Philadelphia Panel Evidence-Based Clinical Practice Guidelines on Selected Rehabilitation Interventions for Shoulder Pain

1. Hélène Corriveau, PhD, 
 
2. Michelle Morin, BSc, 
 
3. Lucie Pelland, PhD, 
 
4. Lucie Poulin, MSc, 
5. Michel Tousignant, PhD, 
 
6. Lucie Laferrière, MHA, 
 
7. Lynn Casimiro and
 
8. Louis E Tremblay, PhD

10. Abstract

    Introduction. A structured and rigorous methodology was developed for the formulation of evidence-based clinical practice guidelines (EBCPGs), then was used to develop EBCPGs for selected rehabilitation interventions for the management of shoulder pain. Methods. Evidence from randomized controlled trials (RCTs) and observational studies was identified and synthesized using methods defined by the Cochrane Collaboration that minimize bias by using a systematic approach to literature search, study selection, data extraction, and data synthesis. Meta-analysis was conducted where possible. The strength of evidence was graded as level I for RCTs or level II for nonrandomized studies. Developing Recommendations. An expert panel was formed by inviting stakeholder professional organizations to nominate a representative. This panel developed a set of criteria for grading the strength of both the evidence and the recommendation. The panel decided that evidence of clinically important benefit (defined as 15% greater relative to a control based on panel expertise and empiric results) in patient-important outcomes was required for a recommendation. Statistical significance was also required but was insufficient alone. Patient-important outcomes were decided by consensus as being pain, function, patient global assessment, quality of life, and return to work, providing that these outcomes were assessed with a scale for which measurement reliability and validity have been established. Validating the Recommendations. A feedback survey questionnaire was sent to 324 practitioners from 6 professional organizations. The response rate was 51%. Results. Only 1 positive recommendation of clinical benefit was developed. Ultrasound provided clinically important pain relief relative to a control for patients with calcific tendinitis in the short term (less than 2 months). There was good agreement with this recommendation from practitioners (75%). For several interventions and indications (eg, thermotherapy, therapeutic exercise, massage, electrical stimulation, mechanical traction), there was a lack of evidence regarding efficacy. Conclusions. This methodology of developing EBCPGs provides a structured approach to assessing the literature and developing EBCPGs that incorporates clinicians' feedback and is widely acceptable to practicing clinicians. Further well-designed RCTs are warranted regarding the use of several interventions for patients with shoulder pain where evidence was insufficient to make recommendations.
    • Clinical practice guidelines
       
    • Evidence-based practice
       
    • Meta-analysis
    • Physical therapy
       
    • Rehabilitation
       
    • Shoulder pain
    Previous SectionNext Section

    INTRODUCTION

    Shoulder pain is among the most common reasons for visits to a general practitioner. The prevalence of shoulder pain accompanied by disability is approximately 20% in the general population.¹ Prospective studies in Europe have shown that approximately 11 out of 1,000 patients seen by a family practitioner have shoulder pain. Over 50% of patients diagnosed by a general practitioner to have shoulder tendinitis are referred for physical therapy.²

    Numerous rehabilitation interventions are available for the management of shoulder pain, including thermotherapy, therapeutic ultrasound, transcutaneous electrical nerve stimulation (TENS), and therapeutic exercises. Among general practitioners, there is a wide variety of treatment approaches, likely related to uncertainty about the efficacy of these multiple interventions.³ Furthermore, the interpretation of shoulder pain research is complicated by the broad inclusion criteria that allow mixed populations with different etiologies of shoulder pain.

    Two systematic reviews of randomized controlled trials (RCTs) of physical treatments for shoulder pain reported no evidence of benefit for shoulder pain.^4,5Evidence-based treatment guidelines for certain interventions have been published in the British Medical Journal (BMJ) clinical series for nonspecific shoulder pain.⁶

    The purpose of this article is to describe the evidence-based clinical practice guidelines (EBCPGs) developed by the Philadelphia Panel regarding rehabilitation interventions for shoulder pain. The aim of developing the EBCPGs was to improve appropriate use of rehabilitation interventions for shoulder pain. The target users of these guidelines are physical therapists, physiatrists, orthopedic surgeons, rheumatologists, family physicians, and neurologists.
    Previous SectionNext Section

    METHODS

    The detailed methods of the EBCPGs development process are summarized in an accompanying paper in this issue (see article titled “Philadelphia Panel Evidence-Based Clinical Practice Guidelines on Selected Rehabilitation Interventions: Overview and Methodology”). Briefly, an a priori protocol was defined that was followed for the conduct of separate systematic reviews for each intervention.

    Studies were eligible if they were RCTs, nonrandomized controlled clinical trials (CCTs), or case control or cohort studies that evaluated the interventions of interest in a population with shoulder pain. Shoulder pain was defined as nonspecific shoulder pain, calcific tendinitis, bursitis, and capsulitis. Rheumatoid arthritis and osteoporotic shoulder pain were excluded from these guidelines because the underlying cause of pain is different. The outcomes of interest were chosen by consensus by the panel and included functional status, pain, ability to work, patient global assessment, patient satisfaction, and quality of life. The interventions assessed were massage, thermotherapy (hot or cold packs), electrical stimulation, TENS, therapeutic ultrasound, therapeutic exercises, and combinations of these rehabilitation interventions. Iontophoresis was excluded because it includes a mix of medication and ultrasound, and medication is not a physical rehabilitation intervention. Acceptable control groups received either a placebo therapy or no therapy. Only English-, French-, and Spanish-language articles were accepted. Abstracts were not included.

    A structured literature search was developed based on the sensitive search strategy for RCTs recommended by the Cochrane Collaboration⁷ and modifications proposed by Haynes et al.⁸ The search strategy was expanded to identify case control, cohort, and nonrandomized studies. The search was conducted in the electronic databases of MEDLINE, EMBASE, Current Contents, CINAHL, and the Cochrane Controlled Trials Register up to July 1, 2000. In addition, the registries of the Cochrane Field of Rehabilitation and Related Therapies and the Cochrane Musculoskeletal Group and the Physiotherapy Evidence Database (PEDro) were searched. The references of all included trials were searched for relevant studies. Content experts were contacted for additional studies.

    Two independent reviewers (VAR, JP) appraised the titles and abstracts of the literature search, using a checklist with the a priori defined selection criteria. Relevant studies were retrieved and the full articles were assessed by 2 independent reviewers for inclusion. Data were extracted by 2 independent reviewers from included articles, using predetermined extraction forms regarding the population characteristics, details of the interventions, trial design, allocation concealment, and outcomes. Methodological quality was assessed with on a 5-point validated scale that assigns 2 points each for randomization and double-blinding and 1 point for description of withdrawals.^9,10 Differences in data extraction and quality assessment were resolved by consensus.

    Data were analyzed at 3 approximate time points posttherapy: 1 month, 6 months, and 12 months. If outcomes were reported at different intervals, the closest time was used for these time points.

    Data were analyzed using the Review Manager (RevMan) computer program, Version 4.1 for Windows.* Continuous data were analyzed using weighted mean differences (WMDs) between the treatment and control groups at the end of study, where the weight is the inverse of the variance. Where an outcome was measured with different scales (eg, pain, functional status), the data were analyzed with standardized mean differences, calculated using the mean and standard deviation. Dichotomous data were analyzed using relative risks. Heterogeneity was tested using a chi-square statistic. When heterogeneity was not significant, fixed-effects models were used. With significant heterogeneity, random-effects models were used.

    To calculate clinical improvement (defined as 15% improvement relative to a control), the absolute benefit and the relative difference in the change from baseline were calculated. Absolute benefit was calculated as the improvement in the treatment group less the improvement in the control group, in the original units. Relative difference in the change from baseline was calculated as the absolute benefit divided by the baseline mean (weighted for the treatment and control groups). For dichotomous data, the relative percentage of improvement was calculated as the difference in the percentage of improvement in the treatment and control groups.

    The recommendations were graded by their level of evidence (I or II) and by the strength of evidence (A, B, or C). This grading system is shown in Table 1 and is described more fully elsewhere (see article titled “Philadelphia Panel Evidence-Based Clinical Practice Guidelines on Selected Rehabilitation Interventions: Overview and Methodology”). A master grid showing each rehabilitation intervention assessed and the strength and level of evidence is shown in Table 2. For those interventions for which 1 or more eligible studies were found, the results follow the same order as this grid (from left to right, top to bottom).

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 1.
    

    Details of Philadelphia Panel Classification System

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 2.
    

    Master Grid of Shoulder Pain Guidelines^a

    Clinically important benefit was shown for therapeutic ultrasound for calcific tendinitis (Tab. 3). There is no evidence of clinically important benefit for therapeutic ultrasound for other types of shoulder pain (capsulitis, bursitis, tendinitis) (Tab. 4).

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 3.
    

    Grade A Guideline: Clinically Important Benefit Demonstrated^a

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 4.
    

    Grade C Rehabilitation Interventions: No Evidence of Clinically Important Benefit^a

    Therapeutic exercises, TENS, thermotherapy, and massage have limited evidence available, but the trials available were insufficient to draw conclusions^11–16 (Tab. 5). The Philadelphia Panel EBCPGs are compared with other published guidelines inAppendix 1.

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 5.
    

    Rehabilitation Interventions With Insufficient Data^a

    A survey questionnaire was sent to 324 practitioners for feedback on the 9 grade A or B recommendations. Their comments were reviewed by the Philadelphia Panel and were incorporated in this EBCPG document.
    Previous SectionNext Section

    RESULTS

    Literature Search

    The electronic literature search and hand-searching identified 2,496 citations that pertained to shoulder pain. Of these, 54 were retrieved for closer examination after screening the titles and abstracts. Of these, only 23 met the inclusion criteria, and 12 citations that met the inclusion criteria were excluded due to irrelevant outcomes or lack of appropriate control group (Fig. 1).

    
    

    View larger version:
    

    • In this page
       
    • In a new window

    • Download as PowerPoint Slide

    Figure 1.
    

    Cityscape of number of trials identified for shoulder pain. EMG=electromyographic, TENS=transcutaneous electrical nerve stimulation.
    Previous SectionNext Section

    CALCIFIC SHOULDER TENDINITIS

    Eligible studies were identified only for therapeutic ultrasound.

    Therapeutic Ultrasound for Calcific Shoulder Tendinitis, Level I (RCT), Grade A for Pain and Function (Clinically Important Benefit)

    Summary of Trials:

    One RCT (N=61) was included of therapeutic ultrasound versus a placebo for calcific tendinitis of the shoulder.¹⁷ One CCT was excluded because no outcomes of interest were reported¹⁸ (only range of motion [ROM] and size of calcified deposit were reported). One RCT (N=22) was excluded because acetic acid iontophoresis was combined with therapeutic ultrasound.¹⁹

    Efficacy:

    Clinically important benefit demonstrated. There was a clinically important and statistically significant reduction in pain (77% relative to the control group) and improvement in functional status (15% relative to the control group) after 2 months of therapy (Tab. 6, Fig. 2). There was also a decrease in calcification of 37% relative to placebo¹⁷ (Tab. 7) (P<.05). There were no differences between groups at 9 months posttherapy.¹⁷

    
    

    View larger version:
    

    • In this page
       
    • In a new window

    • Download as PowerPoint Slide

    Figure 2.
    

    Therapeutic ultrasound versus placebo for calcific shoulder tendinitis: pain at 2 and 9 months. VAS=visual analog scale, CI=confidence interval.

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 6.
    

    Pain, Function, and Quality of Life After 2 Months of Therapeutic Ultrasound for Calcific Shoulder Tendinitis^a

    View this table:
    

    • In this window
       
    • In a new window

    • Download as PowerPoint Slide

    Table 7.
    

    Calcification 9 Months After Therapeutic Ultrasound for Calcific Shoulder Tendinitis^a

    Strength of Published Evidence in Comparison With Other Guidelines:

    The Philadelphia Panel found good evidence (level I, RCT) of benefit with therapeutic ultrasound at 2 months, but no difference after the end of 9 months of therapy.

    Clinical Recommendation in Comparison With Other Guidelines:

    The Philadelphia Panel recommends there is good evidence to include continuous therapeutic ultrasound (5 times per week) as an intervention for short-term pain relief of calcific shoulder tendinitis (level I, grade A for pain and function) for a 2-month period.

    Practitioner Agreement

    • Response rate for this EBCPG: 49%
    • Percentage of practitioners giving comments for this EBCPG: 32%
    • Agree with recommendation: 76%
    • Think a majority of my colleagues would agree: 61%
    • Will (or already) follow this recommendation: 81%

    Practitioner Comments

    1. No difference at 9 months, so why recommend?
    2. Frequency of treatment was very high in study by Ebenlicher et al¹⁷ (5 times per week for 3 weeks).
    3. Exercise is very helpful for these patients. Why was it not evaluated?

    Panel's Response:

    The EBCPG clearly specifies the lack of effect at 9 months, so that clinicians can decide whether a short-term benefit is desirable. The frequency of treatment is now specified in the EBCPG. No trials of exercise for shoulder tendinitis met the inclusion criteria for the EBCPG development process, as described in Table 5.
    Previous SectionNext Section

    NONSPECIFIC SHOULDER PAIN

    Therapeutic Ultrasound for Nonspecific Shoulder Pain (Capsulitis, Bursitis, Tendinitis), Level I (RCT), Grade C for Pain, Patient Global Assessment, and Function (No Evidence of Benefit)

    Summary of Trials:

    Four RCTs^20–23 and 3 CCTs^24–26 were identified that compared therapeutic ultrasound with a placebo. Three trials were excluded due to lack of a placebo (or untreated) control group.^14,16,27 One retrospective study of therapeutic ultrasound versus no intervention was excluded.²⁸

    Efficacy:

    None demonstrated. Two RCTs (N=40) compared continuous therapeutic ultrasound with a placebo.^20,21 Meta-analysis of pain and function showed no evidence of benefit at 2, 4, or 8 weeks. Two RCTs (N=253) compared pulsed therapeutic ultrasound with a palcebo and found no difference in pain or function.^22,23 The results from 2 CCTs (N=50) also failed to show a significant or minimal clincally important benefit of therapeutic ultrasound on pain, patient global assessment, or function as measured by activities of daily living (ADL).^24–26The pooled results for pain and ADL are shown in Figure 3. One CCT (n=20) demonstrated a 37% relative difference in pain between therapeutic ultrasound (81%, 9 out of 11 patients) and placebo (44%, 4 out of 9 patients) 3 weeks posttherapy, but this difference was not staistically significant.²⁵

    
    

    View larger version:
    

    • In this page
       
    • In a new window

    • Download as PowerPoint Slide

    Figure 3.
    

    Therapeutic ultrasound for shoulder capsulitis, bursitis, or tendinitis: pain and function at 1 month. VAS=visual analog scale, ADL=activities of daily living, CI=confidence interval.

    Strength of Published Evidence in Comparison With Other Guidelines:

    The Philadelphia Panel found good scientific evidence (level I, RCTs), which showed no evidence of benefit.

    Clinical Recommendation in Comparison With Other Guidelines:

    The Philadelphia Panel recommends there is poor evidence to include or exclude either continuous or pulsed therapeutic ultrasound alone (grade C for pain, patient global assessment, and function) as an intervention for nonspecific shoulder pain (due to capsulitis, bursitis, or tendinitis).

    Interventions With Insufficient Evidence

    For therapeutic exercises, 2 CCTs were identified of therapeutic exercises versus a control for shoulder pain, but these trials were excluded due to nonvalidated outcomes¹¹ and poorly defined diagnoses.¹² One RCT (N=80) compared a group that received exercise with a control group that received detuned laser.²⁹ There was better functional status (as indicated by the Neer shoulder score) and less pain in the exercise group at both 3 and 6 months; however, no variance was available, so the data could not be analyzed.²⁹ Several trials without control groups were excluded that compared different types of exercise.^30–33

    For thermotherapy, one CCT of ice versus a control was excluded because no outcomes of interest were measured (ROM only).³⁴

    For TENS, one comparative RCT versus therapeutic ultrasound was excluded.¹⁶

    Therapeutic massage was used as a cointervention in a physical therapy group, but the effects of the individual massage component of the program could not be determined.¹⁵

    Electromyographic (EMG) biofeedback was superior to traditional exercises for anterior shoulder instability in one RCT.³² However, because there was no control group, it is impossible to draw conclusions about the efficacy of EMG biofeedback.

    Electrical stimulation was not used in any of the studies identified.
    Previous SectionNext Section

    DISCUSSION

    A thorough literature search, data synthesis using meta-analysis, quality assessment, and consensus panel assessment have reviewed the evidence for 7 rehabilitation interventions for shoulder pain. Only 1 intervention (therapeutic ultrasound for calcified shoulder tendinitis) was shown to have a clinically important benefit.

    As with other systematic reviews and guideline development projects, there are methodologic limitations. These limitations are discussed in the accompanying methodology article (see article titled “Philadelphia Panel Evidence-Based Clinical Practice Guidelines on Selected Rehabilitation Interventions: Overview and Methodology” in this issue).

    The effectiveness of rehabilitation interventions for the management of shoulder pain is a complex issue. Rehabilitation specialists use concomitant treatment interventions in daily practice.^15,35 The therapeutic application of several concurrent rehabilitation interventions are based on empirical experience,^35–37and the measurement of their effects is complex.³⁸ The practice of rehabilitation requires a better theoretical basis^39,40 and well-designed controlled trials.⁴¹

    The Philadelphia Panel EBCPGs for the management of shoulder pain are largely in agreement with previous and recent EBCPGs⁶ for shoulder joint pain exhibited inAppendix 1. The Philadelphia Panel EBCPGs for shoulder joint pain have the advantage that they were developed based on a systematic grading of the evidence determined by an expert panel, and the evidence was derived from systematic reviews and meta-analyses using the Cochrane Collaboration methodology. The finalized EBCPGs were circulated for feedback from practitioners to verify their applicability and ease of use for practicing clinicians. This rigorous methodological procedure provides considerable credibility for rehabilitation specialists who intend to use these EBCPGs for the management of shoulder joint pain in their daily practice.

    There are very few published guidelines for the management of shoulder pain. Managed care guidelines have been developed based on observations and expert opinion.⁴² Preferred conservative treatment programs are described by the American Physical Therapy Association.⁴³ However, these guidelines are vague concerning which interventions should be used and are not based on a scientific review of the evidence.

    There are several rehabilitation interventions that were not assessed by this panel, such as the use of intra-articular corticosteroid injections. There is evidence from meta-analysis and clinical trials that these interventions may offer clinically important benefit on shoulder function and pain relief.^44,45 The practitioner managing a patient needs to consider other interventions that have not been assessed by this EBCPG development project.

    Therapeutic Ultrasound

    Therapeutic ultrasound showed clinically important benefit for calcified shoulder tendinitis.¹⁷ However, ultrasound was not shown to provide clinically important benefit for nonspecific shoulder pain such as capsulitis, bursitis, or tendinitis. Phonophoresis was not considered in our systematic review. The Philadelphia Panel recommendation regarding nonspecific shoulder pain (level I, grade C) agrees with the BMJ guidelines, which also concluded that evidence for the effectiveness of ultrasound is lacking. It is suggested that therapeutic ultrasound is one of the rehabilitation interventions that is selectively effective, depending on the condition treated or the characteristics of therapeutic application.^46,47

    The RCTs were of good quality (4 out of 5 on the Jadad scale^9,10) (Appendix 2). The highest methodological quality was found in the more recent RCTs.^17,23 The type of therapeutic ultrasound was continuous in all trials, except for one trial²³ in which a pulsed therapeutic ultrasound type was used for a chronic shoulder condition. It is clinically recommended to use a continuous mode in chronic conditions.⁴⁸ There was a wide variety of diagnostic groups, therapeutic applications, and follow-up durations. Calibration of the therapeutic ultrasound device was not described in most studies. These results concur partially with previous systematic reviews^5,35,49 of nonspecific shoulder pain or soft tissue shoulder disorders. These 3 systematic reviews did not include the most recent trial on calcified shoulder tendinitis¹⁷ in their analyses. Further investigations should be conducted on the optimal therapeutic application of therapeutic ultrasound in relation to the type of conditions managed.^35,48

    Therapeutic Exercises, EMG Biofeedback, TENS, Thermotherapy, Therapeutic Massage, Electrical Stimulation, and Combined Rehabilitation Interventions

    Despite the fact there is a positive physiological effect of these interventions,^46,50–55 there are no clinical data or insufficient clinical information on the effectiveness of therapeutic exercises, EMG biofeedback, TENS, thermotherapy, therapeutic massage, electrical stimulation, and combined rehabilitation interventions for shoulder joint pain. These results concur with recent systematic reviews on physical rehabilitation interventions for painful shoulders.^4,5,44 These researchers included comparative trials as well as placebo-controlled trials. Conclusions of head-to-head comparison could lead to results that 2 rehabilitation interventions are equally effective or equally ineffective.⁴⁴Firm conclusions of efficacy require comparison with a standard treatment. Is there a standard treatment in physical rehabilitation? Obviously, there is an urgent need to conduct well-designed studies on the effectiveness of these interventions for shoulder pain.

    Special attention on the characteristics of the therapeutic application³⁹ is needed in the field of rehabilitation. For example, the types of exercises used, adequate exercise intensity, and progression need to be clarified according to patient-specific classification of physical dysfunction, needs, treatment goals, and outcomes.^56,57 The effectiveness of massage could be influenced by the types of maneuvers used, the massage approach adopted, years of experience of the therapist, number and size of the muscles involved, the patient's position used, pressure exerted, rhythm and progression, and frequency and duration of the treatment sessions.⁵² The characteristics of a specific clinical device and the selection of treatment variables are of key importance.^{50,51,53,58–60}

    The Philadelphia Panel was unable to make clinical recommendations regarding these interventions for shoulder pain. This is in agreement with the BMJ⁶ for all of these rehabilitation interventions except for TENS. The BMJ⁶ found good evidence regarding the effectiveness of TENS for the management of shoulder pain as opposed to the Philadelphia Panel, but this finding was based on the use of TENS during distension arthrography. This surgical intervention was excluded from the Philadelphia Panel review. For therapeutic exercises, the BMJ⁶ reported no evidence for exercises compared with manual therapy for shoulder pain. No recommendation, however, was made for therapeutic exercises alone.

    Overall

    The main difficulty in determining the effectiveness of rehabilitation interventions is the lack of well-designed prospective RCTs. Future research in physical therapy should adopt rigorous methods such as the use of an appropriate placebo (and double-blind procedure), adequate randomization, homogeneous sample of patients based on rigorous selection and diagnosis criteria, and adequate sample size to detect clinically important differences with confidence.

    There is an urgent need for RCTs to determine whether commonly applied rehabilitation interventions for shoulder pain are effective at reducing pain and improving long-term patient-important outcomes. This research should pay attention to the dosing schedule, in terms of device characteristics for electrical modalities and duration and frequency of sessions for physical treatments. Furthermore, the adherence to recommended therapy should be considered in the analysis.
    Previous SectionNext Section

    CONCLUSION

    There is evidence to support and recommend the use of therapeutic ultrasound for calcified shoulder tendinitis. There is a lack of evidence at present regarding whether to include or exclude the use of therapeutic exercises, thermotherapy, therapeutic massage, EMG biofeedback, TENS, electrical stimulation, and combined rehabilitation interventions for nonspecific shoulder pain in the daily practice of physical rehabilitation.
    Previous SectionNext Section

    Appendix 1.

    
    

    View larger version:
    

    • In this page
       
    • In a new window

    • Download as PowerPoint Slide

    Appendix 1.
    

    Strength of Published Evidence and Clinical Recommendations of Previous Evidence-Based Clinical Practice Guidelines (EBCPGs) for Shoulder Pain
    Previous SectionNext Section

    Appendix 2.

    
    

    View larger version:
    

    • In this page
       
    • In a new window

    • Download as PowerPoint Slide

    Appendix 2.
    

    Characteristics of Included Trials
    Previous SectionNext Section

    Footnotes

    • This study was financially supported by an unrestricted educational grant from the Cigna Foundation, Philadelphia, Pa, USA; the Ministry of Human Resources and Development, Government of Canada (Summer Students Program); and the Ontario Ministry of Health and Long-Term Care (Canada). Ian Graham is a Medical Research Council Scholar, Canadian Institutes of Health Research (Canada).
      Acknowledgments: Summer students: Sarah Milne, Michael Saginur, Marie-Josée Noël, Mélanie Brophy, Anne Mailhot
    • ↵* Oxford, England: The Cochrane Collaboration, 2000.
    • Physical Therapy
    Previous Section
    

    References

    1. ↵ 
       Pope DP, Croft PR, Pritchard CM, Silman AJ. Prevalence of shoulder pain in the community: the influence of case definition. Ann Rheum Dis.1997;56:308–312.

       
       

       Abstract/FREE Full Text
    2. ↵ 
       van der Windt DA, Koes BW, de Jong BA, Bouter LM. Shoulder disorders in general practice: incidence, patient characteristics, and management. Ann Rheum Dis.1995 ;54:959–964.

       
       

       Abstract/FREE Full Text
    3. ↵ 
       Johansson K, Adolfsson L, Foldevi M. Attitudes toward management of patients with subacromial pain in Swedish primary care. Fam Pract.1999;16:233–237.

       
       

       Abstract/FREE Full Text
    4. ↵ 
       Green S, Buchbinder R, Glazier R, Forbes A. Systematic review of randomised controlled trials of interventions for painful shoulder: selection criteria, outcomes assessment, and efficacy. BMJ.1998 ;316:354–360.

       Abstract/FREE Full Text
    5. ↵ 
       van der Heijden GJ, van der Windt DA, de Winter AF. Physiotherapy for patients with soft tissue shoulder disorders: a systematic review of randomised clinical trial. BMJ.1997 ;315(7099):25–30.
    6. ↵ 
       Clinical Evidence: A Compendium of the Best Available Evidence for Effective Health Care. London, England: BMJ Publishing Group;2000 (issue 4). Available at: www.clinicalevidence.org.
    7. ↵ 
       Dickersin K. The existence of publication bias and risk factors for its occurrence. JAMA.1990 ;263:1385–1389.

       
       

       CrossRefMedline
    8. ↵ 
       Haynes R, Wilczynski N, Mckibbon KA, Walker CJ. Developing optimal search strategies for detecting clinically sound studies in MEDLINE. Journal of the American Medical Information Association.1994 ;1:447–458.
    9. ↵ 
       Jadad AR, Moore RA, Carroll D, et al. Assessing the quality of reports of randomized trials: is blinding necessary? Control Clin Trials.1996 ;17:1–12.

       CrossRefMedline
    10. ↵ 
        Clark HD, Wells GA, Huet C, et al. Assessing the quality of randomized trials: reliability of the Jadad scale. Control Clin Trials.1999 ;20:448–452.

        CrossRefMedline
    11. ↵ 
        Ginn KA, Herbert RD, Khouw W, Lee R. A randomized, controlled clinical trial of a treatment for shoulder pain. Phys Ther.1997 ;77:802–809.

        Abstract/FREE Full Text
    12. ↵ 
        Pearlmutter LL, Bode BY, Wilkinson WE, Maricic MJ. Shoulder range of motion in patients with osteoporosis. Arthritis Care Res.1995 ;8:194–198.

        CrossRefMedline
    13. Binder AI, Bulgen DY, Hazleman BL, Roberts S. Frozen shoulder: a long-term prospective study. Ann Rheum Dis.1984 ;43:361–364.

        Abstract/FREE Full Text
    14. ↵ 
        Hamer J, Kirk JA. Physiotherapy and the frozen shoulder: a comparative trial of ice and ultrasonic therapy. N Z Med J.1976 ;83:191–192.

        
        

        Medline
    15. ↵ 
        Vasseljen O Jr, Johansen BM, Westgaard RH. The effect of pain reduction on perceived tension and EMG-recorded trapezius muscle activity in workers with shoulder and neck pain. Scand J Rehabil Med.1995 ;27:243–252.

        Medline
    16. ↵ 
        Herrera-Lasso I, Mobarak L, Fernandez-Dominguez L, et al. Comparative effectiveness of packages of treatment including ultrasound or transcutaneous electrical nerve stimulation in painful shoulder syndrome.Physiotherapy.1993 ;79:251–253.
    17. ↵ 
        Ebenlichler GR, Erdogmus CB, Resch KL, et al. Ultrasound therapy for calcific tendinitis of the shoulder. N Engl J Med.1999 ;340:1533–1538.

        CrossRefMedline
    18. ↵ 
        Flax H. Ultrasound treatment of peritendinitis calcarea of the shoulder. Am J Phys Med.1964 ;43:117–14.

        
        

        Medline
    19. ↵ 
        Perron M, Malouin F. Acetic acid iontophoresis and ultrasound for the treatment of calcifying tendinitis of the shoulder: randomized control trial.Arch Phys Med Rehabil.1997 ;78:379–384.

        
        

        CrossRefMedline
    20. ↵ 
        Berry H, Fernandes L, Bloom B, et al. Clinical study comparing acupuncture, physiotherapy, injection and oral anti-inflammatory therapy in shoulder-cuff lesions. Curr Med Res Opin.1980 ;7:121–126.

        
        

        CrossRefMedline
    21. ↵ 
        Downing DS, Weinstein A. Ultrasound therapy of subacromial bursitis: a double blind trial. Phys Ther.1986 ;66:194–199.

        
        

        Abstract/FREE Full Text
    22. ↵ 
        Nykanen M. Pulsed ultrasound treatment of the painful shoulder: a randomized, double-blind, placebo-controlled study. Scand J Rehabil Med.1995 ;27:105–108.

        
        

        Medline
    23. ↵ 
        van der Heijden GJ, Leffers P, Wolters PJ, et al. No effect of bipolar interferential electrotherapy and pulsed ultrasound for soft tissue shoulder disorders: a randomised controlled trial. Ann Rheum Dis.1999 ;58:530–540.

        Abstract/FREE Full Text
    24. ↵ 
        Mueller EE, Mead S, Schulz BF, Vaden MR. A placebo-controlled study of ultrasound treatment for periarthritis. Am J Phys Med.1954 ;33:31–35.

        Medline
    25. ↵ 
        Munting E. Ultrasonic therapy for painful shoulders. Physiotherapy.1978;64:180–181.

        
        

        Medline
    26. ↵ 
        Roman MP. A clinical evaluation of ultrasound by use of a placebo technic.Phys Ther Rev.1960 ;40:649–652.

        
        

        Medline
    27. ↵ 
        Delacerda FG. A comparative study of ultrasound. J Orthop Sports Phys Ther.1982 ;4:51–54.
    28. ↵ 
        Hazleman BL. The painful stiff shoulder. Rheum Phys Med.1972 ;11:413–420.
    29. ↵ 
        Brox JI, Staff PH, Ljunggren AE, Brevik JI. Arthroscopic surgery compared with supervised exercises in patients with rotator cuff disease (stage II impingement syndrome) [published erratum appears in BMJ. 1993;307(6914):1269]. BMJ.1993 ;307(6909):899–903.
    30. ↵ 
        Randlov A, Ostergaard M, Manniche C, et al. Intensive dynamic training for females with chronic neck/shoulder pain: a randomized controlled trial. Clin Rehabil.1998 ;12:200–210.

        
        

        Abstract/FREE Full Text
    31. Levoska S, Keinanen-Kiukaanniemi S. Active or passive physiotherapy for occupational cervicobrachial disorders? A comparison of two treatment methods with a 1-year follow-up. Arch Phys Med Rehabil.1993 ;74:425–430.

        Medline
    32. ↵ 
        Reid DC, Saboe LA, Chepeha JC. Anterior shoulder instability in athletes: comparison of isokinetic resistance exercises and an electromyographic biofeedback re-education program—a pilot program. Physiotherapy Canada.1996 ;48:251–256.
    33. ↵ 
        Lundberg BJ, Svenungson-Hartwig E, Wikmark R. Independent exercises versus physiotherapy in nondisplaced proximal humeral fractures. Scand J Rehabil Med.1979 ;11:133–136.

        
        

        Medline
    34. ↵ 
        Bulgen DY, Binder AI, Hazleman BL, et al. Frozen shoulder: prospective clinical study with an evaluation of three treatment regimens. Ann Rheum Dis.1984 ;43:353–360.

        
        

        Abstract/FREE Full Text
    35. ↵ 
        Gam AN, Johannsen F. Ultrasound therapy in musculoskeletal disorders: a meta-analysis. Pain.1995 ;63:85–91.

        
        

        CrossRefMedline
    36. Delitto A. Clinicians and researchers who treat and study patients with low back pain: are you listening? Phys Ther.1998 ;78:705–707.

        Abstract/FREE Full Text
    37. ↵ 
        Jette AM, Delitto A. Physical therapy treatment choices for musculoskeletal impairments. Phys Ther.1997 ;77:145–154.

        
        

        Abstract/FREE Full Text
    38. ↵ 
        Delitto A. Are measures of function and disability important in low back care? Phys Ther.1994 ;74:452–462.

        
        

        Abstract/FREE Full Text
    39. ↵ 
        Morin M, Brosseau L, Quirion-DeGrardi C. A theoretical framework on low level laser therapy (classes I, II, and III) application for the treatment of OA and RA. In: Proceedings of the Canadian Physiotherapy Association National Congress.1996 :1.
    40. ↵ 
        Rothstein JM. Editor's note: Theoretically speaking. Phys Ther.1991;71:789–790.

        
        

        Abstract/FREE Full Text
    41. ↵ 
        Schlapbach P, Gerber NJ. Physiotherapy: Controlled Trials and Facts. Basel, Switzerland: Karger,1991 .
    42. ↵ 
        West Virginia Workers' Compensation Treatment Guidelines. Vol 1. Approved by the Health Care Advisory Panel and the Performance Council West Virginia Workers' Compensation Division, West Virginia,1995 .
    43. ↵ 
        Guide to Physical Therapist Practice: Second Edition. Alexandria, Va: American Physical Therapy Association,2001 .
    44. ↵ 
        Green S, Buchbinder R, Glazier RH, Forbes A. Interventions for Shoulder Pain (Cochrane Review). Oxford, England: The Cochrane Library, The Cochrane Collaboration,1999 :1.
    45. ↵ 
        van der Windt DA, Koes BW, Deville W, et al. Effectiveness of corticosteroid injections versus physiotherapy for treatment of painful stiff shoulder in primary care: randomised trial. BMJ.1998 ;317(7168):1292–1296.
    46. ↵ 
        Chapman CE. Can the use of physical modalities for pain control be rationalized by the research evidence? Can J Physiol Pharmacol.1991;69:704–712.

        
        

        Medline
    47. ↵ 
        Stratford PW. Who will decide the efficacy of physiotherapeutic interventions? Physiotherapy Canada.1999 ;51:235–238.
    48. ↵ 
        Hartley A. Therapeutic Ultrasound. 2nd ed. Etobicoke, Ontario, Canada: Anne Hartley Agency,1993 .
    49. ↵ 
        van der Windt DA, van der Heijden GJ, van den Berg SG, et al. Ultrasound therapy for musculoskeletal disorders: a systematic review. Pain.1999;81:257–271.

        
        

        CrossRefMedline
    50. ↵ 
        Baker LL. Electrical stimulation to increase functional activity. In: Nelson RM, Hayes KW, Currier DP, eds. Clinical Electrotherapy. 3rd ed. East Norwalk, Conn: Appleton & Lange,1999 :355–409.
    51. ↵ 
        Barr JO. Transcutaneous electrical nerve stimulation for pain management. In: Nelson RM, Hayes KW, Currier DP, eds. Clinical Electrotherapy. 3rd ed. East Norwalk, Conn: Appleton & Lange,1999 :291–354.
    52. ↵ 
        Furlan A, Wong J, Brosseau L, Welch V. Massage for Low Back Pain [Update software]. Oxford, England: The Cochrane Library, The Cochrane Collaboration,2000 :5.
    53. ↵ 
        Hanke TA. Therapeutic uses of Biofeedback. In: Nelson RM, Hayes KW, Currier DP, eds. Clinical Electrotherapy. 3rd ed. East Norwalk, Conn: Appleton & Lange,1999 :489–522.
    54. Hebert J, Boucher JP. Effect of manual segmental vibration on neuromuscular excitability. J Manipulative Physiol Ther.1998 ;21:528–533.

        
        

        Medline
    55. ↵ 
        Knight K. Cryotherapy in Sport Injury Management. Champaign, Ill: Human Kinetics Inc,1995 .
    56. ↵ 
        Cleroux J, Feldman RD, Petrella RD. Recommendations on physical exercise training. Can Med Assoc J.1999 ;160(suppl):21s–28s.

        
        

        Abstract
    57. ↵ 
        Hilde G, Bo K. Effect of exercise in the treatment of chronic low back pain: a systematic review emphasising type and dose of exercise. Physical Therapy Reviews.1998 ;3:107–117.
    58. ↵ 
        Nash TP, Williams JD, Machin D. TENS: does the type of stimulus really matter? The Pain Clinic.1990 ;3:161–168.
    59. Guieu R, Tardy-Gervet MF, Roll JP. Analgesic effects of vibration and transcutaneous electrical nerve stimulation applied separately and simultaneously to patients with chronic pain. Can J Neurol Sci.1991 ;18:113–119.

        
        

        Medline
    60. ↵ 
        Tardy-Gervet MF, Guieu R, Ribot-Ciscar E, Roll JP. Les vibrations mécaniques transcutanées: effets antalgiques et mécanismes antinociceptifs.Rev Neurol (Paris).1993 ;149:177–185.

        
        

        Medline