Extracorporeal Shock Wave Treatment for Plantar Faciitis and Other Musculoskeletal Conditions - CAM 20140HB

Description:  
Extracorporeal shock wave therapy (ESWT) is a noninvasive method used to treat pain with shock or sound waves directed from outside the body onto the area to be treated (e.g., the heel in the case of plantar fasciitis). Shock waves are generated at high- or low-energy intensity, and treatment protocols can include more than 1 treatment. ESWT has been investigated for use in a variety of musculoskeletal conditions.

For individuals who have plantar fasciitis who receive ESWT, the evidence includes 2 recent systematic reviews containing 9 randomized controlled trials (RCTs) each (8 overlapping RCTs). Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. While most the same trials are included in both meta-analyses, pooled results were inconsistent. One meta-analysis reported that ESWT was beneficial in improving pain reduction, while the other reported nonsignificant findings in pain reduction. Reasons for the differing results include lack of uniformity in the definitions of outcomes, and heterogeneity in ESWT protocols (focused vs radial, number and duration of shocks per treatment, the number of treatments). The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have lateral epicondylitis who receive ESWT, the evidence includes small RCTs. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. Overall, although some RCTs have demonstrated benefits in pain and functional outcomes associated with ESWT, the limited amount of high-quality RCT evidence precludes conclusions about the efficacy of ESWT for lateral epicondylitis. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have shoulder tendinopathy who receive ESWT, the evidence includes 2 recent network meta-analyses as well as several systematic reviews and meta-analyses of RCTs. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The network meta-analyses focused on 3 outcomes: pain reduction, functional assessment, and change in calcific deposits. One network meta-analysis separated trials using high-energy focused ESWT (H-FSW), low-energy ESWT, and radial ESWT (RSW). This analysis reported the most effective treatment for pain reduction was ultrasound-guided needling, followed by RSW and H-FSW. The only treatment showing a benefit in functional outcomes was H-FSW. For the largest change in calcific deposits, the most effective treatment was ultrasound-guided needling, followed by RSW, then H-FSW. Many of the RCTs are considered poor quality. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have Achilles tendinopathy who receive ESWT, the evidence includes systematic reviews of RCTs and nonrandomized studies. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. In the most recent systematic review, a pooled analysis reported that ESWT reduced both short- and long-term pain compared with nonoperative treatments, although the authors warned that results were inconsistent across the RCTs and that there was heterogeneity across studies in patient populations and treatment protocols. An RCT published after the systematic review compared ESWT with hyaluronan injections and reported improvements in both treatment groups, although the improvements were significantly higher in the injection group. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have patellar tendinopathy who receive ESWT, the evidence includes systematic reviews of small studies, plus an RCT published after the systematic review. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The studies reported inconsistent results. Many had methodologic deficiencies such as small numbers, short follow-up periods, and heterogeneous treatment protocols. Results from a nonrandomized study suggested that the location of the patellar tendinopathy might impact the response to ESWT (patients with retropatella fat extension did not respond to RSW compared with patients with tendon involvement). The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have medial tibial stress syndrome who receive ESWT, the evidence includes a small RCT and a small nonrandomized cohort study. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The RCT reported no difference in selfreported pain between study groups. The cohort study reported improvements with ESWT, although selection bias impacts the strength of the conclusions. The available evidence is limited and inconsistent; it does not permit conclusions about the benefits of ESWT for medial tibial stress syndrome. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have osteonecrosis of the femoral head who receive ESWT, the evidence includes 2 systematic reviews of small, mostly nonrandomized studies. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. While many of the studies have suggested that ESWT might be effective in improving motor function and pain, particularly in patients with early-stage osteonecrosis, the studies were low quality based on lack of blinding, lack of comparators, small ample sizes, and short follow-up. Treatment protocols also differed between studies. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have nonunion or delayed union who receive ESWT, the evidence includes a systematic review of a RCT and several case series, as well as 2 RCTs published after the systematic review. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The review concluded that the evidence was inconsistent and of poor quality. Data pooling was not possible due to the heterogeneity of outcome definitions and treatment protocols. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals who have spasticity who receive ESWT, the evidence includes RCTs and systematic reviews. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. As a treatment for spasticity, several small studies have demonstrated ESWT provides short-term improvements in Modified Ashworth Scale scores, but direct evidence on the effect of ESWT on more clinically meaningful measures (eg, pain, function) are lacking. Differences in treatment parameters among studies, including energy dosage, method of generating and directing shock waves, and use or absence of anesthesia, limit generalizations about the evidence base. The evidence is insufficient to determine the effects of the technology on health outcomes.

Background 
Chronic Musculoskeletal Conditions
Chronic musculoskeletal conditions (e.g., tendinitis) can be associated with a substantial degree of scarring and calcium deposition. Calcium deposits may restrict motion and encroach on other structures, such as nerves and blood vessels, causing pain and decreased function. One hypothesis is that disruption of calcific deposits by shock waves may loosen adjacent structures and promote resorption of calcium, thereby decreasing pain and improving function.

Plantar Fasciitis
Plantar fasciitis is a common ailment characterized by deep pain in the plantar aspect of the heel, particularly on arising from bed. While the pain may subside with activity, in some patients the pain persists, interrupting activities of daily living. On physical examination, firm pressure will elicit a tender spot over the medial tubercle of the calcaneus. The exact etiology of plantar fasciitis is unclear, although repetitive injury is suspected. Heel spurs are a common associated finding, although it is unproven that heel spurs cause the pain. Asymptomatic heel spurs can be found in up to 10% of the population.

Tendinitis and Tendinopathies
Common tendinitis and tendinopathy syndromes are summarized in Table 1. Many tendinitis and tendinopathy syndromes are related to overuse injury.

Table 1. Tendinitis and Tendinopathy Syndromes

Disorder Location Symptoms Conservative Therapy Other Therapies
Lateral epicondylitis (tennis elbow) Lateral elbow (insertion of wrist extensors) Tenderness over lateral opicondyle and proximal wrist extensor muscle mass; pain with resisted wrist extension with elbow in full extensionl pain with passive terminal wrist flexion with the elbow in full extension
  • Rest
  • Activity modification
  • NSAIDs
  • Physical therapy
  • Orthotic devices
Corticosteroid injections; joint debridement (open or laparoscopic)
Shoulder tendinopathy Rotator cuff muscle tendons, most commonly supraspinatus Pain with overhead activity
  • Rest
  • Ice
  • NSAIDs
  • Physical therapy
Corticosteroid injections
Achilles tendinopathy Achilles tendon Pain or stiffness 2 – 6 cm above the posterior calcaneus
  • Avoidance of aggravating activities
  • Ice when symptomatic
  • NSAIDs
  • Heel lift
Surgical repair for tendon rupture
Patellar tendinopathy ("jumper's knee") Proximal tendon at lower pole of the patella Pain over anterior knee and patellar tendon; may progress to tendon calcification and/or tear
  • Icing
  • Supportive taping
  • Patellar tendon straps
  • NSAIDs
 

NSAIDs: nonsteroidal anti-inflammatory drugs.

Fracture Nonunion and Delayed Union
The definition of a fracture nonunion remains controversial, particularly the duration necessary to define nonunion. One proposed definition is a failure of progression of fracture healing for at least 3 consecutive months (and at least 6 months after the fracture) accompanied by clinical symptoms of delayed/nonunion (pain, difficulty weight bearing). The following criteria to define nonunion were used to inform this review:

  • At least 3 months since the date of fracture.
  • Serial radiographs have confirmed that no progressive signs of healing have occurred.
  • The fracture gap is 1 cm or less.
  • The patient can be adequately immobilized and is of an age likely to comply with no-weight-bearing.

The delayed union can be defined as a decelerating healing process, as determined by serial radiographs, together with a lack of clinical and radiologic evidence of union, bony continuity, or bone reaction at the fracture site for no less than 3 months from the index injury or the most recent intervention. (In contrast, nonunion serial radiographs show no evidence of healing.)

Other Musculoskeletal and Neurologic Conditions
Other musculoskeletal conditions include medial tibial stress syndrome, osteonecrosis (avascular necrosis) of the femoral head, coccydynia, and painful stump neuromas. Neurologic conditions include spasticity, which refers to a motor disorder characterized by increased velocity-dependent stretch reflexes. It is a characteristic of upper motor neuron dysfunction, which may be due to a variety of pathologies.

Treatment
Most cases of plantar fasciitis are treated with conservative therapy, including rest or minimization of running and jumping, heel cups, and nonsteroidal-anti-inflammatory drugs. Local steroid injection may also be used. Improvement may take up to 1 year in some cases.

For tendinitis and tendinopathy syndromes, conservative treatment often involves rest, activity modifications, physical therapy, and anti-inflammatory medications (see Table 1).

Extracorporeal Shock Wave Therapy
Also known as orthotripsy, extracorporeal shock wave therapy (ESWT) has been available since the early 1980s for the treatment of renal stones and has been widely investigated for the treatment of biliary stones. ESWT uses externally applied shock waves to create a transient pressure disturbance, which disrupts solid structures, breaking them into smaller fragments, thus allowing spontaneous passage and/or removal of stones. The mechanism by which ESWT might have an effect on musculoskeletal conditions is not well-defined.

Other mechanisms are also thought to be involved in ESWT. Physical stimuli are known to activate endogenous pain control systems, and activation by shock waves may “reset” the endogenous pain receptors. Damage to endothelial tissue from ESWT may result in increased vessel wall permeability, causing increased diffusion of cytokines, which may, in turn, promote healing. Microtrauma induced by ESWT may promote angiogenesis and thus aid healing. Finally, shock waves have been shown to stimulate osteogenesis and promote callous formation in animals, which is the basis for trials of ESWT in delayed union or nonunion of bone fractures.

There are 2 types of ESWT: focused and radial. Focused ESWT sends medium- to high-energy shockwaves of single pressure pulses lasting microseconds, directed on a specific target using ultrasound or radiographic guidance. Radial ESWT (RSW) transmits low- to medium-energy shockwaves radially over a larger surface area. The Food and Drug Administration (FDA) approval was first granted in 2002 for focused ESWT devices and in 2007 for RSW devices.

REGULATORY STATUS
Currently, five ESWT devices for orthopedic use are approved for marketing by FDA and are summarized in Table 2. FDA product code: NBN.

Table 2: FDA-Approved Extracorporeal Shock Wave Therapy Devices  

Device Name

Approval Date

Delivery System Type

Indication

OssaTron® device (HealthTronics)

2000

Electrohydraulic delivery system

  • Chronic proximal plantar fasciitis, i.e., pain persisting > 6 mo and unresponsive to conservative management
  • Lateral epicondylitis

Epos™ Ultra (Dornier)

2002

Electromagnetic delivery system

Plantar fasciitis

Sonocur® Basic (Siemens)

2002

Electromagnetic delivery system

Chronic lateral epicondylitis (unresponsive to conservative therapy for > 6 mo)

Orthospec™ Orthopedic ESWT (Medispec)

2005

Electrohydraulic spark-gap system

Chronic proximal plantar fasciitis in patients ≥ 18 y

Orbasone™ Pain Relief System (Orthometrix)

2005

High-energy sonic wave system

Chronic proximal plantar fasciitis in patients ≥ 18 y

Duolith® SD1 Shock Wave Therapy Device (Storz Medical AG)

2016

Electromagnetic delivery system

Chronic proximal plantar fasciitis in patients ≥ 18 y with history of failed alternative conservative therapies > 6 mo

FDA: Food and Drug Administration.

Both high-dose and low-dose protocols have been investigated. A high-dose protocol consists of a single treatment of high-energy shock waves (1300 mJ/mm2). This painful procedure requires anesthesia. A low-dose protocol consists of multiple treatments, spaced 1 week to 1 month apart, in which lower dose shock waves are applied. This protocol does not require anesthesia. The FDA-labeled indication for the OssaTron® and Epos™ Ultra devices specifically describes a high-dose protocol, while the labeled indication for the Sonocur® device describes a low-dose protocol.

In 2007, Dolorclast® (EMS Electro Medical Systems), a radial ESWT, was approved by FDA through the premarket approval process. Radial ESWT is generated ballistically by accelerating a bullet to hit an applicator, which transforms the kinetic energy into radially expanding shock waves. Radial ESWT is described as an alternative to focused ESWT and is said to address larger treatment areas, thus providing potential advantages in superficial applications like tendinopathies. The FDA-approved indication is for the treatment of patients 18 years and older with chronic proximal plantar fasciitis and a history of unsuccessful conservative therapy. FDA product code: NBN.

Policy
Extracorporeal shock wave therapy (ESWT), using either a high- or low-dose protocol, is investigational and/or unproven and therefore considered NOT MEDICALLY NECESSARY as a treatment of musculoskeletal conditions, including but not limited to plantar fasciitis; tendinopathies including tendinitis of the shoulder, tendinitis of the elbow (epicondylitis, tennis elbow), stress fractures, delayed union and non-union of fractures, and avascular necrosis of the femoral head.

Policy Guidelines
Coding
Please see the Codes table for details.    

Benefit Application
Extracorporeal shock wave treatment for plantar fasciitis may be performed by podiatrists, orthopedic surgeons, and primary care physicians.

State or federal mandates (e.g., FEP) may dictate that all FDA-approved devices may not be considered investigational and thus these devices may be assessed only on the basis of their medical necessity.  

Rationale 
This evidence review was created in May 2001 and has been updated regularly with searches using the PubMed database. The most recent literature update was performed through May 2, 2022.

The most clinically relevant outcome measures of extracorporeal shock wave treatment (ESWT) used for musculoskeletal conditions are pain and functional limitations. Pain is a subjective, patient-reported measure. Therefore, pain outcomes require quantifiable pre- and posttreatment measures. Pain is most commonly measured with a visual analog scale (VAS). Quantifiable pre- and posttreatment measures of functional status are also used, such as the 12-Item Short-Form Health Survey and 36-Item Short-Form Health Survey. Minor adverse events of ESWT are common but transient, including local pain, discomfort, trauma, bleeding, and swelling. More serious adverse events of ESWT may potentially include neurologic damage causing numbness or tingling, permanent vascular damage, or rupture of a tendon or other soft tissue structure.

Evidence reviews assess the clinical evidence to determine whether the use of a technology improves the net health outcome. Broadly defined, health outcomes are length of life, quality of life, and ability to function including benefits and harms. Every clinical condition has specific outcomes that are important to patients and to managing the course of that condition. Validated outcome measures are necessary to ascertain whether a condition improves or worsens; and whether the magnitude of that change is clinically significant. The net health outcome is a balance of benefits and harms.

To assess whether the evidence is sufficient to draw conclusions about the net health outcome of a technology, 2 domains are examined: the relevance and the quality and credibility. To be relevant, studies must represent 1 or more intended clinical use of the technology in the intended population and compare an effective and appropriate alternative at a comparable intensity. For some conditions, the alternative will be supportive care or surveillance. The quality and credibility of the evidence depend on study design and conduct, minimizing bias and confounding that can generate incorrect findings. The randomized controlled trial (RCT) is preferred to assess efficacy; however, in some circumstances, nonrandomized studies may be adequate. Randomized controlled trials are rarely large enough or long enough to capture less common adverse events and long-term effects. Other types of studies can be used for these purposes and to assess generalizability to broader clinical populations and settings of clinical practice.

Musculoskeletal and Neurologic Conditions
Plantar Fasciitis
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conservative therapy (e.g., stretching, heel supports), nonsteroidal anti-inflammatory therapy, and local corticosteroid injection, in patients with plantar fasciitis.

The question addressed in this evidence review is: Does the use of ESWT for plantar fasciitis improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with plantar fasciitis.

Interventions
The therapy being considered is ESWT.

ESWT is a noninvasive method used to treat pain with shock or sound waves directed from outside the body onto the area to be treated (e.g., the heel). Shock waves are generated at high- or low-energy intensity, may be radial or focused, and treatment protocols can include more than 1 treatment. ESWT has been investigated for use in a variety of musculoskeletal conditions.

Comparators
Comparators of interest include conservative therapy (e.g., stretching, heel supports), nonsteroidal anti-inflammatory therapy, and local corticosteroid injection.

Outcomes
The general outcomes of interest are pain symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 3. Outcomes of Interest for Individuals With Plantar Fasciitis

Outcomes Details Timing
Pain reduction
  • VAS assessment, with successful pain reduction of 50% to 60% or ≥ 4 cm reduction in score
  • Roles and Maudsley pain scores of "good" or "excellent"
  • Pain comparison both to baseline and to control group measurements
  • Patient-assessed and investigator-assessed pain levels
Generally measured for up to 12 weeks
Functional improvement
  • Roles and Maudsley function score of "good" or "excellent"
  • Patient ability to work and perform activities of daily living
Generally measured for up to 12 weeks
Quality of life
  • Patient-reported satisfaction with treatment
Generally measured for up to 12 weeks

VAS: visual analog scale.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

Meta-analyses of RCTs published in 2013 have reported that ESWT for plantar fasciitis is better than or comparable to placebo in reducing pain1,2,3 and improving functional status in the short-term.1,2 However, the RCTs were subject to a number of limitations. They reported inconsistent results, and heterogeneity across them sometimes precluded meta-analysis of pooled data. Outcomes measured and trial protocols (e.g., dose intensities, type of shockwaves, the frequency of treatments) also lacked uniformity. Also, given that plantar fasciitis often resolves within a 6-month period, longer follow-up would be required to compare ESWT results with the natural resolution of the condition. The clinical significance of results reported at shorter follow-up (e.g., 3 months) is uncertain.

A systematic review and meta-analysis by Yin et al. (2014) evaluated 7 RCTs or quasi-RCTs of ESWT for chronic (≥6 months) recalcitrant plantar fasciitis.4 The treatment success rate of the 5 trials (n = 448 patients) that evaluated low-intensity ESWT showed it was more likely than the control to be successful (pooled relative risk, 1.69; 95% confidence interval [CI], 1.37 to 2.07; p < .001). In a pooled analysis of 2 trials (n = 105 subjects) that evaluated high-intensity ESWT, there was no difference between ESWT and control in treatment success. A strength of this analysis was restricting the population to patients with at least 6 months of symptoms because this clinical population is more difficult to treat and less likely to respond to interventions. However, a weakness was the heterogeneity in the definition of "treatment success" across trials, which makes interpreting the pooled analysis challenging.

A meta-analysis by Lou et al. (2017) evaluated the efficacy of ESWT without local anesthesia in patients with recalcitrant plantar fasciitis.The literature search, conducted through September 2015, identified 9 trials for inclusion (N = 1,174 patients). Meta-analyses focused on pain reduction at 12 weeks of follow-up: overall, at first step in the morning, and during daily activities. Three RCTs also provided data to analyze improvement in the Roles and Maudsley score to excellent or good at 12-week follow-up.

A meta-analysis by Sun et al. (2017) evaluated the efficacy of all ESWT, then conducted subgroup analyses on the type of ESWT (focused shock wave [FSW], radial shock wave [RSW]).6 The literature search, conducted through July 2016, identified 9 trials for inclusion (N = 935 patients). An outcome in all 9 trials was "therapeutic success" rate, defined as the proportion of patients experiencing a decrease in VAS pain score from baseline more than a threshold of either at least 50% or at least 60%. Only 4 studies provided data on reducing pain (3 FSW, 1 RSW). Pooled results are summarized in Table 6.

In a systematic review and meta-analysis, Li et al. (2018) assessed RCTs to determine whether ESWT or corticosteroid injections are more effective in plantar fasciitis pain reduction (measured using VAS), treatment success, recurrence rate, function scores, and adverse events.7 The review included 9 RCTs with a total of 658 cases in which 330 participants received ESWT and 328 received corticosteroid injection. Meta-analyses showed that corticosteroid injection is more effective than low-intensity ESWT at VAS reduction (3 months post-treatment: mean difference, -1.67; 95% CI, -3.31 to -0.04; p = .04; I2 = 85%). However, high-intensity ESWT is more effective than corticosteroid injection (2 to 3 months post-treatment: mean difference, 1.12; 95% CI, 0.52 to 1.72; p = .0003; I2 = 59%). One study followed patients for 12 months post-treatment and found no significant difference in pain outcomes, and another found no significant difference in recurrence rates or functional scores between ESWT and corticosteroid injection. Four ESWT recipients in a single trial reported severe headache or migraine following the procedure; no severe adverse effects were reported for corticosteroid injection. Though corticosteroid injection is more readily available than ESWT, the authors reported that ESWT recipients had a faster return to full activities after the procedure. One limitation of this systematic review is the inclusion of only 9 trials with 658 cases, only 2 of which were followed up for as long as 1 year. Also, the doses of corticosteroid injection varied across studies, which may affect heterogeneity. This study is not included in the results summary table (Table 6) because its comparator is a corticosteroid injection rather than placebo.

A meta-analysis by Xiong et al. (2019) compared the efficacy of shock wave therapy with corticosteroid injections for managing plantar fasciitis in terms of pain and functionality.8 The analysis included 6 RCTs with 454 patients and revealed a significant difference in VAS score (mean difference, -0.96; 95% CI, -1.28 to -0.63; p < .00001, I2 = 96%), favoring shock wave therapy. This analysis is also not included in the results summary table (Table 6) because its comparator is a corticosteroid injection rather than placebo.

Results of the meta-analyses must be interpreted with caution due to the following limitations: lack of uniform measurement of outcomes, heterogeneity in ESWT protocols (focused and radial, low- and high-intensity/energy, the number of shocks per treatment, treatment duration, and differing comparators), and lack of functional outcomes.

Table 4. Comparison of Systematic Reviews Assessing ESWT for Plantar Fasciitis

Study Aqil (2013)2 Dizon (2013)1 Zhiyun (2013)3 Yin (2014)4 Lou (2017)5 Sun (2017)6 Li (2018)17 Xiong (2019)8
Buchbinder (2002)              
Chow (2005)              
Eslamian (2016)              
Fariba (2016)              
Gerdesmeyer (2008)      
Gollwitzer (2007)    
Gollwitzer (2015)              
Gollwitzer (2017)              
Greve (2009)            
Guevara (2018)              
Haake (2003)            
Hocaoglu (2017)              
Ibrahim (2010)        
Istemi (2010)              
Kudo (2006)            
Lai (2018)            
Malay (2006)      
Mardani-Kivi (2015)              
Mark (2005)              
Marks (2008)          
Nayera (2012)              
Ogden (2004)              
Porter (2005)              
Radwan (2012)              
Rompe (1996)              
Rompe (2002)              
Rompe (2003)            
Saber (2012)              
Sehriban (2017)              
Sorrentino (2008)              
Speed (2003)      
Theodore (2004)            
Yucel (2010)            

ESWT: extracorporeal shockwave therapy.
1 Only 7 trials mentioned in meta-analysis.

Table 5. Characteristics of Systematic Reviews and Meta-Analyses Assessing ESWT for Plantar Fasciitis

Study Dates Trials Participants N (Range) Design Duration
Aqil (2013)2 2003 – 2010 7 PF patients with continued symptoms after 3 months of consecutive therapy 663 (25 to 243) RCTs 12 weeks
Dizon (2013)1 2002 – 2010 11 Patients with chronic PF 1287 (32 to 272) RCTs Immediately after treatment to 1 year
Zhiyun (2013)3 2004 – 2007 5 Adults with recalcitrant PF; baseline pain ≥5 points on VAS 716 (40 to 293) RCTs
(double-blind)
12 weeks
Yin (2014)4 2003 – 2012 7 Adults with PF ≥6 months; single-site heel pain with local pressure at origin of proximal plantar fascia on the medial calcaneal tuberosity 550 (25 to 243) RCTs 3 to 12 months
Lou (2017)5 2001 –  2015 91 Patients with recalcitrant PF 1174 (NA) RCTs Primary outcomes=12 weeks; studies up to >12 months
Sun (2017)6 1996 – 2015 9 Patients with chronic PF 935 (29 to 246) RCTs 3 weeks to 6 months
Li (2018)7 2005 – 2018 9 Adults with PF and without injection history 658 (40 to 125) RCTs 6 weeks to 1 year
Xiong (2019)8 2005 – 2018 6 Patients with PF 454 (40 to 125) RCTs -

ESWT: extracorporeal shockwave therapy; NA: not available; PF: plantar fasciitis; RCT: randomized controlled trial; VAS: visual analog scale.

Table 6. Results of Systematic Reviews and Meta-Analyses Assessing ESWT for Plantar Fasciitis Compared with Placebo

Study 60% VAS Score Reduction From Baseline (or > 50% reduction and VAS score ≤ 4 cm) Roles & Maudsley Score
  First Steps Overall Heel Pain Daily Activities Composite  
Aqil (2013)2
RR 1.30 - 1.44 - -1
SMD - 0.60   0.38 -
95% CI 1.04 to 1.62 0.34 to 0.85 1.13 to 1.84 0.05 to 0.72 -
Z score 2.29 4.64 2.96 2.27 -
P-value < .02 < .001 .003 .02 -
Dizon (2013)1
WMD -0.77 -4.39 0.59 - -
OR         0.57
95% CI -1.30 to -0.25 -9.05 to 0.27 0.33 to 1.05 - 0.43 to 0.76
P-value .004 .06 .07 - .0001
Zhiyun (2013)33
Success rate % (12 weeks) - 46.5 to 62.5 - - -
OR - 2.25 - - -
95% CI - 1.66 to 3.06 - - -
Z score - 5.19 - - -
P-value - < .0001 - - -
Yin (2014)4
L-ESWT          
MD - 1.512 -    
RR -   - - 1.41
95% CI - 0.77 to 2.26 - - 1.08 to 1.82
P-value - < .001 - - .01
H-ESWT          
MD - 1.4 - -  
RR -   - - 1.33
95% CI - 0.57 to 2.23 - - 0.94 to 1.9
P-value - .11 - - .11
Lou (2017)5
RR 1.32 1.50 1.37 - 1.51
95% CI 1.11 to 1.56 1.27 to 1.77 1.14 to 1.65 - 1.26 to 1.81
Z score 3.19 4.84 3.31 - 4.51
P-value .001 < .0001 .0009 - < .0001
I2 % 0 0 -   0
Sun (2017)6
OR - - - 2.58 -
SMD - 1.01 - - -
95% CI - -0.01 to 2.03 - 1.97 to 3.39 -
Z score - 1.94 - 6.88 -
P-value - .05 - < .0001 -
I2 % - 96 - 38 -

CI: confidence interval; ESWT: extracorporeal shockwave therapy; FSW: focused shockwave; H-ESWT: high-intensity/energy shockwave therapy; L-ESWT: low-intensity/energy shockwave therapy; MD: mean difference; OR: odds ratio; RR: risk ratio; RSW: radial shockwave; SMD: standard mean difference; VAS: visual analog scale ; WMD: weighted mean difference.
Li (2018) and Xiong (2019) are not included in the results summary table because the comparator in the studies is corticosteroid injections rather than placebo.
1 Aqil et al. gathered data on 3 studies that measured Roles and Maudsley scores but did not statistically combine the results. However, all 3 studies showed statistically significant improvements for the ESWT group at 12 weeks.
2 Yin et al. compared ESWT value for pain relief before and after treatment.
3 Zhivun compared H-ESWT to placebo.

Randomized Controlled Trials
Trials With Sham Controls

Several representative RCTs are discussed next. Gollwitzer et al. (2015) reported on results of a sham-controlled randomized trial, with patients and outcome assessments blinded, evaluating ESWT for plantar fasciitis present for at least 6 months and refractory to at least 2 nonpharmacologic and 2 pharmacologic treatments.9 A total of 250 subjects were enrolled (126 in the ESWT group, 124 in the placebo group). The trial's primary outcome was an overall reduction of heel pain, measured by percentage change of the VAS composite score at 12 weeks. Median decrease for the ESWT group was -69.2% and -34.5% for the placebo group (effect size, 0.603; p = .003). Secondary outcomes included success rates defined as decreases in heel pain of at least 60% from baseline. Secondary outcomes generally favored the ESWT group. Most patients reported satisfaction with the procedure. Strengths of this trial included an intention-to-treat analysis, use of validated outcome measures, and at least some reporting of changes in success rates (rather than percentage decrease in pain) for groups. There was some potential for bias because treating physicians were unblinded.

Gerdesmeyer et al. (2008) reported on a multicenter, double-blind RCT of RSW conducted for U.S. Food and Drug Administration (FDA) premarket approval of the Dolorclast.10 The trial randomized 252 patients, 129 to RSW and 122 to sham treatment. Patients had heel pain for at least 6 months and had failed at least 2 nonpharmacologic and 2 pharmacologic treatments. Over 90% of patients were compliant with the 3 weekly treatment schedule. Outcome measures were composite heel pain (pain on first steps of the day, with activity and as measured with Dolormeter), change in VAS pain score, and Roles and Maudsley score measured at 12 weeks and 12 months. Success was defined as a reduction of 60% or more in 2 of 3 VAS scores, or patient ability to work and complete activities of daily living, treatment satisfaction, and requiring no further treatment. Secondary outcomes at 12 weeks included changes in Roles and Maudsley score, 36-Item Short-From Health Survey Physical Component Summary score, 36-Item Short-Form Health Survey Mental Component Summary score, investigator's and patient's judgment of effectiveness, and patient recommendation of therapy to a friend. At 12-week follow-up, RSW resulted in a decrease of the composite VAS score by 72.1% versus 44.7% after placebo (p = .022). Success rates for the composite heel pain score were 61% and 42% (p = .002). Statistically significant differences were noted in all secondary measures. A number of limitations prevent definite conclusions from being reached including: the limited data on specific outcomes (e.g., presenting percent changes rather than actual results of measures); inadequate description of prior treatments; use of a composite outcome measure; no data on the use of rescue medication; and uncertainty in the clinical significance of changes in outcome measures.

In 2005, results were reported from the FDA regulated trials delivering ESWT with the Orthospec and Orbasone Pain Relief System. In the RCT evaluating Orthospec, investigators conducted a multicenter, double-blind, sham-controlled trial randomizing 172 participants with chronic proximal plantar fasciitis failing conservative therapy to ESWT or to sham treatments.11 At 3 months, the ESWT arm had lower investigator-assessed pain levels with the application of a pressure sensor (0.94 points lower on a 10-point VAS; 95% CI, 0.02 to 1.87). However, this improvement was not found for patient-assessed activity and function. In the trial supporting the FDA approval of Orbasone, investigators conducted a multicenter, randomized, sham-controlled, double-blind trial evaluating 179 participants with chronic proximal plantar fasciitis.12 At 3 months, both active and sham groups improved in patient-assessed pain levels on awakening (by 4.6 and 2.3 points, respectively, on a 10-point VAS; absolute difference between groups, 2.3; 95% CI, 1.5 to 3.3). While ESWT was associated with more rapid and statistically significant improvement in a mixed-effects regression model, insufficient details were provided to evaluate the analyses.

Table 7. Summary of Key Characteristics of RCTs Assessing ESWT for Plantar Fasciitis

Study; Trial Countries Sites Participants Interventions
        Active Comparator
Gollwitzer (2015)9 U.S. 5 Patients with ≥ 6 months PF; failed ≥ 4 non-surgical treatments, including ≥ 2 non-pharmacological and ≥ 2 pharmacological treatments; (n = 250) 2000 impulses; maximum 0.25 mJ/mm2 (4 impulses per second); up to 3 weekly sessions; (n = 126) Identical placebo handpiece for sham intervention; air-filled standoff prevented transmission of shockwaves; (n = 124)
Gerdesmeyer (2008)10 U.S., EU 8 Patients with ≥ 6 months painful heel syndrome resistant to nonsurgical treatment; score ≥ 5 on 3 VAS scores; failed ≥ 2 non-pharmacological and 2 pharmacological treatments; sufficient washout period; (n = 254) 2000 impulses radial shockwaves; energy flux density 0.16 mJ/mm2 (8 impulses per second); 3 bi-weekly sessions; (n = 129) Identical placebo handpiece; same schedule as active group but with no energy administered; (n = 122)
FDA, Orbasone (2005)12 U.S. 3 Patients ≥ 21 years; proximal PF ≥ 6 months and in prescribed stretching program; failed ≥ 4 conventional treatments; score ≥ 6 cm on VAS scale; (n = 179) Single treatment of 2000 pulses at 20 to 21 KV; frequency 110 pulses per minute; total energy density < 1000 mJ/mm2; injection of approx. 10 mL of 0.5% bupivacaine; (n = 96) Sham treatment with no water pumped into reflector head, preventing shockwave energy from reaching patient's foot; (n = 83)
FDA, Orthospec (2005)11 U.S. 3 Adults (non-pregnant) with proximal PF for >6 months; under treatment ≥ 4 months; VAS score upon first steps ≥ 5 cm; failed 2 pharmacological and 2 nonpharmacological treatments; washout period; (n = 172) Total of 3,800 shocks; (n = 115) Total of 3,800 shocks; contact membrane of device lined with internal foam insert to absorb shockwaves; (n = 57)

ESWT: extracorporeal shockwave therapy; EU: European Union; FDA: U.S. Food and Drug Administration; PF: plantar fasciitis; RCT: randomized controlled trial; VAS: visual analog scale;.

Table 8. Summary of Key Results of RCTs Assessing ESWT for Plantar Fasciitis

Study VAS Pain Score Improvement Functional Improvement
Gollwitzer (2015)9
P-value (MW effect size)3 .0027 (0.6026) .0006 (0.6135)
Lower-bound 95% CI 0.5306 0.5466
ESWT mean % from baseline (95% CI) -54.5 (-61.4 to -47.7) -
Placebo mean % from baseline (95% CI) -40.3 (-47.5 to -33.1) -
ESWT mean score (95% CI)4 - 2.5 (2.3 to 2.7)
Placebo mean score (95% CI) - 2.9 (2.7 to 3.1)
Gerdesmeyer (2008)10,
ESWT reduction in VAS composite % 72.1 -
Placebo reduction in VAS composite % 44.7 -
P-value .0220 -
ESWT success rate %1 60.98 58.402
Placebo success rate % 42.24 41.52
P-value (MW effect size) .0020 (-) .0031 (0.5973)
FDA, Orbasone (2005)12
ESWT 12-wk mean score (SE) 3.11 (0.30) -
Range 0 to 9.8 -
Placebo 12-wk mean score (SE) 5.51 (0.35) -
Range 0 to 10 -
P-value .0002 -
% ESWT with 40% reduction in VAS 70.8 -
% Placebo with 40% reduction in VAS 36.6 -
FDA, Orthospec (2005)11
ESWT mean change from baseline6 -2.51 -
Placebo mean change from baseline -1.57 -
Difference -0.94 -
95% CI -1.87 to -0.02 -
P-value .045 -
ESWT effectiveness rate %7 - 64.3
Placebo effectiveness rate % - 57.1
P-value - .33

CI: confidence interval; ESWT: extracorporeal shockwave therapy; FDA: US Food and Drug Administration; MW: Mann-Whitney; RCT: randomized controlled trial; SD: standard deviation; SE: standard error; VAS: visual analog scale; wk: week.
1 Based on overall VAS score.
2 Roles and Maudsley Score of "excellent" or "good."
3 Based on composite VAS score.
4 Roles and Maudsley Score.
5 Based on pain at first steps VAS score.
6 Physician's assessment of pain at first steps VAS score.
7 Patient's assessment.

Tables 9 and 10 display notable limitations identified in each study.

Table 9. Study Relevance Limitations of RCTs Assessing ESWT for Plantar Fasciitis

Study Populationa Interventionb Comparatorc Outcomesd Follow-Upe
Gollwitzer (2015)9          
Gerdesmeyer (2008)10          
FDA, Orbasone (2005)12 3. Allocation concealment unclear        
FDA, Orthospec (2005)11 3. Allocation concealment unclear 1. Few details provided  

     
ESWT: extracorporeal shockwave therapy; FDA: US Food and Drug Administration; RCT: randomized controlled trial.
The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Population key: 1. Intended use population unclear; 2. Clinical context is unclear; 3. Study population is unclear; 4. Study population not representative of intended use.
b Intervention key: 1. Not clearly defined; 2. Version used unclear; 3. Delivery not similar intensity as comparator; 4. Not the intervention of interest.
c Comparator key: 1. Not clearly defined; 2. Not standard or optimal; 3. Delivery not similar intensity as intervention; 4. Not delivered effectively.
d Outcomes key: 1. Key health outcomes not addressed; 2. Physiologic measures, not validated surrogates; 3. No CONSORT reporting of harms; 4. Not establish and validated measurements; 5. Clinical significant difference not prespecified; 6. Clinical significant difference not supported.
e Follow-Up key: 1. Not sufficient duration for benefit; 2. Not sufficient duration for harms.

Table 10. Study Design and Conduct Limitations of RCTs Assessing ESWT for Plantar Fasciitis

Study Allocationa Blindingb Selective Reportingc Data Completenessd Powere Statisticalf
Gollwitzer (2015)9            
Gerdesmeyer (2008)10           3. Confidence intervals not reported
FDA, Orbasone (2005)12 1. Allocation concealment unclear   1. Registration unclear   1. Power calculations not reported 3. Confidence intervals and p-values not reported
FDA, Orthospec (2005)11 1. Allocation concealment unclear   1. Registration unclear   1. Power calculations not reported 3. Confidence intervals not reported for function


ESWT: extracorporeal shockwave therapy; FDA: US Food and Drug Administration; RCT: randomized controlled trial.
The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Allocation key: 1. Participants not randomly allocated; 2. Allocation not concealed; 3. Allocation concealment unclear; 4. Inadequate control for selection bias.
b Blinding key: 1. Not blinded to treatment assignment; 2. Not blinded outcome assessment; 3. Outcome assessed by treating physician.
c Selective Reporting key: 1. Not registered; 2. Evidence of selective reporting; 3. Evidence of selective publication.
d Data Completeness key: 1. High loss to follow-up or missing data; 2. Inadequate handling of missing data; 3. High number of crossovers; 4. Inadequate handling of crossovers; 5. Inappropriate exclusions; 6. Not intent to treat analysis (per protocol for noninferiority trials).
e Power key: 1. Power calculations not reported; 2. Power not calculated for primary outcome; 3. Power not based on clinically important difference.
f Statistical key: 1. Intervention is not appropriate for outcome type: (a) continuous; (b) binary; (c) time to event; 2. Intervention is not appropriate for multiple observations per patient; 3. Confidence intervals and/or p values not reported; 4.Comparative treatment effects not calculated.

Trials With Active Comparators
Radwan et al. (2012) compared ESWT with endoscopic plantar fasciotomy in 65 patients who had refractory plantar fasciitis and had failed at least 3 lines of treatment in the preceding 6 months.13, Outcome measures included a 0-to-100 VAS assessing morning pain, the American Orthopaedic Foot and Ankle Society (AOFAS) Ankle-Hindfoot Scale score, and patient subjective assessment using the 4-item Roles and Maudsley score. Improvements were similar in both treatment groups at the 1-year follow-up; however, a larger proportion of patients in the surgery group continued to report success at years 2 and 3 compared with those of the ESWT group.

Randomized controlled trials comparing ESWT and RSW with corticosteroid injection and conservative treatment (exercise, orthotic support) have been performed, with mixed findings.14,15,16, As the follow-up period for these studies are 3 months or less, the clinical significance of these results are uncertain.17

In a double-blind RCT, Bahar-Ozdemier et al. (2021) evaluated the effects of ESWT alone (n = 15), ESWT plus low-dye kinesiotaping (n = 15), and ESWT plus sham kinesiotaping (n = 15) in 45 patients with plantar fasciitis.18 Main outcome measures included VAS change, the heel tenderness index, and foot function index. Low-dye kinesiotaping plus ESWT was more effective on foot function improvement than ESWT and sham kinesiotaping or ESWT alone in the 4 week duration of follow-u. However, the combination did not provide a significant benefit on pain and heel tenderness due to plantar fasciitis.

Section Summary: Plantar Fasciitis
Numerous RCTs were identified, including several well-designed double-blind RCTs, that evaluated ESWT for the treatment of plantar fasciitis. Several systematic reviews and meta-analyses have been conducted, covering numerous studies, including studies that compared ESWT with corticosteroid injections. Pooled results were inconsistent. Some meta-analyses reported that ESWT reduced pain, while others reported nonsignificant pain reduction. Reasons for the differing results included lack of uniformity in the definitions of outcomes and heterogeneity in ESWT protocols (focused versus radial, low- versus high-intensity/energy, number and duration of shocks per treatment, number of treatments, and differing comparators). Some studies reported significant benefits in pain and functional improvement at 3 months, but it is not evident that the longer-term disease natural history is altered with ESWT. Currently, it is not possible to conclude definitively that ESWT improves outcomes for patients with plantar fasciitis.

Lateral Epicondylitis
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conservative therapy (e.g., physical therapy) and nonsteroidal anti-inflammatory therapy, in patients with lateral epicondylitis.

The question addressed in this evidence review is: does the use of ESWT for lateral epicondylitis improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with lateral epicondylitis.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest include conservative therapy (eg, physical therapy) and nonsteroidal anti-inflammatory therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 11. Outcomes of Interest for Individuals with Lateral Epicondylitis

Outcomes Details Timing
Symptoms
  • Pain improvement via VAS assessment
  • Thomsen Provocation Test score for pain
  • Roles and Maudsley pain scores of "good or excellent"
Generally measured for up to 12 weeks
Functional outcomes
  • Change in Upper Extremity Function Scale (UEFS)
  • Roles and Maudsley function scores of "good" or "excellent"
  • Grip strength improvement
Generally measured for up to 12 weeks
Medication use
  • Nonuse of pain medication
Generally measured for up to 12 weeks

VAS: visual analog scale.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

A Cochrane review by Buchbinder et al. (2005) concluded, "there is ‘Platinum' level evidence [the strongest level of evidence] that shock wave therapy provides little or no benefit regarding pain and function in lateral elbow pain."19 A systematic review by Dingemanse et al. (2014), which evaluated electrophysical therapies for epicondylitis, found conflicting evidence on the short-term benefits of ESWT.20 No evidence demonstrated any long-term benefits with ESWT over placebo for epicondylitis treatment. A meta-analysis by Zheng et al. (2020) of 9 studies concluded that ESWT does not reduce the mean overall pain compared with placebo in lateral epicondylitis of the humerus.21 A systematic review and meta-analysis by Yoon et al. (2020) of 12 studies revealed that ESWT lacks clinically important pain reduction or improvement in grip strength compared with sham stimulation or no additional treatment in patients with lateral epicondylitis.22 A meta-analysis by Karanasios et al. (2021) of 27 randomized trials (N = 1,871) found that ESWT (alone or as an additive intervention) compared with sham or other control treatment in patients with lateral elbow tendinopathy did not provide clinically meaningful improvement in pain intensity, elbow disability, or grip strength.23

Interestingly, some systematic reviews revealed a potential benefit of ESWT in patients with lateral epicondylitis when comparing with other treatment methods outside conservative and nonsteroidal anti-inflammatory therapy. A systematic review and meta-analysis by Yao et al. (2020) of 13 studies revealed improved VAS scores (p = .0004) and grip strength (p < .00001) with ESWT compared with other methods including placebo, autologous blood injection, corticosteroid injection, physiotherapy, wrist-extensor splints, laser, and/or kinesiotaping.24 A meta-analysis by Yan et al. (2019) of 5 studies demonstrated improvement in VAS scores (p < .0001), grip strength (p < .00001), and subjective scores of elbow function (p = .0008) with ESWT compared with ultrasonics.25 A meta-analysis by Xiong et al. (2019) of 4 studies revealed improved VAS scores (p < .00001) and grip strength (p < .00001) with shock wave therapy compared with corticosteroid injections.26

Randomized Controlled Trials
Aldajah et al. (2022) compared ESWT (n = 20) with conventional physiotherapy (n = 20) in patients with lateral epicondylitis.27 All patients received 5 sessions during the treatment program. Outcome measures included changes in VAS for pain intensity, the Disabilities of the Arm, Shoulder, and Hand (DASH) questionnaire for upper extremity function, and dynamometer for maximal grip strength. Patients in both groups improved significantly after treatment in terms of VAS, DASH scores, and maximal grip strength from baseline. However, patients in the ESWT arm performed better than those in the physiotherapy arm for all outcomes. This RCT is not included in the summary table because it compares ESWT with a physiotherapy program that includes ultrasound therapy.

Guler et al. (2020) compared ESWT (n = 20) with kinesiotaping (n = 20) as part of a 3-week treatment in patients with newly diagnosed lateral epicondylitis.28 Outcomes included VAS pain, grip strength, and functional assessment as measured by Roles and Maudsley score. At 8 week follow-up, kinesiotaping revealed a lower VAS score (2.52 vs. 4.0; p = .01), a better hand grip strength score (26.8 vs. 20.6; p = .005), and a lower Roles and Maudsley score (1.7 vs. 2.2; p = .02) compared with ESWT. This RCT is not included in the summary table because it compares ESWT to kinesiotaping as opposed to conservative or nonsteroidal anti-inflammatory therapy.

Yang et al. (2017) published results from an RCT (N=30) comparing RSW plus physical therapy with physical therapy alone in patients with lateral epicondylitis.29 Outcomes included VAS pain and grip strength. Significant differences were seen in grip strength by 12 weeks of follow-up; the mean difference in grip strength between groups was 7.7 (95% CI, 1.3 to 14.2), favoring RSW. Significant differences in VAS pain (10-point scale) were not detected until 24 weeks of follow-up; the mean difference between groups was -1.8 (95% CI, -3.0 to -0.5), favoring RSW. This RCT is not included in the summary table because it compares RSW with a physical therapy program that includes ultrasound therapy.

A small RCT by Capan et al. (2016) comparing RSW (n = 28) with sham RSW (n = 28) for lateral epicondylitis did not find significant differences between groups in grip strength or function.30 However, this trial might have been underpowered to detect a difference.

Lizis (2015) compared ESWT with therapeutic ultrasound among 50 patients who had chronic tennis elbow.31 For most pain measures assessed, the pain was lower in the ESWT group immediately posttreatment and at 3 months, except pain on gripping, which was higher in the ESWT group. While trial results favored ESWT, it had a high risk of bias, in particular, due to lack of blinding of participants and outcome assessors, which make interpretation of results difficult. This RCT is not included in the summary tables because the comparator is ultrasound as opposed to conservative or nonsteroidal anti-inflammatory therapy.

Gunduz et al. (2012) compared ESWT with 2 active comparators.32 This trial randomized 59 patients with lateral epicondylitis to ESWT, physical therapy, or a single corticosteroid injection. Outcome measures were VAS pain, grip strength, and pinch strength by dynamometer. The authors reported that VAS pain scores improved significantly in all 3 groups at all 3 follow-up time points out to 6 months, but they reported no between-group differences. No consistent changes were reported for grip strength or on ultrasonography. This RCT is not included in the summary table because it compares ESWT with corticosteroid injections, and the physical therapy comparator includes ultrasound therapy.

Staples et al. (2008) reported on a double-blind controlled trial of ESWT for epicondylitis in 68 patients.33 Patients were randomized to 3 ESWT treatments or 3 treatments at a subtherapeutic dose at weekly intervals. There were significant improvements in most of the 7 outcome measures for both groups over 6 months of follow-up but no between-group differences. The authors found little evidence to support the use of ESWT for this indication.

Pettrone and McCall (2005) reported on results from a multicenter, double-blind, randomized trial of 114 patients receiving ESWT in a "focused" manner (2,000 impulses at 0.06 mJ/mm34 without local anesthesia) weekly for 3 weeks or placebo.35 Patients were followed for 12 weeks, and benefit demonstrated with the following outcomes: VAS pain (0 to 10 points) declined at 12 weeks in the treatment group from 7.4 to 3.8; among placebo patients, from 7.6 to 5.1. A reduction in pain on the Thomsen Provocation Test of at least 50% was demonstrated in 61% of those treated compared with 29% in the placebo group. Mean improvement on a 10-point Upper Extremity Function Scale (UEFS) activity score was 2.4 for ESWT-treated patients compared with 1.4 in the placebo group-a difference at 12 weeks of 0.9 (95% CI, 0.18 to 1.6). Although this trial found a benefit of ESWT for lateral epicondylitis over 12 weeks, the placebo group also improved significantly; whether the natural history of disease was altered with ESWT is unclear.

Table 12. Summary of Key Characteristics of RCTs Assessing ESWT for Lateral Epicondylitis

Study; Trial Countries Sites Dates Participants Interventions
          Active Comparator
Capan (2016)30 Turkey 1 - Patients with unilateral LE for > 3 months unresponsive to other treatments; (n = 56) rESWT with 2,000 pulses; 10 Hz frequency; 1.8 bar of air pressure; 3 weekly sessions; (n = 28) 3 sham treatments of rESWT; same dosage and schedule as active but with no contact between applicator head and skin; (n = 28)
Staples (2008)33 Australia 1 1998 – 2001 Adults with lateral elbow pain for ≥ 6 weeks; normal anteroposterior and lateral elbow radiographs; reproducibility of pain by ≥ 2 pain tests; (n = 68) ESWT with 2,000 pulses; energy level = maximum tolerated by patient; 240 pulses per minute; 3 weekly sessions; (n = 36) ESWT with 100 pulses; maximum energy ≤ 0.03 mJ/mm2; 90 pulses per minute; 3 weekly sessions; (n = 32)
Pettrone & McCall (2005)35 US 3 - Patients with LE ≥ 6 months; pain resistant ≥ 2 of 3 conventional therapies; pain ≥ 40 mm on VAS with resisted wrist extension; (n = 114) ESWT with 2,000 pulses; 0.06 mJ/mm2; 3 weekly sessions; (n = 56) 3 sham treatments of ESWT with same settings as active but with sound-reflecting pad between patient and machine application head; (n = 58)

ESWT: extracorporeal shockwave therapy; LE: lateral epicondylitis; RCT: randomized controlled trial; rEWST: radial extracorporeal shockwave therapy; VAS: visual analog scale.

Table 13. Summary of Key Results of RCTs Assessing ESWT for Lateral Epicondylitis

Study Pain Improvement Functional Improvement Grip Strength1
  ≤ 6 wks 3 mos ≤ 6 wks 3 mos ≤ 6 wks 3 mos
Capan (2016)30
rESWT (SD) 3.4 (2.9)2 2.1 (2.2)2 19.3 (10.9)3 14.7 (12.3)3 15.96 (9.61) 17.30 (10.33)
rESWT MD from baseline (SD) -1.9 (2.2)2 -3.2 (2.3)2 -10.9 (11.3)3 -15.4 (13.4)3 5.35 (6.82) 1.35 (3.87)
% difference -36.72 -59.12 -33.43 -49.23 76.3 17.8
P-value < .001 < .001 < .001 < .001 .002 .074
Control (SD) 3.5 (2.9)2 2.6 (2.8)2 21.9 (12.6)3 19.2 (13.6)3 10.14 (6.42) 12.18 (6.01)
Control MD from baseline (SD) -2.2 (2.4)2 -3.1 (2.7)2 -7.9 (10.1)3 -10.6 (11.6)3 3.68 (4.56) 2.05 (3.46)
% difference -39.62 -54.82 -28.93 -37.83 110.0 57.0
P-value .001 <.001 .001 .001 .001 .017
% difference between groups 0.758 0.882 0.617 0.323 0.578 0.768
Staples (2008)33
  - - - - - -
ESWT mean (SE) change 27.7 (5.7)4 26.1 (6.5)4 15.3 (2.4)7 18.9 (2.7)7 0.17 (0.06) 0.35 (0.06)
  - - -   - -
Control mean (SE) change 26.0 (6.4)4 26.7 (6.0)4 9.0 (3.8)7 10.9 (3.4)7 0.22 (0.07) 0.31 (0.06)
Between-group difference 1.74 -0.64 6.37 8.17 -0.05 0.04
95% CI -18.8 to 15.34 -18.4 to 17.34 -2.5 to 15.17 -0.5 to 16.77 -0.22 to 0.12 -0.13 to 0.20
P-value .84 .95 .16 .07 .57 -
Pettrone & McCall (2005)35
ESWT mean (SD) - 37.6 (28.7)4 - 2.3 (1.6)6 - 38.2
Change % - 494 - 516 - 23
Control mean (SD) - 51.3 (29.7)4 - 3.2 (2.1)6 - 37.4
Change % - 324 - 306 - 12
P-value - .02 - .01 - .09
ESWT % pts w/pain reduction - 615 - - - -
Placebo % pts w/pain reduction - 295 -   - -
P-value - .0001 - - -

CI: confidence interval; ESWT: extracorporeal shockwave therapy; MD: mean difference; pts: patients; RCT: randomized controlled trial; rESWT: radial extracorporeal shockwave therapy; SD: standard deviation; SE: standard error of the mean; VAS: visual analog scale.
1Grip strength in kilograms measured with a squeeze dynamometer.
 2 Pain assessed using at-rest VAS (range = 0 – 10).
 3 Patient-Related Tennis Elbow Evaluation (PRTEE) function scores.
4 VAS pain index (range = 0 – 100).
5Pain reduction of ≥ 50% on Thomsen test.
6Functional improvement assessed using Upper Extremity Functional Scale
7Disabilities of the Arm, Shoulder, and Hand (DASH) questionnaire function scores.

Tables 14 and 15 display notable limitations identified in each study.

Table 14. Study Relevance Limitations of RCTs Assessing ESWT for Lateral Epicondylitis

Study Populationa Interventionb Comparatorc Outcomesd Follow-Upe
Capan (2016)30       3. CONSORT flow diagram included, but no reporting of harms  
Staples (2008)33          
Pettrone & McCall (2005)35        

               
ESWT: extracorporeal shockwave therapy; RCT: randomized controlled trial.
The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Population key: 1. Intended use population unclear; 2. Clinical context is unclear; 3. Study population is unclear; 4. Study population not representative of intended use.
b Intervention key: 1. Not clearly defined; 2. Version used unclear; 3. Delivery not similar intensity as comparator; 4. Not the intervention of interest.
c Comparator key: 1. Not clearly defined; 2. Not standard or optimal; 3. Delivery not similar intensity as intervention; 4. Not delivered effectively.
d Outcomes key: 1. Key health outcomes not addressed; 2. Physiologic measures, not validated surrogates; 3. No CONSORT reporting of harms; 4. Not establish and validated measurements; 5. Clinical significant difference not prespecified; 6. Clinical significant difference not supported.
e Follow-Up key: 1. Not sufficient duration for benefit; 2. Not sufficient duration for harms.

Table 15. Study Design and Conduct Limitations of RCTs Assessing ESWT for Lateral Epicondylitis

Study Allocationa Blindingb Selective Reportingc Data Completenessd Powere Statisticalf
Capan (2016)30     1. Not registered 6. No intent-to-treat analysis 1. Calculations not reported  
Staples (2008)33     1. Not registered   3. Underpowered  
Pettrone & McCall (2005)35 3. Unclear how randomized   1. Not registered    

       
ESWT: extracorporeal shockwave therapy; RCT: randomized controlled trial.
The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Allocation key: 1. Participants not randomly allocated; 2. Allocation not concealed; 3. Allocation concealment unclear; 4. Inadequate control for selection bias.
b Blinding key: 1. Not blinded to treatment assignment; 2. Not blinded outcome assessment; 3. Outcome assessed by treating physician.
c Selective Reporting key: 1. Not registered; 2. Evidence of selective reporting; 3. Evidence of selective publication.
d Data Completeness key: 1. High loss to follow-up or missing data; 2. Inadequate handling of missing data; 3. High number of crossovers; 4. Inadequate handling of crossovers; 5. Inappropriate exclusions; 6. Not intent to treat analysis (per protocol for noninferiority trials).
e Power key: 1. Power calculations not reported; 2. Power not calculated for primary outcome; 3. Power not based on clinically important difference.
f Statistical key: 1. Intervention is not appropriate for outcome type: (a) continuous; (b) binary; (c) time to event; 2. Intervention is not appropriate for multiple observations per patient; 3. Confidence intervals and/or p values not reported; 
4.Comparative treatment effects not calculated.

Section Summary: Lateral Epicondylitis
The most direct evidence on the use of ESWT to treat lateral epicondylitis comes from multiple small RCTs, which did not consistently show outcome improvements beyond those seen in control groups. The highest quality trials tend to show no benefit, and systematic reviews have generally concluded that the evidence does not support a treatment benefit over placebo or no treatment.

Shoulder Tendinopathy
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conservative therapy (e.g., physical therapy) and nonsteroidal anti-inflammatory therapy, in patients with shoulder tendinopathy.

The question addressed in this evidence review is: Does the use of ESWT for shoulder tendinopathy improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with shoulder tendinopathy.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest include conservative therapy (eg, physical therapy) and nonsteroidal anti-inflammatory therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 16. Outcomes of Interest for Individuals with Shoulder Tendinopathy

Outcomes Details Timing
Symptoms
  • Pain reduction via VAS assessment
  • American Shoulder and Elbow Surgeons (ASES) scale for pain
  • L'Insalata Shoulder Questionnaire for pain
  • Reduction in size of deposit as assessed by radiograph or ultrasound1
1 week to 1 year
Functional outcomes
  • Constant-Murley Score (CMS)
  • Shoulder Pain And Disability Index (SPADI)
  • American Shoulder and Elbow Surgeons (ASES) scale for function
  • Simple Shoulder Test
1 week to 1 year
Quality of life
  • Patients' subjective assessment of improvement
1 week to 1 year


VAS: visual analog scale.
1 For studies that assessed calcific tendinitis.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

A systematic review and network meta-analysis of RCTs by Wu et al. (2017) compared the effectiveness of nonoperative treatments for chronic calcific tendinitis.36 The literature review, conducted through April 2016, identified 14 RCTs (N = 1,105 patients) for inclusion. Treatments included in the network meta-analysis were ultrasound-guided needling (UGN), RSW, high-energy FSW (H-FSW), low-energy FSW (L-FSW), ultrasound therapy, and transcutaneous electrical nerve stimulation. Trials either compared the treatments with each other or with sham/placebo. Outcomes were pain (VAS range, 0 [no pain] to 10 [worst pain]), functional assessment (Constant-Murley Score [CMS], up to 100 [asymptomatic]), and calcific deposit change ("no change," "partial resolution," or "complete resolution," assessed by radiograph or ultrasound). Treatments most effective in reducing pain and resolving calcific deposits were UGN, RSW, and H-FSW. The only treatment significantly improving function was H-FSW. Table 17 lists the treatments, from most effective to the least effective, by outcome, as determined by network meta-analysis.

Table 17. Ranking of Nonoperative Treatments for Chronic Calcific Tendinitis, by Outcome

Pain Reduction (8 Trials) Functional Assessment (7 Trials) Calcific Deposit Change (14 Trials)
Treatment Difference From Control (95% CrI) Treatment Difference From Control (95% CrI) Treatment Difference From Control (95% CrI)
UGN 8.0 (4.9 to 11.1) H-FSW 25.1 (10.3 to 40.0) UGN 6.8 (3.8 to 9.9)
RSW 6.1 (3.9 to 8.3) TENS 8.7 (-13.5 to 30.9) RSW 6.2 (3.2 to 9.1)
H-FSW 4.2 (2.0 to 6.4) L-FSW 7.6 (-7.2 to 22.5) H-FSW 2.4 (1.5 to 3.4)
TENS 3.2 (-0.1 to 6.5) Ultrasound 3.3 (-15.0 to 21.6) Ultrasound 2.1 (0.4 to 3.8)
L-FSW 1.9 (-0.4 to 4.3)     TENS 1.9 (-0.8 to 4.6)
Ultrasound 1.1 (-1.7 to 3.9)     L-FSW 1.2 (0.1 to 2.2)

Adapted from Wu et al. (2017).36,
CrI: credible interval; H-FSW: high-energy focused extracorporeal shockwave; L-FSW: low-energy focused extracorporeal shockwave; RSW: radial extracorporeal shockwave; TENS: transcutaneous electrical nerve stimulation; UGN: ultrasound-guided needling.

A systematic review and network meta-analysis of RCTs by Arirachakaran et al. (2017) evaluated ESWT, ultrasound-guided percutaneous lavage (UGPL), subacromial corticosteroid injection (SAI), and combined treatments for rotator cuff calcific tendinopathy.37 The literature search, conducted through September 2015, identified 7 RCTs for inclusion. Six of the trials had ESWT as 1 treatment arm, with the following comparators: placebo (4 trials), UGPL plus ESWT (1 trial), and UGPL plus SAI (1 trial). One trial compared UGPL plus SAI with SAI alone. Outcomes were CMS (5 trials), VAS pain (5 trials), and size of calcium deposit (4 trials). Network meta-analysis results are summarized below:

  • VAS pain:

    • ESWT, UGPL plus SAI, and SAI alone were more effective in reducing pain than placebo

    • Compared with each other, ESWT, UGPL plus SAI, and SAI alone did not differ statistically

  • CMS:

    • ESWT was statistically more effective than placebo

    • No other treatment comparisons differed statistically

  • Size of calcium deposit:

    • UGPL plus SAI was statistically more effective than placebo and SAI alone

    • ESWT was statistically better than SAI alone, but not more effective than placebo.

In a systematic review and meta-analysis, Ioppolo et al. (2013) identified 6 RCTs that compared ESWT with sham treatment or placebo for calcific shoulder tendinopathy.38 Greater shoulder function and pain improvements were reported at 6 months with ESWT than placebo. Most studies were considered low quality.

Table 18. Comparison of Systematic Reviews with Meta-Analyses Assessing ESWT for Shoulder Tendinopathy

Study Arirachakaran (2017)37 Ioppolo (2013)38 Wu (2017)36
Ainsworth (2007)    
Albert (2007)    
Cacchio (2006)
Cosentino (2003)
Cosentino (2004)    
del Castillo-Gonzalez (2016)    
de Witte (2013)    
Ebenbichler (1999)    
Gerdesmeyer (2003)
Hearnden (2009)  
Hsu (2008)
Ioppolo (2012)    
Kim (2014)  
Krasny (2005)    
Loew (1999)    
Pan (2003)    
Peters (2004)    
Pleiner (2004)    
Rompe (1998)    


ESWT: extracorporeal shockwave therapy.

Table 19. Characteristics of Systematic Reviews with Meta-Analyses Assessing ESWT for Shoulder Tendinopathy

Study Dates Trials Participants N (Range) Design Duration
Arirachakaran (2017)37 2003 – 2008 4 Patients with rotator cuff calcific tendinopathy 882 (136 to 302) RCTs 6 to 12 months
Ioppolo (2013)38 2003 – 2009 6 Adults with shoulder pain or tenderness from calcific tendinitis with type I or II calcification 460 (20 to 144) RCTs 1 week to 1 year
Wu (2017)36 1998 – 2016 5 Adults with clinical symptoms related to calcific tendinitis of the shoulder 370 (20 to 144) RCTs 1 month to 1 year


ESWT: extracorporeal shockwave therapy; RCT: randomized controlled trial.

Table 20. Results of Systematic Reviews With Meta-Analyses Assessing ESWT, H-ESWT, L-ESWT, and rESWT for Shoulder Tendinopathy

Study VAS Score Improvement/Pain Reduction CMS/SPADI/Functional Improvement Decrease in Calcium Deposit Size
ESWT
Arirachakaran (2017)37      
I% 95.8 92.4 97.4
UMD -4.4 23.3 -11.3 mm
95% CI -6.3 to -2.3 9.8 to 17.6 -24.7 to 2.2
P-value < .05 < .05 > .05
Ioppolo (2013)38      
Pooled total resorption ratio - - 27.19
95% CI - - 7.20 to 102.67
P-value     0.552
Pooled partial resorption ratio - - 16.22
95% CI - - 3.33 to 79.01
P-value     .845
H-FSW
Wu (2017)36      
WMD 4.18 - -
95% CrI 1.99 to 6.37 - -
L-FSW
WMD 1.94 - -
95% CrI -0.42 to 4.30 - -
rESWT
WMD 6.12 - -
95% CrI 3.91 to 8.34 - -


CI: confidence interval; CMS: Constant-Murley Score; CrI: credible interval; CSI: corticosteroid injection; ESWT: extracorporeal shockwave therapy; H-ESWT: high-energy/intensity extracorporeal shockwave therapy; H-FSW: high-energy focused extracorporeal shockwave therapy; L-ESWT: low-energy/intensity extracorporeal shockwave therapy; L-FSW: low-energy focused extracorporeal shockwave therapy; MD: mean difference; OR: odds ratio; rESWT: radial extracorporeal shockwave therapy; RR: risk ratio; SE: supervised exercise; SMD: standard mean difference; SPADI: Shoulder Pain And Disability Index; UMD: unstandardized mean difference; VAS: visual analog scale ; WMD: weighted mean difference.

The following systematic reviews are mostly qualitative in nature and are not included in the summary tables.

In a systematic review by Yu et al. (2015) of RCTs of various passive physical modalities for shoulder pain, which included 11 studies considered at low risk of bias, 5 studies reported on ESWT.39 Three, published from 2003 to 2011, assessed calcific shoulder tendinopathy, including 1 RCT comparing high-energy ESWT with low-energy ESWT (N = 80), 1 RCT comparing RSW with sham ESWT (N = 90), and 1 RCT comparing high-energy ESWT with low-energy ESWT and sham ESWT (N = 144). All 3 trials reported statistically significant differences between groups for change in VAS score for shoulder pain.

In another meta-analysis of RCTs comparing high-energy with low-energy ESWT, Verstraelen et al. (2014) evaluated 5 studies (N = 359 patients) on calcific shoulder tendinitis.40 Three were considered high quality. High-energy ESWT was associated with significant improvements in functional outcomes, with a mean difference at 3 months of 9.88 (95% CI, 0.04 to 10.72; p < .001). High-energy ESWT was more likely to lead to resolution of calcium deposits at 3 months (pooled odds ratio, 3.4; 95% CI, 1.35 to 8.58; p = .009). The pooled analysis could not be performed for 6-month follow-up data.

Bannuru et al. (2014) published a systematic review of RCTs comparing high-energy ESWT with placebo or low-energy ESWT for the treatment of calcific or noncalcific shoulder tendinitis.41 All 7 studies comparing ESWT with placebo for calcific tendinitis reported significant improvements in pain or functional outcomes associated with ESWT. Only high-energy ESWT was consistently associated with significant improvements in both pain and functional outcomes. Eight studies comparing high- with low-energy ESWT for calcific tendinitis did not demonstrate significant improvements in pain outcomes, although shoulder function improved. Trials were reported to be of low quality with a high risk of bias.

Huisstede et al. (2011) published a systematic review of RCTs that included 17 RCTs on calcific (n = 11) and noncalcific (n = 6) tendinopathy of the rotator cuff.42 Moderate-quality evidence was found for the efficacy of ESWT versus placebo for calcific tendinopathy, but not for noncalcific tendinopathy. High-frequency ESWT was found to be more efficacious than low-frequency ESWT for calcific tendinopathy.

Randomized Controlled Trials
An RCT by Kvalvaag et al. (2017) randomized patients with subacromial shoulder pain to RSW plus supervised exercise (n = 74) or to sham treatment plus supervised exercise (n = 69).43,44 Patients received 4 treatments of RSW or sham at 1-week intervals. After 24 weeks of follow-up, both groups improved from baseline, with no significant differences between groups. Within a prespecified subgroup of patients with calcification in the rotator cuff, there was a statistically significant improvement in the group receiving ESWT compared with sham treatment (p = .18). After 1 year, there was no statistically significant difference in improvements between RSW and sham when groups were analyzed together and separately.

An RCT by Kim et al. (2016) evaluated the use of ESWT in patients with calcific tendinitis.45 All patients received nonsteroidal anti-inflammatory drugs, transcutaneous electrical nerve stimulation, and ultrasound therapy (N = 34). A subset (n = 18) also received ESWT, 3 times a week for 6 weeks. CMS was measured at 2, 6, and 12 weeks. Both groups improved significantly from baseline. The group receiving ESWT improved significantly more than the control group; however, the lack of a sham control limits interpretability of results.

The following are select trials included in the systematic reviews described above.

Kim et al. (2014) compared UGPL plus SAI with ESWT in patients who had unilateral calcific shoulder tendinopathy and ultrasound-documented calcifications of the supraspinatus tendon.46 Sixty-two patients were randomized. Fifty-four patients were included in the data analysis (8 subjects were lost to follow-up). ESWT was performed for 3 sessions once weekly. The radiologic evaluation was blinded, although it was not specified whether evaluators for pain and functional outcomes were blinded. After an average follow-up of 23.0 months (range, 12.1 to 28.5 months), functional outcomes improved in both groups: for the UGPL plus SAI group, scores on the American Shoulder and Elbow Surgeons scale improved from 41.5 to 91.1 (p = .001) and on the Simple Shoulder Test from 38.2% to 91.7% (p = .03). In the ESWT group, scores on the American Shoulder and Elbow Surgeons scale improved from 49.9 to 78.3 (p = .026) and on the Simple Shoulder Test from 34.0% to 78.6% (p = .017). Similarly, VAS pain scores improved from baseline to the last follow-up in both groups. At the last follow-up visit, calcium deposit size was smaller in the UGPL plus SAI group (0.5 mm) than in the ESWT group (5.6 mm; p = .001).

An example of a high-energy versus low-energy trial is that by Schofer et al. (2009), which assessed 40 patients with rotator cuff tendinopathy.47 An increase in function and reduction of pain were found in both groups (p < .001). Although improvement in the Constant score was greater in the high-energy group, there were no statistically significant differences in any outcomes studied (Constant score, pain, subjective improvement) at 12 weeks, or at 1 year post-treatment.

At least 1 RCT has evaluated patients with bicipital tendinitis of the shoulder.48 This trial by Liu et al. (2012) randomized 79 patients with tenosynovitis to ESWT or to sham treatment. ESWT was given for 4 sessions over 4 weeks. Outcomes were measured at up to 12 months using a VAS for pain and the L'Insalata Shoulder Questionnaire. The mean decrease in the VAS score at 12 months was greater for the ESWT group (4.24 units) than for the sham group (0.47 units; p < .001). There were similar improvements in the L'Insalata Shoulder Questionnaire, with scores in the ESWT group improving by 22.8 points.

Section Summary: Shoulder Tendinopathy
A number of small RCTs, summarized in several systematic reviews and meta-analyses, have evaluated the use of ESWT to treat shoulder tendinopathy. Network meta-analyses focused on 3 outcomes: pain reduction, functional assessment, and change in calcific deposits. One network meta-analysis separated trials using H-FSW, L-FSW, and RSW. It reported that the most effective treatment for pain reduction was UGN, followed by RSW and H-FSW. The only treatment showing a benefit in functional outcomes was H-FSW. For the largest change in calcific deposits, the most effective treatment was UGN, followed by RSW and H-FSW. Although some trials have reported a benefit for pain and functional outcomes, particularly for high-energy ESWT for calcific tendinopathy, many available trials have been considered poor quality. More high-quality trials are needed to determine whether ESWT improves outcomes for shoulder tendinopathy.

Achilles Tendinopathy
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conservative therapy (eg, physical therapy) and nonsteroidal anti-inflammatory therapy, in patients with Achilles tendinopathy.

The question addressed in this evidence review is: Does the use of ESWT for Achilles tendinopathy improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with Achilles tendinopathy.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest include conservative therapy (e.g., physical therapy) and nonsteroidal anti-inflammatory therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 21. Outcomes of Interest for Individuals with Achilles Tendinopathy

Outcomes Details Timing
Symptoms
  • Pain improvement via VAS assessment
  • Victorian Institute of Sports Assessment-Achilles (measures redness, warmth, swelling, tenderness, edema)
  • American Orthopedic Foot And Ankle Score (AOFAS) for pain1
  • Roles and Maudsley pain scores of "good" or "excellent"
4 weeks to > 1 year
Functional outcome
  • American Orthopedic Foot And Ankle Score (AOFAS) for function
  • Roles and Maudsley function scores of "good" or "excellent"
4 weeks to > 1 year

VAS: visual analog scale.
1 Researchers concluded that AOFAS might not be appropriate to evaluate treatment of Achilles tendinopathy.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

Mani-Babu et al. (2015) reported on results of a systematic review of studies evaluating ESWT for lower-limb tendinopathies.49 Reviewers included 20 studies, 11 of which evaluated ESWT for Achilles tendinopathy (5 RCTs, 4 cohort studies, 2 case-control studies). In the pooled analysis, reviewers reported that evidence was limited, but showed that ESWT was associated with greater short-term (< 12 months) and long-term (> 12 months) improvements in pain and function compared with nonoperative treatments, including rest, footwear modifications, anti-inflammatory medication, and gastrocnemius-soleus stretching and strengthening. Reviewers noted that findings from RCTs of ESWT for Achilles tendinopathy were contradictory, but that some evidence supported short-term improvements in function with ESWT. Reviewers warned that results be interpreted cautiously due to heterogeneity in patient populations (age, insertional versus mid-portion Achilles tendinopathy) and treatment protocols.

Al-Abbad and Simon (2013) conducted a systematic review of 6 studies on ESWT for Achilles tendinopathy.50 Selected for the review were 4 small RCTs and 2 cohort studies. Satisfactory evidence was found in 4 studies demonstrating the effectiveness of ESWT in the treatment of Achilles tendinopathy at 3 months. However, 2 RCTs found no significant difference between ESWT and placebo in the treatment of Achilles tendinopathy. These trials are described next.51,52

Randomized Controlled Trials
Abdelkader et al. (2021) performed a double-blind, randomized trial that compared ESWT (n = 25) with sham control (n = 25) in patients with unilateral noninsertional Achilles tendinopathy.53 Scores were improved in both ESWT and control groups at 1 month on the Victorian Institute of Sports Assessment-Achilles (VISA-A) questionnaire (85 and 53.4, respectively) and the VAS (1 and 7, respectively), as well as at 16 months on the VISA-A (80 and 67, respectively) and the VAS (3 and 5.6, respectively). At both time points, scores were statistically and clinically superior with ESWT than with sham control (both p = .0001).

Pinitkwamdee et al. (2020) conducted a double-blind, randomized trial to compare the effectiveness of low-energy ESWT (n = 16) with sham controls (n = 15) in patients with chronic insertional Achilles tendinopathy.54 The primary outcomes consisted of changes in VAS pain scores and VAS foot and ankle pain scores at time points ranging from 2 to 24 weeks. At 24 weeks, low-energy ESWT and sham controls revealed similar changes in VAS and VAS foot and ankle pain scores. But ESWT had a significant improvement in VAS scores compared with sham controls at weeks 4 to 12, based on which, authors concluded that ESWT may provide a short period of therapeutic effect.

Lynen et al. (2017) published results from an RCT comparing 2 peri-tendinous hyaluronan injections (n = 29) with 3 ESWT applications (n = 30) for the treatment of Achilles tendinopathy.55 The primary outcome was percent change in VAS pain score at the 3-month follow-up. Other measurements included the VISA-A, clinical parameters (redness, warmth, swelling, tenderness, edema), and patients' and investigators' impression of treatment outcome. Follow-up was conducted at 4 weeks, 3 months, and 6 months. Pain decreased in both groups from baseline, though percent decrease in pain was statistically larger in the hyaluronan injections group than in the ESWT group at all follow-up time points. Secondary outcomes also showed larger improvements in the hyaluronan injection group.

The 2 trials described next were included in the systematic reviews.

Rasmussen et al. (2008) reported on a single-center, double-blind controlled trial with 48 patients, half randomized after 4 weeks of conservative treatment to 4 sessions of active RSW and half to sham ESWT.52 The primary end point was AOFAS score measuring function, pain, and alignment and VAS pain score. AOFAS score after treatment increased from 70 to 88 in the ESWT group and from 74 to 81 in the control (p = .05). The pain was reduced in both groups, with no statistically significant difference between groups. The authors suggested that the AOFAS might not be appropriate to evaluate treatment of Achilles tendinopathy.

Costa et al. (2005) reported on a randomized, double-blind, placebo-controlled trial of ESWT for chronic Achilles tendon pain treated monthly for 3 months.51 The trial randomized 49 participants and was powered to detect a 50% reduction in VAS pain scores. No differences in pain relief at rest or during sports participation were found at 1 year. Two older ESWT-treated participants experienced tendon ruptures.

Section Summary: Achilles Tendinopathy
Two systematic reviews of RCTs and 3 RCTs published after the systematic reviews have evaluated the use of ESWT for Achilles tendinopathy. In the most recent systematic review, a pooled analysis found that ESWT reduced both short- and long-term pain compared with nonoperative treatments, although these reviewers warned that results were inconsistent across the RCTs and that there was heterogeneity across patient populations and treatment protocols. An RCT published after the systematic review compared ESWT with hyaluronan injections and reported improvements in both treatment groups, although significantly higher in the injection group. Another RCT found no difference in pain scores between low-energy ESWT and sham controls at week 24, but ESWT may provide short therapeutic effects at weeks 4 to 12. Another RCT found scores were statistically and clinically improved with ESWT compared with sham control at 1 month and 16 months on measures of pain and function.

Patellar Tendinopathy
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conservative therapy (e.g., physical therapy) and nonsteroidal anti-inflammatory therapy, in patients with patellar tendinopathy.

The question addressed in this evidence review is: Does the use of ESWT for patellar tendinopathy improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with patellar tendinopathy.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest include conservative therapy (eg, physical therapy) and nonsteroidal anti-inflammatory therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 22. Outcomes of Interest for Individuals with Patellar Tendinopathy

Outcomes Details Timing
Symptoms
  • Pain reduction via VAS assessment
  • Patellar tendon thickness
  • Victorian Institute of Sports Assessment-Patellar Tendon
  • McGill Pain Questionnaire
  • Roles and Maudsley score for pain
  • Likert scale/numerical rating scale for pain
  • Swelling
< 1 month to 1 year
Functional Outcomes
  • Range of motion
  • Knee Outcome Survey Activities of Daily Living
  • Vertical jump test
  • Roles and Maudsley score for function
  • International Knee Documentation Committee scale
< 1 month to 1 year


VAS: visual analog scale.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

Liao et al. (2018) examined RCTs to determine the clinical efficacy of ESWT of different shockwave types, energy levels, and durations to treat knee tendinopathies and other knee soft tissue disorders.56 Their review included 19 RCTs, encompassing 1,189 participants. Of the participants, 562 underwent ESWT and 627 received a placebo or other conservative treatment. Analysis revealed that ESWT results in significant improvements in pain levels, with a pooled standard mean difference of -1.49 (95% CI, -2.11 to -0.87; p < .0001; I2 = 95%) compared with the control groups. This effect resulted regardless of follow-up duration, type of shockwave, application level, or control intervention type. Four trials reported range of motion (ROM) recovery, specifically from focused ESWT (FoSWT) and radial ESWT (RaSWT), with significant pooled standard mean differences of 2.61 (95% CI, 2.11 to 3.12; p < .0001; I2 = 0%). In general, low-energy FoSWT was more effective in increasing treatment success rate than high-energy FoSWT; however, high-energy RaSWT was more effective than low-energy RaSWT. No severe adverse effects were reported with ESWT. Meta-analysis limitations include, but are not limited to, heterogeneity across trials; no consideration for other application parameters (rate of shocks, number of treatments, and treatment intervals); and high risk of selection, blinding, performance, and other biases.

Van Leeuwen et al. (2009) conducted a literature review to study the effectiveness of ESWT for patellar tendinopathy and to draft a treatment protocol.57 Reviewers found that most of the 7 selected studies had methodologic deficiencies, small numbers and/or short follow-up periods, and variation in treatment parameters. Reviewers concluded ESWT appears to be a safe and promising treatment but could not recommend a treatment protocol.

In the systematic review of ESWT for lower-extremity tendinopathies (previously described), Mani-Babu et al. (2015) identified 7 studies of ESWT for patellar tendinopathy (2 RCTs, 1 quasi-RCT, 1 retrospective cross-sectional study, 2 prospective cohort studies, 1 case-control study).49 The 2 RCTs came to different conclusions: 1 found no difference in outcomes between ESWT and placebo at 1, 12, or 22 weeks, whereas the other found improved outcomes on vertical jump test and Victorian Institute of Sport Assessment-Patellar scores at 12 weeks with ESWT compared with placebo. Two studies that evaluated outcomes beyond 24 months found ESWT comparable to patellar tenotomy surgery and better than nonoperative treatments.

Randomized Controlled Trials
An RCT by Thijs et al. (2017) compared the use of ESWT plus eccentric training (n = 22) with sham shock wave therapy plus eccentric training (n = 30) for the treatment of patellar tendinopathy.58 Patients were physically active with a mean age of 28.6 years (range, 18 to 45 years). ESWT and sham shock wave were administered in 3 sessions, once weekly. Patients were instructed to perform eccentric exercises, 3 sets of 15 repetitions twice daily for 3 months on a decline board at home. Primary outcomes were Victorian Institute of Sport Assessment-Patellar score and pain score during functional knee loading tests (10 decline squats, 3 single leg jumps, 3 vertical jumps).

Measurements were taken at baseline, 6, 12, and 24 weeks. There were no statistically significant differences between the ESWT and sham shock wave groups for any of the primary outcome measurements at any follow-up except for the vertical jump test at week 6.

In an RCT of patients with chronic patellar tendinopathy (N = 46), despite at least 12 weeks of nonsurgical management, Smith and Sellon (2014) reported that improvements in pain and functional outcomes were significantly greater (p < .05) with plasma-rich protein injections than with ESWT at 6 and 12 months, respectively.59

Section Summary: Patellar Tendinopathy
The trials on the use of ESWT for patellar tendinopathy have reported inconsistent results and were heterogeneous in treatment protocols and lengths of follow-up.

Medial Tibial Stress Syndrome
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as icing or support, in patients with medial tibial stress syndrome.

The question addressed in this evidence review is: Does the use of ESWT for medial tibial stress syndrome improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with medial tibial stress syndrome.

Interventions
The therapy being considered is ESWT.

Comparators
The comparator of interest is conservative therapy (e.g., icing, support).

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 23. Outcomes of Interest for Individuals with Medial Tibial Stress Syndrome

Outcomes Details Timing
Symptoms
  • 6-point Likert scale for pain
  • Self-reported pain during bone pressure, muscle pressure, or while running
1 to 15 months from baseline


Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Randomized and Nonrandomized Studies

Newman et al. (2017) published a double-blind, sham-controlled randomized trial on the use of ESWT for the treatment of 28 patients with medial tibial stress syndrome (commonly called shin splints).60 Enrolled patients had running-related pain for at least 21 days confined to the posteromedial tibia, lasting for hours or days after running. Patients received treatments (ESWT or sham) at weeks 1, 2, 3, 5, and 9 and were instructed to keep activity levels as consistent as possible. At week 10 measurements, there was no difference between the treatment and control groups in self-reported pain during bone pressure, muscle pressure, or during running. There was no difference in pain-limited running distances between groups.

Rompe et al. (2010) published a report on the use of ESWT in medial tibial stress syndrome.61 In this nonrandomized cohort study, 47 patients with medial tibial stress syndrome for at least 6 months received 3 weekly sessions of RSW and were compared with 47 age-matched controls at 4 months. Mild adverse events were noted in 10 patients: skin reddening in 2 patients and pain during the procedure in 8 patients. Patients rated their condition on a 6-point Likert scale. Successful treatment was defined as self-rating "completely recovered" or "much improved." The authors reported a success rate of 64% (30/47) in the treatment group compared with 30% (14/47) in the control group. In a comment, Barnes (2010) raised several limitations of this nonrandomized study, including the possibility of selection bias.62

Section Summary: Medial Tibial Stress Syndrome
Evidence for the use of ESWT for medial tibial stress syndrome includes a small RCT and a small nonrandomized study. The RCT showed no differences in self-reported pain measurements between study groups. The nonrandomized trial reported improvements with ESWT, but selection bias limited the strength of the conclusions.

Osteonecrosis of the Femoral Head
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as medication (eg, alendronate) or hip arthroplasty, in patients with osteonecrosis of the femoral head.

The question addressed in this evidence review is: Does the use of ESWT for osteonecrosis of the femoral head improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with osteonecrosis of the femoral head.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest include medication and hip arthroplasty.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 24. Outcomes of Interest for Individuals with Osteonecrosis of the Femoral Head

Outcomes Details Timing
Symptoms
  • Pain reduction via VAS assessment
  • Harris Hip Scores for pain
  • Radiographic reduction of bone marrow edema on magnetic resonance imaging
3 months to > 24 months
Functional outcomes
  • Harris Hip Scores for function
3 months to > 24 months


VAS: visual analog scale.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

In their meta-analysis, Hao et al. (2018) compared the effectiveness of ESWT with other treatment strategies in improving pain scores and Harris Hip Score (HHS) for patients with osteonecrosis of the femoral head.63 Their search for interventional studies published in Chinese or English yielded 4 articles with a total of 230 patients, most of whom were in stages I through III of osteonecrosis of the femoral head. Before treatment, no significant differences in pain scores (p = .1328) and HHS (p = .287) were found between the ESWT group (n = 130) and control group (n = 110). Post-treatment, the ESWT group reported significantly higher improvement in pain scores than the control group (standard mean difference, -2.1148; 95% CI, -3.2332 to -0.9965; Z = 3.7063; p = .0002), as well as higher HHSs (standard mean difference, 2.1377; 95% CI, 1.2875 to 2.9880; Z = 4.9281; p < .001). However, the analysis revealed no significant improvements in pain scores before and after treatment (p = .005), but it did reveal significant improvements in the HHS (p < .001). Patient follow-up time across studies ranged from 3 to 25 months. This analysis had several limitations including: only 1 RCT was included out of 4 studies; small sample size resulted in more pronounced heterogeneity between studies; the studies were of poor quality; publication bias was detected for the HHS after treatment; and only 2 studies reported pain scores.

A systematic review by Zhang et al. (2016) evaluated evidence on the use of ESWT for osteonecrosis of the femoral head.64 The literature search, conducted through July 2016, identified 17 studies for inclusion (9 open-label studies, 4 RCTs, 2 cohort studies, 2 case reports). Study quality was assessed using the Oxford Centre of Evidence-Based Medicine Levels of Evidence (I = highest quality and V = lowest quality, and each level can be subdivided a through c). Four studies were Ib, 2 studies were IIb, and 11 studies were IV. Most studies included patients with Association Research Circulation Osseous categories I through III (out of 5 stages of osteonecrosis). Outcomes in most studies were VAS pain score and HHS, a composite measure of pain and hip function. Reviewers concluded that ESWT can be a safe and effective method to improve motor function and relieve pain, particularly in patients with early-stage osteonecrosis. Studies that included imaging results showed that bone marrow edema could be relieved, but that necrotic bone was not reversed. Evidence limitations included the heterogeneity of treatment protocol (numbers of sessions, energy intensities, focus sizes differed among studies) and most studies were of low quality.

A systematic review of ESWT for osteonecrosis (avascular necrosis) of the femoral head was conducted by Alves et al. (2009).65 The literature search conducted through 2009 identified 5 articles, all from non-U.S. sites (2 RCTs, 1 comparative study, 1 open-label study, 1 case report; N = 133 patients). Of the 2 RCTs, 1 randomized 48 patients to the use of concomitant alendronate; both arms received ESWT treatments and therefore ESWT was not a comparator. The other RCT compared ESWT with a standard surgical procedure. All results noted a reduction in pain during the trial, which the authors attributed to ESWT. However, reviewers, when discussing the limitations of the available evidence, noted a lack of double-blind design, small numbers of patients enrolled, short follow-up times, and nonstandard interventions (e.g., energy level, the number of treatments).

Section Summary: Osteonecrosis of the Femoral Head
The body of evidence on the use of ESWT for osteonecrosis of the femoral head consists of systematic reviews of small, mostly nonrandomized studies. Many of the studies were low quality and lacked comparators. While most studies reported favorable outcomes with ESWT, limitations such as heterogeneity in the treatment protocols, patient populations, and lengths of follow-up make conclusions on the efficacy of ESWT for osteonecrosis uncertain.

Nonunion or Delayed Union of Acute Fracture
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on surgical therapy for patients with acute fracture nonunion or delayed union.

The question addressed in this evidence review is: Does the use of ESWT for acute fracture nonunion or delayed union improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with acute fracture nonunion or delayed union.

Interventions
The therapy being considered is ESWT.

Comparators
The comparator of interest is surgical therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 25. Outcomes of Interest for Individuals with Acute Fracture Nonunion or Delayed Union

Outcomes Details Timing
Symptoms
  • Pain reduction via VAS assessment
  • Radiographic evidence of healing
6 to 12 months
Functional outcomes
  • Weight-bearing status
6 to 12 months


VAS: visual analog scale.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

Sansone et al. (2022) published a systematic review and meta-analysis involving 23 studies that evaluated the effectiveness of ESWT in the treatment of nonunion fracture in long bones.66 The review included 2 RCTs, a single non-randomized controlled trial, and 20 observational studies (14 retrospective; 6 prospective), with a total of 1,838 cases of delayed union or nonunion. Only data for 1,200 of the 1,838 cases were included in the meta-analysis since several studies did not separate results from long bones from those of other bones. Healing occurred in 876 (73%) of the 1200 total long bones after ESWT. Hypertrophic cases were associated with a 3-fold higher healing rate as compared to oligotrophic or atrophic cases (p = .003). Bones in the metatarsal region were the most receptive to ESWT with a healing rate of 90%, followed by the tibiae (75.5%), femurs (66.9%), and humeri (63.9%). Increased healing rates were observed among patients who had shorter periods between the injury and ESWT (p < .02). Six months of follow-up was generally too brief to fully evaluate the healing potential of ESWT with several studies demonstrating increasing healing rates at follow-ups beyond 6 months after the last ESWT. Limitations included that the authors in 7 included studies did not distinguish between delayed union and nonunion when describing the patient population. In several other studies, the patient population was described clearly; however, data from delayed unions and nonunions were reported together. Incomplete data reporting also contributed to a lack of identifying and differentiating treatment protocols for ESWT.

Zelle et al. (2010) published a review of the English and German medical literature on ESWT for the treatment of fractures and delayed union/nonunion.67 Limiting the review to studies with more than 10 patients, reviewers identified 10 case series and 1 RCT. The number of treatment sessions, energy levels, and definitions of nonunion varied across studies; union rates after the intervention were likewise defined heterogeneously, ranging from 40.7% to 87.5%. Reviewers concluded the overall quality of evidence was conflicting and of poor quality.

Randomized Controlled Trials
Wang et al. (2007), which was the single RCT included in the Zelle et al. (2010) review, randomized 56 trauma patients with femur or tibia fractures to a single ESWT treatment following surgical fixation while still under anesthesia.68 Patients in the control group underwent surgical fixation but did not receive the ESWT. Patients were evaluated for pain and percent weight-bearing capability by an independent, blinded evaluator at 3, 6, and 12 months. Radiographs taken at these same intervals were evaluated by a radiologist blinded to study group assignment. Both groups showed significant improvements in pain scores and weight-bearing status. Between-group comparisons of VAS pain and weight bearing favored ESWT patients at each interval. At 6 months, patients who had received ESWT had VAS scores of 1.2 compared with 2.5 in the control group (p < .001); mean percentage of weight bearing at 6 months was 87% and 78%, respectively (p = .01). Radiographic evidence of union at each interval also favored the ESWT group. At 6 months, 63% (17/27) of the treatment group achieved fracture union compared with 20% (6/30) in the control group (p < .001). The authors noted some limitations of the trial: the small number of patients enrolled, surgeries performed by multiple surgeons, and questions about the adequacy of randomization.

Cacchio et al. (2009) published a multicenter RCT after the Zelle et al. (2010) review, which randomized 126 patients into 3 groups: low-energy ESWT, high-energy ESWT therapy, or surgery.69 Nonunion fractures were defined as at least 6 months without evidence of radiographic healing. The primary end point was radiographic evidence of healing. Secondary end points were pain and functional status, collected by blinded evaluators. Neither patients nor treating physicians were blinded. At 6 months, healing rates in the low-energy ESWT, high-energy ESWT, and surgical arms were similar (70%, 71%, 73%, respectively). All groups' healing rates improved at 12- and 24-month follow-ups, without significant between-group differences. Secondary end points of pain and disability were also similar. Lack of blinding might have led to differing levels of participation in other aspects of the treatment protocol.

A study by Zhai et al. (2016), included in the Sansone et al. (2022) review, evaluated the use of human autologous bone mesenchymal stem cells combined with ESWT for the treatment of nonunion long bones.70 Nonunion was defined as 6 or more months post fracture with no evidence of additional healing in the past 3 months. Patients were randomized to high-energy ESWT (n = 31) or human autologous mesenchymal stem cells plus ESWT (n = 32). ESWT was administered every 3 days: 4 times for upper-limb nonunion and 5 times for lower-limb nonunion. Outcome measures were no pain, no abnormal mobility, an x-ray showing blurred fracture line, and upper-limb holding 1 kg for 1 minute or lower-limb walking for 3 minutes. Success was defined as meeting all 4 criteria at 12 months. The human autologous stem cells plus ESWT group experienced an 84% healing rate. The ESWT alone group experienced a 68% healing rate (p < .05).

Section Summary: Nonunion or Delayed Union of Acute Fracture
The evidence on the use of ESWT for the treatment of fractures or for fracture nonunion or delayed union includes systematic reviews, relatively small RCTs with methodologic limitations (e.g., heterogeneous outcomes and treatment protocols), and case series. The available evidence does not permit conclusions on the efficacy of ESWT in fracture nonunion, delayed union, or acute long bone fractures.

Spasticity
Clinical Context and Therapy Purpose

The purpose of ESWT is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as medication and intrathecal medication therapy, in patients with spasticity.

The question addressed in this evidence review is: Does the use of ESWT for spasticity improve the net health outcome?

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals with spasticity.

Interventions
The therapy being considered is ESWT.

Comparators
Comparators of interest are medication and intrathecal medication therapy.

Outcomes
The general outcomes of interest are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity.

Table 26. Outcomes of Interest for Individuals With Spasticity

Outcomes Details Timing
Symptoms
  • Modified Ashworth Scale for assessing resistance during soft-tissue stretching
  • Passive range of motion with goniometer
4 weeks to 3 months
Function outcomes
  • Brunnstrom Recovery Stage tool to assess motor recovery
Up to 5 weeks post-therapy


Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess longer term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews

Mihai et al. (2021) performed a meta-analysis of 7 RCTs to estimate the effect of ESWT on lower limb post-stroke spasticity at long-term follow-up (≥ 3 weeks after treatment).71 Compared with control, ESWT did not significantly improve Modified Ashworth Scale score at up to 12 weeks (7 studies; N = 146; standardized mean difference, 0.32; 95% CI, -0.01 to 0.65; I2 = 0%) or VAS score at up to 12 weeks (2 studies; N = 50; standardized mean difference, 0.35; 95% CI, -0.21 to 0.91; I2 = 0%), but did significantly improve passive range of motion at up to 12 weeks (3 studies; N = 69; standardized mean difference, 0.69; 95% CI, 0.20 to 1.19; I2 = 0%). Limitations of this meta-analysis include the small number of available studies, as well as small sample sizes.

Cabanas-Valdes et al. (2020) performed a meta-analysis of 16 RCTs evaluating the effectiveness of ESWT on spasticity of the upper limb in 764 patients who survived stroke.72 Compared with sham therapy, ESWT significantly improved the Modified Ashworth Scale scores (mean difference, -0.28; 95% CI, -0.54 to -0.03). The addition of ESWT to conventional physiotherapy also provided improvement in the Modified Ashworth Scale scores compared with conventional physiotherapy only (mean difference, -1.78; 95% CI, -2.02 to -1.53). Some limitations of this meta-analysis consist of studies with small sample sizes, unclear monitoring and follow-up procedures for interventions, and heterogeneity among the included studies.

Jia et al. (2020) conducted a meta-analysis of 8 RCTs evaluating the effectiveness of ESWT on post-stroke spasticity in 301 patients.73 At long-term follow-up, ESWT significantly reduced Modified Ashworth Scale scores (weighted mean difference, -0.36; 95% CI, -0.53 to -0.19; p < .001; I2 = 15%) compared with controls. Controls varied among included studies and comprised rehabilitation therapy, oral anti-spastic medications, sham therapy, botulinum toxin type A, stretching exercises, and/or physical therapy.

Kim et al. (2019) performed a meta-analysis of 5 RCTs evaluating the effectiveness of ESWT on reducing spasticity in patients with cerebral palsy.74 Compared with controls, ESWT significantly improved Modified Ashworth Scale scores (mean difference, -0.62; 95% CI, -1.05 to -0.18; p < .00001; I2 = 86%). Controls included placebo or no therapy.

Lee et al. (2014) conducted a meta-analysis of studies evaluating ESWT for patients with spasticity secondary to a brain injury.75 Studies included evaluated ESWT as sole therapy and reported pre- and post-intervention Modified Ashworth Scale scores. Five studies were selected, 4 examining spasticity in the ankle plantar flexor and 1 examining spasticity in the wrist and finger flexors; 3 studies evaluated post-stroke spasticity and 2 evaluated spasticity associated with cerebral palsy. Immediately post-ESWT, Modified Ashworth Scale scores improved significantly compared with baseline (standardized mean difference, -0.792; 95% CI, -1.001 to -0.583; p < .001). Four weeks post-ESWT, Modified Ashworth Scale scores continued to demonstrate significant improvements compared with baseline (standardized mean difference, -0.735; 95% CI, -0.951 to -0.519; p < .001). A strength of this meta-analysis was its use of a consistent and well-definable outcome measure. However, the Modified Ashworth Scale does not account for certain clinically important factors related to spasticity, including pain and functional impairment.

Randomized Controlled Trials
Vidal et al. (2020) performed a randomized, controlled, crossover trial that compared radial ESWT with botulinum toxin type A in reducing plantar flexor muscle spasticity in 68 patients with cerebral palsy.76 After 6 months, patients crossed over to the alternative treatment. Spasticity was evaluated using the Tardieu scale, which measures resistance to passive movement at slow and fast velocities with a goniometer. Treatment success was defined as improvement in dorsiflexion by ≥ 10° of the gastrocnemius muscle or the soleus muscle at 2 months after each intervention. In the first phase, success rates were similar between radial ESWT and botulinum toxin type A (45.7% and 36.4%, respectively; p = .469). Following crossover, significantly more patients achieved response with radial ESWT (39.4% vs. 11.4%; p = .011), which the authors attributed to a carry-over effect of radial ESWT from the first phase of treatment.

Li et al. (2020) assessed the effects of radial ESWT on agonist muscles (n = 27) and antagonist muscles (n = 30) compared with control (n = 25) in patients with stroke.77 All patients received conventional physical therapy for 3 weeks. Radial ESWT was administered at 4-day intervals for 5 consecutive treatments on either agonist or antagonist muscles. After treatment and 4 weeks of follow-up, the changes in the Modified Ashworth Scale scores were 24% for the control group, 74.1% for the agonist muscle group receiving radial ESWT, and 66.7% for the antagonist muscle group receiving radial ESWT, with statistical significance at p < .01 among the 3 groups. The authors concluded that radial ESWT is effective for spasticity after stroke and may have lasting effects up to 4 weeks after the treatment.

Wu et al. (2018) evaluated whether ESWT is noninferior to botulinum toxin type A for post-stroke upper limb spasticity among 42 patients with chronic stroke.78 At week 4, the change from baseline of the Modified Ashworth Scale score of the wrist flexors was -0.80 with ESWT and -0.9 with botulinum toxin type A; the difference between the 2 groups was within the prespecified margin of 0.5, meeting the noninferiority of ESWT to botulinum toxin type A.

The efficacy and safety of RSW in the treatment of spasticity in patients with cerebral palsy were examined in a small European RCT.79 As reported by Vidal et al. (2011), the 15 patients in this trial were divided into 3 groups (ESWT in a spastic muscle, ESWT in both spastic and antagonistic muscle, placebo ESWT) and treated in 3 weekly sessions. Spasticity was evaluated in the lower limbs by passive range of motion with a goniometer and in the upper limbs with the Ashworth Scale (0 [not spasticity] to 4 [severe spasticity]) at 1, 2, and 3 months post-treatment. The blinded evaluation showed significant differences between the ESWT and placebo groups for range of motion and Ashworth Scale score. For the group in which only the spastic muscle was treated, there was a 1-point improvement on the Ashworth Scale (reported significant vs. placebo); for the group with both spastic agonist and antagonist muscles treated, there was a 0.5-point improvement (p=not significant vs. placebo); and for the placebo group, there was no change. The significant improvements were maintained at 2 months posttreatment, but not at 3 months.

Section Summary: Spasticity
Limited RCT and systematic review evidence are available on the use of ESWT for spasticity, primarily in patients with stroke and cerebral palsy. Several studies have demonstrated improvements in spasticity measures after ESWT, but most studies have small sample sizes and a single center design. More well-designed controlled trials in larger populations are needed to determine whether ESWT leads to clinically meaningful improvements in pain and/or functional outcomes for spasticity.

Extracorporeal Shock Wave Treatment for Other Conditions
ESWT has been investigated in small studies for other conditions, including coccydynia in a case series of 2 patients80, and an RCT involving 34 patients,81 painful neuromas at amputation sites in an RCT assessing 30 subjects,82 and chronic distal biceps tendinopathy in a case-control study of 48 patients.83

The systematic review of ESWT for lower-extremity tendinopathies (previously described) by Mani-Babu et al. (2015) reviewed 2 studies of ESWT for greater trochanteric pain syndrome, including 1 quasi-RCT comparing ESWT with home therapy or corticosteroid injection and 1 case-control study comparing ESWT with placebo.49 ESWT was associated with some benefits compared with placebo or home therapy.

Summary of Evidence
For treatment of plantar fasciitis using ESWT, numerous RCTs were identified, including several well-designed, double-blind RCTs, that evaluated ESWT for the treatment of plantar fasciitis. Several systematic reviews and meta-analyses have been conducted, covering numerous studies, including studies that compared ESWT with corticosteroid injections. Pooled results were inconsistent. Some meta-analyses reported that ESWT reduced pain, while others reported nonsignificant pain reduction. Reasons for the differing results included lack of uniformity in the definitions of outcomes and heterogeneity in ESWT protocols (focused versus radial, low- versus high-intensity/energy, number and duration of shocks per treatment, number of treatments, and differing comparators). Some studies reported significant benefits in pain and functional improvement at 3 months, but it is not evident that the longer-term disease natural history is altered with ESWT. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have lateral epicondylitis who receive ESWT, the most direct evidence on the use of ESWT to treat lateral epicondylitis comes from multiple small RCTs, which did not consistently show outcome improvements beyond those seen in control groups. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The highest quality trials tend to show no benefit, and systematic reviews have generally concluded that the evidence does not support a treatment benefit over placebo or no treatment. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have shoulder tendinopathy who receive ESWT, a number of small RCTs, summarized in several systematic reviews and meta-analyses, comprise the evidence. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. Network meta-analyses focused on 3 outcomes: pain reduction, functional assessment, and change in calcific deposits. One network meta-analysis separated trials using H-FSW, low-energy focused shock wave, and RSW. It reported that the most effective treatment for pain reduction was ultrasound-guided needling, followed by RSW and H-FSW. The only treatment showing a benefit in functional outcomes was H-FSW. For the largest change in calcific deposits, the most effective treatment was ultrasound-guided needling followed by RSW and H-FSW. Although some trials have reported a benefit for pain and functional outcomes, particularly for high-energy ESWT for calcific tendinopathy, many available trials have been considered poor quality. More high-quality trials are needed to determine whether ESWT improves outcomes for shoulder tendinopathy. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have Achilles tendinopathy who receive ESWT, the evidence includes systematic reviews of RCTs and RCTs published after the systematic review. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. In the most recent systematic review, a pooled analysis found that ESWT reduced both short- and long-term pain compared with nonoperative treatments, although reviewers warned that results were inconsistent across the RCTs and that there was heterogeneity across patient populations and treatment protocols. An RCT published after the systematic review compared ESWT with hyaluronan injections and reported improvements in both treatment groups, although the improvements were significantly higher in the injection group. Another RCT found no difference in pain scores between low-energy ESWT and sham controls at week 24, but ESWT may provide short therapeutic effects at weeks 4 to 12. Another RCT found scores were statistically and clinically improved with ESWT compared with sham control at 1 month and 16 months on measures of pain and function. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have patellar tendinopathy who receive ESWT, the trials have reported inconsistent results and were heterogeneous in treatment protocols and lengths of follow-up. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have medial tibial stress syndrome who receive ESWT, the evidence includes a small RCT and a small nonrandomized cohort study. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The RCT showed no difference in self-reported pain measurements between study groups. The nonrandomized trial reported improvements with ESWT, but selection bias limited the strength of the conclusions. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have osteonecrosis of the femoral head who receive ESWT, the evidence includes systematic reviews of small, mostly nonrandomized studies. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. Many of the studies were low quality and lacked comparators. While most studies reported favorable outcomes with ESWT, limitations such as heterogeneity in the treatment protocols, patient populations, and lengths of follow-up make conclusions on the efficacy of ESWT for osteonecrosis uncertain. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have nonunion or delayed union who receive ESWT, the evidence includes systematic reviews, relatively small RCTs with methodologic limitations (e.g., heterogeneous outcomes and treatment protocols), and case series. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. The available evidence does not permit conclusions on the efficacy of ESWT in fracture nonunion, delayed union, or acute long bone fractures. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

For individuals who have spasticity who receive ESWT, the evidence includes RCTs and systematic reviews, primarily in patients with stroke and cerebral palsy. Several studies have demonstrated improvements in spasticity measures after ESWT, but most studies have small sample sizes and single center designs. Relevant outcomes are symptoms, functional outcomes, quality of life, medication use, and treatment-related morbidity. More well-designed controlled trials in larger populations are needed to determine whether ESWT leads to clinically meaningful improvements in pain and/or functional outcomes for spasticity. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.

The purpose of the following information is to provide reference material. Inclusion does not imply endorsement or alignment with the evidence review conclusions.

Practice Guidelines and Position Statements
Guidelines or position statements will be considered for inclusion in Supplemental Information if they were issued by, or jointly by, a U.S. professional society, an international society with U.S. representation, or National Institute for Health and Care Excellence (NICE). Priority will be given to guidelines that are informed by a systematic review, include strength of evidence ratings, and include a description of management of conflict of interest.

American College of Foot and Ankle Surgeons
In 2010, Thomas et al. revised guidelines on the treatment of heel pain on behalf of the American College of Foot and Ankle Surgeons.84 The guidelines identified extracorporeal shock wave therapy (ESWT) as a third-tier treatment modality in patients who have failed other interventions, including steroid injection. The guidelines recommended ESWT as a reasonable alternative to surgery. In an update to the American College of Foot and Ankle Surgeons clinical consensus statement, Schneider et al. stated that ESWT is a safe and effective treatment for plantar fasciitis.85

National Institute for Health and Care Excellence
The National Institute for Health and Care Excellence has published guidance on ESWT for a number of applications.

  • A guidance issued in 2003 stated that current evidence on safety and efficacy for treatment of calcific tendonitis of the shoulder "appears adequate to support the use of the procedure."86
  • The 2 guidance documents issued in 2009 stated that current evidence on the efficacy of ESWT for refractory tennis elbow and plantar fasciitis "is inconsistent."87,88
  • A guidance issued in 2011 stated that evidence on the efficacy and safety of ESWT for refractory greater trochanteric pain syndrome "is limited in quality and quantity."89
  • A guidance issued in 2016 stated that current evidence on the efficacy of ESWT for Achilles tendinopathy "is inconsistent and limited in quality and quantity."90

U.S. Preventive Services Task Force Recommendations
Not applicable

Ongoing and Unpublished Clinical Trials
Some currently ongoing and unpublished trials that might influence this review are listed in Table 27.

Table 27. Summary of Key Trials

NCT No. Trial Name Planned Enrollment Completion Date
Ongoing      
NCT03472989 The Effectiveness of Radial Extracorporeal Shockwave Therapy (rESWT), Sham- rESWT, Standardized Exercise Program or Usual Care for Patients With Plantar Fasciopathy. Study Protocol for a Double-blind, Randomized Sham-Controlled Trial 200 Jan 2023
NCT04332471 Treatment of Plantar Fasciitis With Radial Shockwave Therapy vs. Focused Shockwave Therapy: a Randomized Controlled Trial 114 Oct 2023
Unpublished      
NCT02668510 A Randomized Controlled Trial Comparing Extracorporeal Shock Wave Therapy with Platelet Rich Plasma versus Extracorporeal Shock Wave Therapy in a High Demand Cohort with Resistant Plantar Fasciitis 30 Mar 2019
NCT02546128 LEICSTES=LEICeSter Tendon Extracorporeal Shock Wave Studies Assessing the Benefits of the Addition of Extracorporeal Shock Wave Treatment to a Home-Rehabilitation Programme for Patients with Tendinopathy 720 Jun 2020
NCT03779919 The Therapeutic Effect of the Extracorporeal Shock Wave Therapy on Shoulder Calcific Tendinitis 90 May 2020
NCT03399968 Extracorporeal Shockwave Therapy (ESWT) in Patients Suffering From Complete Paraplegia at the Thoracic Level 25 May 2020
NCT04316026 Effectiveness of Shock Wave Therapy to Treat Upper Limb Spasticity in Hemiparetic Patients 48 Dec 2020
NCT02424084 Effects of Extracorporeal Shock Wave Therapy in Bone Microcirculation 80 Dec 2020
NCT: national clinical trial.

References: 

  1. Dizon JN, Gonzalez-Suarez C, Zamora MT, et al. Effectiveness of extracorporeal shock wave therapy in chronic plantar fasciitis: a meta-analysis. Am J Phys Med Rehabil. Jul 2013; 92(7): 606-20. PMID 23552334
  2. Aqil A, Siddiqui MR, Solan M, et al. Extracorporeal shock wave therapy is effective in treating chronic plantar fasciitis: a meta-analysis of RCTs. Clin Orthop Relat Res. Nov 2013; 471(11): 3645-52. PMID 23813184
  3. Zhiyun L, Tao J, Zengwu S. Meta-analysis of high-energy extracorporeal shock wave therapy in recalcitrant plantar fasciitis. Swiss Med Wkly. 2013; 143: w13825. PMID 23832373
  4. Yin MC, Ye J, Yao M, et al. Is extracorporeal shock wave therapy clinical efficacy for relief of chronic, recalcitrant plantar fasciitis? A systematic review and meta-analysis of randomized placebo or active-treatment controlled trials. Arch Phys Med Rehabil. Aug 2014; 95(8): 1585-93. PMID 24662810
  5. Lou J, Wang S, Liu S, et al. Effectiveness of Extracorporeal Shock Wave Therapy Without Local Anesthesia in Patients With Recalcitrant Plantar Fasciitis: A Meta-Analysis of Randomized Controlled Trials. Am J Phys Med Rehabil. Aug 2017; 96(8): 529-534. PMID 27977431
  6. Sun J, Gao F, Wang Y, et al. Extracorporeal shock wave therapy is effective in treating chronic plantar fasciitis: A meta-analysis of RCTs. Medicine (Baltimore). Apr 2017; 96(15): e6621. PMID 28403111
  7. Li S, Wang K, Sun H, et al. Clinical effects of extracorporeal shock-wave therapy and ultrasound-guided local corticosteroid injections for plantar fasciitis in adults: A meta-analysis of randomized controlled trials. Medicine (Baltimore). Dec 2018; 97(50): e13687. PMID 30558080
  8. Xiong Y, Wu Q, Mi B, et al. Comparison of efficacy of shock-wave therapy versus corticosteroids in plantar fasciitis: a meta-analysis of randomized controlled trials. Arch Orthop Trauma Surg. Apr 2019; 139(4): 529-536. PMID 30426211
  9. Gollwitzer H, Saxena A, DiDomenico LA, et al. Clinically relevant effectiveness of focused extracorporeal shock wave therapy in the treatment of chronic plantar fasciitis: a randomized, controlled multicenter study. J Bone Joint Surg Am. May 06 2015; 97(9): 701-8. PMID 25948515
  10. Gerdesmeyer L, Frey C, Vester J, et al. Radial extracorporeal shock wave therapy is safe and effective in the treatment of chronic recalcitrant plantar fasciitis: results of a confirmatory randomized placebo-controlled multicenter study. Am J Sports Med. Nov 2008; 36(11): 2100-9. PMID 18832341
  11. Food and Drug Administration. Summary of safety and effectiveness data: OrthospecTM Orthopedic ESWT. 2005; https://www.accessdata.fda.gov/cdrh_docs/pdf4/P040026b.pdf
  12. Food and Drug Administration. Summary of safety and effectiveness: Orbasone Pain Relief System. 2005; https://www.accessdata.fda.gov/cdrh_docs/pdf4/P040039b.pdf
  13. Radwan YA, Mansour AM, Badawy WS. Resistant plantar fasciopathy: shock wave versus endoscopic plantar fascial release. Int Orthop. Oct 2012; 36(10): 2147-56. PMID 22782376
  14. Eslamian F, Shakouri SK, Jahanjoo F, et al. Extra Corporeal Shock Wave Therapy Versus Local Corticosteroid Injection in the Treatment of Chronic Plantar Fasciitis, a Single Blinded Randomized Clinical Trial. Pain Med. Sep 2016; 17(9): 1722-31. PMID 27282594
  15. Lai TW, Ma HL, Lee MS, et al. Ultrasonography and clinical outcome comparison of extracorporeal shock wave therapy and corticosteroid injections for chronic plantar fasciitis: A randomized controlled trial. J Musculoskelet Neuronal Interact. Mar 01 2018; 18(1): 47-54. PMID 29504578
  16. Xu D, Jiang W, Huang D, et al. Comparison Between Extracorporeal Shock Wave Therapy and Local Corticosteroid Injection for Plantar Fasciitis. Foot Ankle Int. Feb 2020; 41(2): 200-205. PMID 31744313
  17. Cinar E, Saxena S, Uygur F. Combination Therapy Versus Exercise and Orthotic Support in the Management of Pain in Plantar Fasciitis: A Randomized Controlled Trial. Foot Ankle Int. Apr 2018; 39(4): 406-414. PMID 29327602
  18. Bahar-Ozdemir Y, Atan T. Effects of adjuvant low-dye Kinesio taping, adjuvant sham taping, or extracorporeal shockwave therapy alone in plantar fasciitis: A randomised double-blind controlled trial. Int J Clin Pract. May 2021; 75(5): e13993. PMID 33410228
  19. Buchbinder R, Green SE, Youd JM, et al. Shock wave therapy for lateral elbow pain. Cochrane Database Syst Rev. Oct 19 2005; (4): CD003524. PMID 16235324
  20. Dingemanse R, Randsdorp M, Koes BW, et al. Evidence for the effectiveness of electrophysical modalities for treatment of medial and lateral epicondylitis: a systematic review. Br J Sports Med. Jun 2014; 48(12): 957-65. PMID 23335238
  21. Zheng C, Zeng D, Chen J, et al. Effectiveness of extracorporeal shock wave therapy in patients with tennis elbow: A meta-analysis of randomized controlled trials. Medicine (Baltimore). Jul 24 2020; 99(30): e21189. PMID 32791694
  22. Yoon SY, Kim YW, Shin IS, et al. Does the Type of Extracorporeal Shock Therapy Influence Treatment Effectiveness in Lateral Epicondylitis? A Systematic Review and Meta-analysis. Clin Orthop Relat Res. Oct 2020; 478(10): 2324-2339. PMID 32332245
  23. Karanasios S, Tsamasiotis GK, Michopoulos K, et al. Clinical effectiveness of shockwave therapy in lateral elbow tendinopathy: systematic review and meta-analysis. Clin Rehabil. Oct 2021; 35(10): 1383-1398. PMID 33813913
  24. Yao G, Chen J, Duan Y, et al. Efficacy of Extracorporeal Shock Wave Therapy for Lateral Epicondylitis: A Systematic Review and Meta-Analysis. Biomed Res Int. 2020; 2020: 2064781. PMID 32309425
  25. Yan C, Xiong Y, Chen L, et al. A comparative study of the efficacy of ultrasonics and extracorporeal shock wave in the treatment of tennis elbow: a meta-analysis of randomized controlled trials. J Orthop Surg Res. Aug 06 2019; 14(1): 248. PMID 31387611
  26. Xiong Y, Xue H, Zhou W, et al. Shock-wave therapy versus corticosteroid injection on lateral epicondylitis: a meta-analysis of randomized controlled trials. Phys Sportsmed. Sep 2019; 47(3): 284-289. PMID 30951399
  27. Aldajah S, Alashram AR, Annino G, et al. Analgesic Effect of Extracorporeal Shock-Wave Therapy in Individuals with Lateral Epicondylitis: A Randomized Controlled Trial. J Funct Morphol Kinesiol. Mar 18 2022; 7(1). PMID 35323612
  28. Guler T, Yildirim P. Comparison of the efficacy of kinesiotaping and extracorporeal shock wave therapy in patients with newly diagnosed lateral epicondylitis: A prospective randomized trial. Niger J Clin Pract. May 2020; 23(5): 704-710. PMID 32367880
  29. Yang TH, Huang YC, Lau YC, et al. Efficacy of Radial Extracorporeal Shock Wave Therapy on Lateral Epicondylosis, and Changes in the Common Extensor Tendon Stiffness with Pretherapy and Posttherapy in Real-Time Sonoelastography: A Randomized Controlled Study. Am J Phys Med Rehabil. Feb 2017; 96(2): 93-100. PMID 27323324
  30. Capan N, Esmaeilzadeh S, Oral A, et al. Radial Extracorporeal Shock Wave Therapy Is Not More Effective Than Placebo in the Management of Lateral Epicondylitis: A Double-Blind, Randomized, Placebo-Controlled Trial. Am J Phys Med Rehabil. Jul 2016; 95(7): 495-506. PMID 26544854
  31. Lizis P. Analgesic effect of extracorporeal shock wave therapy versus ultrasound therapy in chronic tennis elbow. J Phys Ther Sci. Aug 2015; 27(8): 2563-7. PMID 26357440
  32. Gunduz R, Malas FU, Borman P, et al. Physical therapy, corticosteroid injection, and extracorporeal shock wave treatment in lateral epicondylitis. Clinical and ultrasonographical comparison. Clin Rheumatol. May 2012; 31(5): 807-12. PMID 22278162
  33. Staples MP, Forbes A, Ptasznik R, et al. A randomized controlled trial of extracorporeal shock wave therapy for lateral epicondylitis (tennis elbow). J Rheumatol. Oct 2008; 35(10): 2038-46. PMID 18792997
  34. Blue Cross and Blue Shield Association Technology Evaluation Center (TEC). Extracorporeal shock wave treatment for musculoskeletal indications TEC Assessments. 2003;Volume 18:Tab 5.
  35. Pettrone FA, McCall BR. Extracorporeal shock wave therapy without local anesthesia for chronic lateral epicondylitis. J Bone Joint Surg Am. Jun 2005; 87(6): 1297-304. PMID 15930540
  36. Wu YC, Tsai WC, Tu YK, et al. Comparative Effectiveness of Nonoperative Treatments for Chronic Calcific Tendinitis of the Shoulder: A Systematic Review and Network Meta-Analysis of Randomized Controlled Trials. Arch Phys Med Rehabil. Aug 2017; 98(8): 1678-1692.e6. PMID 28400182
  37. Arirachakaran A, Boonard M, Yamaphai S, et al. Extracorporeal shock wave therapy, ultrasound-guided percutaneous lavage, corticosteroid injection and combined treatment for the treatment of rotator cuff calcific tendinopathy: a network meta-analysis of RCTs. Eur J Orthop Surg Traumatol. Apr 2017; 27(3): 381-390. PMID 27554465
  38. Ioppolo F, Tattoli M, Di Sante L, et al. Clinical improvement and resorption of calcifications in calcific tendinitis of the shoulder after shock wave therapy at 6 months' follow-up: a systematic review and meta-analysis. Arch Phys Med Rehabil. Sep 2013; 94(9): 1699-706. PMID 23499780
  39. Yu H, Cote P, Shearer HM, et al. Effectiveness of passive physical modalities for shoulder pain: systematic review by the Ontario protocol for traffic injury management collaboration. Phys Ther. Mar 2015; 95(3): 306-18. PMID 25394425
  40. Verstraelen FU, In den Kleef NJ, Jansen L, et al. High-energy versus low-energy extracorporeal shock wave therapy for calcifying tendinitis of the shoulder: which is superior? A meta-analysis. Clin Orthop Relat Res. Sep 2014; 472(9): 2816-25. PMID 24872197
  41. Bannuru RR, Flavin NE, Vaysbrot E, et al. High-energy extracorporeal shock-wave therapy for treating chronic calcific tendinitis of the shoulder: a systematic review. Ann Intern Med. Apr 15 2014; 160(8): 542-9. PMID 24733195
  42. Huisstede BM, Gebremariam L, van der Sande R, et al. Evidence for effectiveness of Extracorporal Shock-Wave Therapy (ESWT) to treat calcific and non-calcific rotator cuff tendinosis--a systematic review. Man Ther. Oct 2011; 16(5): 419-33. PMID 21396877
  43. Kvalvaag E, Roe C, Engebretsen KB, et al. One year results of a randomized controlled trial on radial Extracorporeal Shock Wave Treatment, with predictors of pain, disability and return to work in patients with subacromial pain syndrome. Eur J Phys Rehabil Med. Jun 2018; 54(3): 341-350. PMID 28655271
  44. Kvalvaag E, Brox JI, Engebretsen KB, et al. Effectiveness of Radial Extracorporeal Shock Wave Therapy (rESWT) When Combined With Supervised Exercises in Patients With Subacromial Shoulder Pain: A Double-Masked, Randomized, Sham-Controlled Trial. Am J Sports Med. Sep 2017; 45(11): 2547-2554. PMID 28586628
  45. Kim EK, Kwak KI. Effect of extracorporeal shock wave therapy on the shoulder joint functional status of patients with calcific tendinitis. J Phys Ther Sci. Sep 2016; 28(9): 2522-2524. PMID 27799684
  46. Kim YS, Lee HJ, Kim YV, et al. Which method is more effective in treatment of calcific tendinitis in the shoulder? Prospective randomized comparison between ultrasound-guided needling and extracorporeal shock wave therapy. J Shoulder Elbow Surg. Nov 2014; 23(11): 1640-6. PMID 25219475
  47. Schofer MD, Hinrichs F, Peterlein CD, et al. High- versus low-energy extracorporeal shock wave therapy of rotator cuff tendinopathy: a prospective, randomised, controlled study. Acta Orthop Belg. Aug 2009; 75(4): 452-8. PMID 19774810
  48. Liu S, Zhai L, Shi Z, et al. Radial extracorporeal pressure pulse therapy for the primary long bicipital tenosynovitis a prospective randomized controlled study. Ultrasound Med Biol. May 2012; 38(5): 727-35. PMID 22425375
  49. Mani-Babu S, Morrissey D, Waugh C, et al. The effectiveness of extracorporeal shock wave therapy in lower limb tendinopathy: a systematic review. Am J Sports Med. Mar 2015; 43(3): 752-61. PMID 24817008
  50. Al-Abbad H, Simon JV. The effectiveness of extracorporeal shock wave therapy on chronic achilles tendinopathy: a systematic review. Foot Ankle Int. Jan 2013; 34(1): 33-41. PMID 23386759
  51. Costa ML, Shepstone L, Donell ST, et al. Shock wave therapy for chronic Achilles tendon pain: a randomized placebo-controlled trial. Clin Orthop Relat Res. Nov 2005; 440: 199-204. PMID 16239807
  52. Rasmussen S, Christensen M, Mathiesen I, et al. Shockwave therapy for chronic Achilles tendinopathy: a double-blind, randomized clinical trial of efficacy. Acta Orthop. Apr 2008; 79(2): 249-56. PMID 18484252
  53. Abdelkader NA, Helmy MNK, Fayaz NA, et al. Short- and Intermediate-Term Results of Extracorporeal Shockwave Therapy for Noninsertional Achilles Tendinopathy. Foot Ankle Int. Jun 2021; 42(6): 788-797. PMID 33451253
  54. Pinitkwamdee S, Laohajaroensombat S, Orapin J, et al. Effectiveness of Extracorporeal Shockwave Therapy in the Treatment of Chronic Insertional Achilles Tendinopathy. Foot Ankle Int. Apr 2020; 41(4): 403-410. PMID 31924120
  55. Lynen N, De Vroey T, Spiegel I, et al. Comparison of Peritendinous Hyaluronan Injections Versus Extracorporeal Shock Wave Therapy in the Treatment of Painful Achilles' Tendinopathy: A Randomized Clinical Efficacy and Safety Study. Arch Phys Med Rehabil. Jan 2017; 98(1): 64-71. PMID 27639439
  56. Liao CD, Xie GM, Tsauo JY, et al. Efficacy of extracorporeal shock wave therapy for knee tendinopathies and other soft tissue disorders: a meta-analysis of randomized controlled trials. BMC Musculoskelet Disord. Aug 02 2018; 19(1): 278. PMID 30068324
  57. van Leeuwen MT, Zwerver J, van den Akker-Scheek I. Extracorporeal shockwave therapy for patellar tendinopathy: a review of the literature. Br J Sports Med. Mar 2009; 43(3): 163-8. PMID 18718975
  58. Thijs KM, Zwerver J, Backx FJ, et al. Effectiveness of Shockwave Treatment Combined With Eccentric Training for Patellar Tendinopathy: A Double-Blinded Randomized Study. Clin J Sport Med. Mar 2017; 27(2): 89-96. PMID 27347857
  59. Smith J, Sellon JL. Comparing PRP injections with ESWT for athletes with chronic patellar tendinopathy. Clin J Sport Med. Jan 2014; 24(1): 88-9. PMID 24366015
  60. Newman P, Waddington G, Adams R. Shockwave treatment for medial tibial stress syndrome: A randomized double blind sham-controlled pilot trial. J Sci Med Sport. Mar 2017; 20(3): 220-224. PMID 27640922
  61. Rompe JD, Cacchio A, Furia JP, et al. Low-energy extracorporeal shock wave therapy as a treatment for medial tibial stress syndrome. Am J Sports Med. Jan 2010; 38(1): 125-32. PMID 19776340
  62. Barnes M. Letter to the editor. "Low-energy extracorporeal shock wave therapy as a treatment for medial tibial stress syndrome". Am J Sports Med. Nov 2010; 38(11): NP1; author reply NP1-2. PMID 20971968
  63. Hao Y, Guo H, Xu Z, et al. Meta-analysis of the potential role of extracorporeal shockwave therapy in osteonecrosis of the femoral head. J Orthop Surg Res. Jul 03 2018; 13(1): 166. PMID 29970103
  64. Zhang Q, Liu L, Sun W, et al. Extracorporeal shockwave therapy in osteonecrosis of femoral head: A systematic review of now available clinical evidences. Medicine (Baltimore). Jan 2017; 96(4): e5897. PMID 28121934
  65. Alves EM, Angrisani AT, Santiago MB. The use of extracorporeal shock waves in the treatment of osteonecrosis of the femoral head: a systematic review. Clin Rheumatol. Nov 2009; 28(11): 1247-51. PMID 19609482
  66. Sansone V, Ravier D, Pascale V, et al. Extracorporeal Shockwave Therapy in the Treatment of Nonunion in Long Bones: A Systematic Review and Meta-Analysis. J Clin Med. Apr 01 2022; 11(7). PMID 35407583
  67. Zelle BA, Gollwitzer H, Zlowodzki M, et al. Extracorporeal shock wave therapy: current evidence. J Orthop Trauma. Mar 2010; 24 Suppl 1: S66-70. PMID 20182240
  68. Wang CJ, Liu HC, Fu TH. The effects of extracorporeal shockwave on acute high-energy long bone fractures of the lower extremity. Arch Orthop Trauma Surg. Feb 2007; 127(2): 137-42. PMID 17053946
  69. Cacchio A, Giordano L, Colafarina O, et al. Extracorporeal shock-wave therapy compared with surgery for hypertrophic long-bone nonunions. J Bone Joint Surg Am. Nov 2009; 91(11): 2589-97. PMID 19884432
  70. Zhai L, Ma XL, Jiang C, et al. Human autologous mesenchymal stem cells with extracorporeal shock wave therapy for nonunion of long bones. Indian J Orthop. Sep 2016; 50(5): 543-550. PMID 27746499
  71. Mihai EE, Dumitru L, Mihai IV, et al. Long-Term Efficacy of Extracorporeal Shock Wave Therapy on Lower Limb Post-Stroke Spasticity: A Systematic Review and Meta-Analysis of Randomized Controlled Trials. J Clin Med. Dec 29 2020; 10(1). PMID 33383655
  72. Cabanas-Valdes R, Serra-Llobet P, Rodriguez-Rubio PR, et al. The effectiveness of extracorporeal shock wave therapy for improving upper limb spasticity and functionality in stroke patients: a systematic review and meta-analysis. Clin Rehabil. Sep 2020; 34(9): 1141-1156. PMID 32513019
  73. Jia G, Ma J, Wang S, et al. Long-term Effects of Extracorporeal Shock Wave Therapy on Poststroke Spasticity: A Meta-analysis of Randomized Controlled Trials. J Stroke Cerebrovasc Dis. Mar 2020; 29(3): 104591. PMID 31899073
  74. Kim HJ, Park JW, Nam K. Effect of extracorporeal shockwave therapy on muscle spasticity in patients with cerebral palsy: meta-analysis and systematic review. Eur J Phys Rehabil Med. Dec 2019; 55(6): 761-771. PMID 31615195
  75. Lee JY, Kim SN, Lee IS, et al. Effects of Extracorporeal Shock Wave Therapy on Spasticity in Patients after Brain Injury: A Meta-analysis. J Phys Ther Sci. Oct 2014; 26(10): 1641-7. PMID 25364134
  76. Vidal X, Marti-Fabregas J, Canet O, et al. Efficacy of radial extracorporeal shock wave therapy compared with botulinum toxin type A injection in treatment of lower extremity spasticity in subjects with cerebral palsy: A randomized, controlled, cross-over study. J Rehabil Med. Jun 30 2020; 52(6): jrm00076. PMID 32556354
  77. Li G, Yuan W, Liu G, et al. Effects of radial extracorporeal shockwave therapy on spasticity of upper-limb agonist/antagonist muscles in patients affected by stroke: a randomized, single-blind clinical trial. Age Ageing. Feb 27 2020; 49(2): 246-252. PMID 31846499
  78. Wu YT, Yu HK, Chen LR, et al. Extracorporeal Shock Waves Versus Botulinum Toxin Type A in the Treatment of Poststroke Upper Limb Spasticity: A Randomized Noninferiority Trial. Arch Phys Med Rehabil. Nov 2018; 99(11): 2143-2150. PMID 30392753
  79. Vidal X, Morral A, Costa L, et al. Radial extracorporeal shock wave therapy (rESWT) in the treatment of spasticity in cerebral palsy: a randomized, placebo-controlled clinical trial. NeuroRehabilitation. 2011; 29(4): 413-9. PMID 22207070
  80. Marwan Y, Husain W, Alhajii W, et al. Extracorporeal shock wave therapy relieved pain in patients with coccydynia: a report of two cases. Spine J. Jan 2014; 14(1): e1-4. PMID 24094989
  81. Ahadi T, Hosseinverdi S, Raissi G, et al. Comparison of Extracorporeal Shockwave Therapy and Blind Steroid Injection in Patients With Coccydynia: A Randomized Clinical Trial. Am J Phys Med Rehabil. May 01 2022; 101(5): 417-422. PMID 34091468
  82. Jung YJ, Park WY, Jeon JH, et al. Outcomes of ultrasound-guided extracorporeal shock wave therapy for painful stump neuroma. Ann Rehabil Med. Aug 2014; 38(4): 523-33. PMID 25229031
  83. Furia JP, Rompe JD, Maffulli N, et al. Radial Extracorporeal Shock Wave Therapy Is Effective and Safe in Chronic Distal Biceps Tendinopathy. Clin J Sport Med. Sep 2017; 27(5): 430-437. PMID 27893487
  84. Thomas JL, Christensen JC, Kravitz SR, et al. The diagnosis and treatment of heel pain: a clinical practice guideline-revision 2010. J Foot Ankle Surg. May-Jun 2010; 49(3 Suppl): S1-19. PMID 20439021
  85. Schneider HP, Baca JM, Carpenter BB, et al. American College of Foot and Ankle Surgeons Clinical Consensus Statement: Diagnosis and Treatment of Adult Acquired Infracalcaneal Heel Pain. J Foot Ankle Surg. Mar 2018; 57(2): 370-381. PMID 29284574
  86. National Institute for Health and Care Excellence (NICE). Extracorporeal shockwave lithotripsy for calcific tendonitis (tendonopathy) of the shoulder [IPG21]. 2003; https://www.nice.org.uk/guidance/ipg21
  87. National Institute for Health and Care Excellence (NICE). Extracorporeal shockwave therapy for refractory plantar fasciitis: guidance [IPG311]. 2009; https://www.nice.org.uk/guidance/ipg311
  88. National Institute for Health and Care Excellence (NICE). Extracorporeal shockwave therapy for refractory tennis elbow [IPG313]. 2009; https://www.nice.org.uk/guidance/ipg313
  89. National Institute for Health and Care Excellence (NICE). Extracorporeal shockwave therapy for refractory greater trochanteric pain syndrome [IPG376]. 2011; https://www.nice.org.uk/guidance/ipg376
  90. National Institute for Health and Care Excellence (NICE). Extracorporeal shockwave therapy for Achilles tendinopathy [IPG571]. 2016; https://www.nice.org.uk/guidance/ipg571

 Coding Section   

Codes Number Description
CPT 28890 Extracorporeal shock wave, high energy, performed by a physician, requiring anesthesia other than local, including ultrasound guidance, involving the plantar fascia
  0101T Extracorporeal shock wave therapy; involving musculoskeletal system, not otherwise specified (revised eff 01/01/2022)
  0102T Extracorporeal shock wave therapy; performed by a physician, requiring anesthesia other than local, involving lateral humeral epicondyle (revised eff 01/01/2022)
  20999 Unlisted procedure, musculoskeletal system, general. This code would be used for low-energy or radial ESWT.
ICD-10-CM   Investigational for all relevant diagnosis codes
  M72.2 Plantar fascial fibromatosis (plantar fasciitis)
  M75.20-M75.22 Bicipital tendinitis code range
  M75.30-M75.32 Calcific tendinitis of shoulder code range
  M77.00-M77.02 Medial epicondylitis code range
  M77.10-M77.12 Lateral epicondylitis code range
  M84.311A-M84.38S Stress fracture code range
  M87.051-M87.059 Idiopathic aseptic necrosis of femur code range
  S32.2xxK-S32.9xxK;S42.00xK-S42.92xK; S49.00xK-S49.199K;S52.00xK-S52.92xN;S59.00xK-S59.299K; S62.00xK-S62.92xK; S72.00xK-S72.92xN; S79.00xK-S79.199K; S82.00xK-S82.92xN; S89.00xK-S89.399K; S92.00xK-S92.919K Fracture nonunion codes for the appendicular skeleton – 7th digit “K” is subsequent encounter for nonunion (in forearm, femur, lower leg & ankle fractures 7th digits “M” and “N” are also nonunion for certain types of open fractures – in fractures of the shoulder, humerus, wrist, hand and foot there isn’t separation of open vs. closed nonunions).
ICD-10-PCS   ICD-10-PCS codes are only used for inpatient services
  6A930ZZ, 6A931ZZ Extracorporeal therapies, physiological systems, shock wave therapy, musculoskeletal system, code by duration (single or multiple)
Type of service Medicine  
Place of service Outpatient/Inpatient  

Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive.  

This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies, and accredited national guidelines.

"Current Procedural Terminology © American Medical Association. All Rights Reserved" 

History From 2024 Forward     

01012024  NEW POLICY

05/17/2024 Annual review, no change to policy intent

Complementary Content
${loading}