophy is conflicting [75, 79].

If a patient does receive steroids either orally or via injection, a physician should call or see the patient to inquire about adverse effects and any response to treatment. If the patient notes no improvement, reassessment of whether the initial diagnosis was correct or consideration of other therapies is warranted. The panelist felt that such contacts with patients are generally recommended, but that they are essential when the CTS appears work-associated (i.e., the symptoms worsen during or after work) and that the follow-up contact should occur no later than 4 weeks after the initiation of treatment.

Steroid injections are not without risk and multiple repeated injections are less likely to confer benefit. Wong et al. randomized 40 patients to either to single steroid injection or 2 steroid injections 8 weeks apart. At 10 months, there were no differences in symptoms between the two groups [80]. Per the Quality Standards Subcommittee of Academy of Neurology, no more than 3 steroid injections should be attempted [41]. The current panel felt that the maximum number that would be acceptable was four, which allows for additional extenuating circumstances for some patients.

Lasers

A randomized controlled trial has demonstrated that low-level lasers are not effective in decreasing symptoms in patients with CTS [81].

Quality Measures for Addressing Associated Activities and Functional Limitations Potentially Associated with CTS Symptoms

There are two basic reasons that patients with CTS may need to change their activities at work or at home. First, some activities can exacerbate the CTS symptoms. Second, CTS, or its treatment, may lead to functional limitations, defined as any major activities the patient cannot do now but could do before the CTS symptoms started. Both an association with symptoms and functional limitations can create the need for patients to completely eliminate certain activities (“activity restriction”), or to modify how they perform them (“activity modification”). Occupational activity restrictions can be achieved either by eliminating the specific job tasks involving those inciting factors or, if necessary, by placing the individual on disability. Activity modifications can permit an individual to more safely perform a task that involves exposure to a known inciting factor Both occupational and non-occupational activities are important because all exposures to inciting factors need to be identified and mitigated, and because CTS can adversely affect functioning in both occupational and non-occupational settings [82, 83].

History of Associated Activities and Functional Limitations

Asking patients with CTS symptoms about the nature of their occupation is important so that high risk occupations and tasks can be identified, and job modifications can be implemented. For example, occupations associated with higher prevalence of CTS include electrical assembly, food packing and processing, frozen food packaging, and poultry workers, among others [84]. Detailed information on the patient’s functional job duties, duration of current employment, and the timing of the symptoms relative to work activities are important to determining whether a workers’ compensation claim may be appropriate. The panelists felt that a minimum standard of care included documenting one of these pieces of occupational information.

Of the many factors that researchers have examined for an association with CTS, mechanical force, vibration, frequent repetitive movements or some combination of the three appear to be most strongly associated [84–86]. Silverstein et al. evaluated 652 industry workers (in 39 different jobs from seven industrial sites) and categorized their work as by force and repetitiveness and screened them for CTS by symptoms and physical exam. They found that high repetitiveness was a risk factor for CTS and the combination of high force and high repetitiveness also increased risk for CTS [87]. Cannon et al. in a case control study, found that use of vibratory tools was associated with CTS with an odds ratio of 13.8 [88]. The panelists concluded that a minimum standard of care entailed assessing whether any such exposures are present for both occupational and non-occupational settings, since people may engage in hobbies, sports, or other non-employment-related activities that exacerbate CTS symptoms.

In addition to associated activities, functional limitations are also important because they are symptoms that reflect the severity of the condition and how well patients are responding to therapy [82, 83]. Limitations can be occupational, such as an inability to perform specific job tasks[82, 83]; or non-occupational, such as difficulties turning keys, opening jars, buttoning clothes, etc. [89–91]. When limitations are present, the specific nature of the limitations must be understood in order to formulate recommendations for modifying activities and to monitor responses to therapy over time. The panelists concluded that a basic standard of care is for providers to document the specific functional job duties or non-occupational activities that the patients cannot perform.

Judgments of Work Association

Assessing and documenting the likelihood that CTS is work associated is not only consistent with the expectations of State and Federal governments but also benefits patients [92–94]. Individuals with work-related CTS are entitled to medical benefits under workers’ compensation systems. If a treating healthcare professional does not assess whether an individual patient’s CTS is work-related, then that provider would be less likely to recognize when a workers’ compensation claim is appropriate. Administrative delays occur when treating healthcare professionals fail to make judgments about causation, or fail to provide a rationale for the judgments. Such delays can prevent patients from receiving necessary care in a timely fashion, which can prolong their CTS symptoms [95]. Thus, healthcare professionals treating patients with CTS have a basic responsibility to document their opinion as to the likelihood that the CTS is work-related together with a rationale. Several prior panels have come to this conclusion, as did the current panel [49, 96, 97].

Patient Education and Activity Modification

Patient education is an important component of any therapeutic treatment plan because it supports patient adherence to provider recommendations, helps patients to navigate the healthcare and workers’ compensation systems, and enables patients to play a more active role in managing their recovery. This assertion is supported by the fact that patients’ confidence in their ability to function despite having CTS was a significant predictor of return to work and work-role functioning in the studies described above [98, 99]. As with any condition, patients should be provided with basic information about common symptoms and treatments as well as prognosis. In addition, patients with CTS should be advised to avoid well-established inciting factors; such as vibration, mechanical force, frequent repetitive movements, and awkward postures; since such exposures are common in occupational and non-occupational settings [86]. An American College of Occupational and Environmental Medicine position statement makes several recommendations regarding work-associated CTS [100]. When providers judge CTS to be work-associated, patients need to understand the rationale since they are entitled to file a workers’ compensation claim and will need this information to navigate the workers’ compensation system. Since patients may not realize that unnecessary time off work is often not in their best interest, they should be apprised of this. When work-site or work-activity modifications are recommended, providers should make it clear that patients are responsible for communicating these recommendations to their employers. Lastly, when patients are well enough to safely return to work, they should be informed of this. The current panelists recognized that each of these types of education is helpful, and felt it is essential that some patient education occur. When an exposure to vibration, mechanical force, or frequent repetitive movements is present, panelists felt that patients must be instructed in modifying their activities to avoid the exposure.

Follow-up

The current panelists concluded that follow-up must occur promptly for patients with work-associated CTS. Although no studies have directly evaluated the effect of having regular follow-up on patient outcomes, several guidelines have made recommendations, which vary from every 3–5 days [49], to every two weeks [97], to at least once within six months [41]. The current panel considered follow-up within four weeks of the initial evaluation to be a minimum standard of care applicable to all patients with work-associated CTS (including those not off work).

During the first three months after CTS is diagnosed, when disability and functional status undergo the greatest changes [63], it is essential for providers to document whether or not patients are working. For patients who are on temporary disability, documenting that they have not yet returned to work is necessary in order to determine when returning would be appropriate. Among patients who are not placed on disability, monitoring work status is an important component of monitoring functional status, and is part of monitoring exposure to any occupational inciting factors.

After individuals with CTS return to work following a prolonged period of temporary disability, their CTS needs to be reassessed [97]. The current panel concluded that, at a minimum, providers should also document whether the patient is experiencing any functional limitations at their place of work, so that treatments or job tasks can be modified, if necessary.

When patients with CTS have a delayed returned to work after being on disability, physicians should identify and, when possible, treat any issues that may be interfering with recovery. Medical conditions that prior studies have identified as risk factors for delayed recovery among CTS patients include alcohol use, depression or anxiety, obesity, and smoking; although findings are not consistent across published studies [98, 99, 101–103]. Alcohol abuse and substance abuse are common and serious health problems that are challenging to detect, and the benefits of identifying them extend beyond facilitating return to work [104]. ACOEM guidelines and the position statement argue that healthcare providers can and should identify and intervene for other types of barriers to return to work [82, 100, 105].

Comparison with Occupational Medicine Guidelines

The table below compares the RAND/UCLA CTS measures with the ACOEM guideline [49]. As seen in the table, 17 measures (55%) are fully concordant, five are somewhat concordant (16%), the ACOEM guideline did not address content within eight of the measures (26%), and one measure is discordant with the guideline (3%). The measure that is discordant addresses the use of non-steroidal anti-inflammatory agents, for which recent literature has identified new risks. The RAND/UCLA measures are also largely concordant with a CTS guideline by the American Academy for Orthopedic Surgeons, although this guideline is much less detailed with respect to occupational issues [106, 107]. Table 4.

Table 4.

Comparison of RAND/UCLA CTS quality-of-care measures with the ACOEM guideline [49]

RAND/UCLA measure title	Concordance with ACOEM guideline	Comments
1. New symptoms characteristic of CTS require detailed assessment	Concordant
2. New symptoms characteristic of CTS should lead to suspicion	Concordant
3. New hand or forearm pain requires evaluation for “red flags”	Concordant
4. Symptoms inconsistent with CTS require evaluation	Concordant	Some relevant content is in guideline sections that are not specific to CTS.
5. New CTS diagnosis requires assessment of medical risk factors	Concordant
6. New suspicion of CTS requires specific physical examination	Concordant
7. New suspicion of CTS requires evaluation for overweight	Not Addressed (N/A)	Guideline does not explicitly link overweight/obesity and CTS.
8. Imaging should be used selectively for suspected CTS	Concordant
9. Symptoms should be monitored after new diagnosis of CTS	N/A	Guideline does not specify which symptoms should be monitored at follow-up visits.
10. Splints should be placed in neutral position	Concordant
11. An attempt at splinting should last at least six weeks	Somewhat Concordant	Guideline states that an attempt at splinting can last about four weeks before steroid injections is attempted
Certain medications should not be used for CTS
12. NSAIDs	Discordant	Guideline recommends NSAIDs for hand disorders in general, states that corticosteroids may be more effective than NSAIDs for CTS, but notes that the side effects of steroids are a concern
13. Muscle relaxants	N/A	Guideline does not mention the use of muscle relaxants for CTS
14. Opioids	N/A	Guideline considers a short course of opiods to be an option for hand disorders in general but does not discuss the use of opioids for CTS
15. Diuretics	N/A	Guideline does not mention the use of diuretics for CTS
16. Lasers should not be used for CTS	Concordant
17. Discuss benefits of surgery when offering steroids to patients with severe CTS	N/A
18. First time steroid treatment requires discussion of risks	N/A
19. Steroids for work-associated symptoms require follow-up	Somewhat Concordant	Guideline recommends that follow-up visits for work-related CTS be performed at a frequency of 4–7 or 7–14 days, depending upon whether the patient is working. The measure sets the minimum acceptable standard for follow-up at 4 weeks after the injection.
20. Limit steroid injections to 4	Concordant	Guideline suggests steroid injections should be used for 8-12 weeks but does not specify the number of injections, whereas the measures specify the number but not the total duration of use.
21. New CTS diagnosis requires detailed occupational history	Concordant
22. New CTS diagnosis requires assessment of occupational factors	Concordant	The CTS chapter in guideline does not specify how to assess occupational factors. The ACOEM Return to Work Position Statement provides more specific recommendations [69].
23. New CTS diagnosis requires assessment of non-occupational factors	N/A	Guideline does not discuss assessing non-occupational factors that may be associated with the CTS symptoms.
24. Exacerbating activities should be identified when CTS limits functioning	Concordant
25. Rationale for work-association should be documented	Concordant
26. Patients diagnosed with CTS should be educated about the condition	Concordant	Guideline is less specific about how patients should be educated.
27. Exposures to vibration, force, and repetition should be minimized	Somewhat Concordant	Guideline mentions force and repetition but not vibration.
28. Work-associated CTS symptoms require prompt follow-up	Somewhat Concordant	Guideline recommends that all follow-up visits for work-related CTS be performed at a frequency of 4–7 or 7–14 days, depending upon whether the patient is working. The measure sets the minimum acceptable standard for follow-up frequency at 4 weeks.
29. Work status should be monitored when CTS appears work associated	Concordant
30. Return to work after CTS-related disability requires follow-up assessment	Somewhat Concordant	Guideline does not specify a time frame for follow-up in this specific situation. Its overall recommended frequency for follow-up would suggest within 4–7 days, whereas the measure sets the minimum acceptable standard at 4 weeks after return to work.
31. Prolonged CTS-related disability should trigger evaluation	Concordant