Extracorporeal shock wave therapy in patients with plantar fasciitis. A randomized, placebo-controlled trial with ultrasonographic and subjective outcome assessments.

BACKGROUND AND AIM: Results of previous studies have been conflicting on the efficacy of extracorporeal shock wave therapy (ESWT) in the treatment of plantar fasciitis. We evaluated the effects of ESWT on plantar fasciitis in terms of ultrasonographic and subjective evaluations.
MATERIALS AND METHODS: In this randomized placebo-controlled trial, patients with plantar fasciitis were assigned to receive ESWT (4000 shock waves/session of 0.2 mJ/mm(2)) in 3 sessions at weekly intervals) or sham therapy (n = 20 in each group). Outcomes were documented by the ultrasonographic appearance of the aponeurosis and by patients' pain scores, performed at baseline and 12 weeks after completion of the therapy.
RESULTS: The two groups were similar in baseline characteristics. Over the study period, plantar fascia thickness significantly reduced in the ESWT group (4.1 ± 1.3 to 3.6 ± 1.2 mm, P < 0.001), but slightly increased in the sham group (4.1 ± 0.8 to 4.5 ± 0.9 mm, P = 0.03). Both groups showed significant pain improvement over the course of the study (P < 0.001), though pain scores were significantly more reduced in the ESWT than the sham group (-4.2 ± 2.9 vs. -2.7 ± 1.8, P = 0.049).
CONCLUSIONS: Extracorporeal shock wave therapy contributes to healing and pain reduction in plantar fasciitis and ultrasound imaging is able to depict the morphologic changes related to plantar fasciitis as a result of this therapy.

RCT Entities:   Population Interventions Outcomes

INTRODUCTION

Plantar fasciitis is one of the most common causes of foot pain in adults, with the peak incidence occurs between ages 40 and 60 years in the general population.[1] In up to a third of the cases it may be bilateral, and heel spurs often coexist, but whether they have a causal role in the etiology of the disease is still unknown.[23] The etiology of plantar fasciitis is multifactorial. Suggested risk factors include those conditions that increase the pressure at the plantar surface such as obesity, prolonged standing, flat feet, and reduced ankle dorsiflexion.[4] The high incidence in runners suggests that, at least in this population, plantar fasciitis might be due to an injury by repetitive microtrauma.[56]

The diagnosis of plantar fasciitis is clinical and local point tenderness is the hallmark for diagnosis, while laboratory testing is not helpful nor necessary for the diagnosis.[7] However, radiography is required to rule out other disorders, especially calcaneal stress fractures. Ultrasonography of the foot is also useful in diagnosis and treatment follow-ups with indicating plantar fascial thickening, hypoechogenicity at the insertion upon the calcaneus, and features of edema including blurring of the boundary between the fascia and surrounding tissues and decreased echogenicity.[8-10] Diagnostic accuracy of ultrasonography for the diagnosis of plantar fasciitis is acceptable (sensitivity 80% and specificity 88.5%),[11] and Doppler ultrasound can improve the accuracy and provide additional information on local hyperemia as well.[12]

The treatment of plantar fasciitis is primarily conservative, initially with rest and icing to give pain relief. Non-steroidal anti-inflammatory drugs (NSAIDs), local injection of steroids, and electrotherapy and physiotherapy with stretching exercises are also used.[7] In about 10% of the cases who do not respond to such treatments, surgical intervention is suggested.[13]

Extracorporeal shock wave therapy (ESWT) is a noninvasive procedure used in rehabilitation therapy that is recently being applied in the treatment of tendinopathies and also plantar fasciitis.[14-20] In ESWT, shock waves are generated by means of electrohydraulic, piezoelectric, and electromagnetic methods. There are some possible mechanisms mentioned for the efficacy of shock wave therapy. The transmitted waves may have effects on physiology of pain receptor,[21] and also, through microtrauma, they may initiate healing processes by the release of molecular agents and growth factors leading to neovascularization.[22]

Despite increasing use of ESWT in the treatment of plantar fasciitis, few well-controlled trials have been conducted to approve its efficacy with conflicting results.[142023] Therefore, we conducted a randomized, placebo-controlled trial to evaluate the efficacy of ESWT in the management of plantar fasciitis. The outcome was documented by the ultrasonographic appearance of the aponeurosis, as well as by subjective pain scores.

MATERIALS AND METHODS

Patients and settings

This randomized, placebo-controlled trial was conducted from Jun 2010 to Jul 2011 on adult patients with a clinical diagnosis of plantar fasciitis referred to the outpatient clinics of Alzahra University Hospital, Isfahan (IRAN). Patients with plantar heel pain for at least three months and point tenderness at or near the medial calcaneal insertion of the plantar fascia, who had no satisfactory response to common treatments such as NSAIDs and physiotherapy were included. Patients with diabetes, additional foot or ankle pathology (including instability, arthritis, generalized polyarthritis, diffuse heel pad tenderness), local dermatological problems, neurological abnormalities, history of recent trauma or foot surgery, connective tissue or infectious diseases, malignancy, or vasculitis and pregnant patients or those who received anticoagulant therapy in the preceding six months were not included. Considering type I error (alpha) = 0.05 and study power = 80%, with minimum expected difference of 1 score in 11-point scale for pain assessment, the sample size was calculated as at least 20 patients in each group. The study protocol was approved by the Ethics Committee of Isfahan University of Medical Sciences and informed consent was obtained from all patients. Also, the trial was registered in Iranian Registry of Clinical Trials IRCT2012072910439N1.

Intervention

Patients were randomly assigned (by a random table list) to receive ESWT (n = 20) or identical sham therapy as the placebo (n = 20) by weekly interval for three consecutive weeks. We used the site of maximum local tenderness as the target area for shock waves with Duolith SD1 shock wave machine. Patient in the intervention group received 2000 focused shock waves and 2000 radial pulses in three sessions (4000 shock waves/session of 0.2 mJ/mm2) at weekly intervals. ESWT dose and treatment schedule were based on the previous studies.[1420232425] For the placebo group sham treatment was done where standard contact of radial and focus probe with the skin was provided. The machine makes a noise with every shock wave delivered and, in order to enhance the sham design, minimal energy pulses (0.04 mJ/mm2) were generated.[2324]

Assessments

Ultrasonographic evaluation was carried out before and after the therapy. Ultrasound was performed by the same radiologist, using a 10 MHz linear array transducer. Both heels of the participants were scanned in two-dimensional (2D) real-time B mode. We took care to obtain comparable views of the contralateral sides. Sagital imaging of the plantar fascia was performed with the transducer aligned along the longitudinal axis of the aponeurosis. Quantitative evaluation of plantar fasciitis was achieved by measurement of its thickness about 2 cm distal of the medial calcaneal tuberosity. In addition, qualitative assessment including echogenic appearance of plantar fascia and its fibrillary pattern was done. For subjective pain assessment, all subjects completed a numerical rating scale (NRS) for foot pain (from 0 = no pain to 10 = the most severe pain) during the daily activity.

All assessments (pain and ultrasonographic evaluation) were repeated three months after completion of the therapy. Along this time, conservative managements including stretching exercise, using NSAIDs, and heel pad were considered in both groups.

Statistical analysis

Data were analyzed with SPSS software for windows, version 16.0 (SPSS Inc., Chicago IL., USA). A paired samples t-test was used to ascertain significant changes in both plantar fascia thickness and subjective sub-calcaneal pain over the experimental period, and an independent t-test was used for detecting any significant differences in these two parameters between the two groups. The Pearson correlation coefficient was employed to investigate the relationship between continuous variables. A result was considered to be statistically significant if the observed significance level (P value) was <0.05.

RESULTS

During the study period, 40 patients with plantar fasciitis were enrolled and completed the study [Figure 1]. Demographic characteristics of the patients are outlined in Table 1. There was no significant difference between the two groups in baseline characteristics.

Figure 1

Participants’ flow diagram

Table 1

Demographic characteristics of the two groups

Data regarding plantar fascia thickness and pain scores are presented in Table 2. In two patients who had severe pain, abnormal fluid collection was seen surrounding the plantar fascia. Initially there were no significant differences between the mean plantar fascia thickness of the two groups (P = 0.95). After treatment, the mean plantar fascia thickness was significantly decreased in the ESWT group (P < 0.001), while it was slightly increased in the placebo group (P = 0.03), Figure 2.

Table 2

Comparison of pain scores and plantar fascia thickness before and after the study within and between the two groups

Figure 2

Post-treatment plantar fascia thickness in the placebo (a) and ESWT (b) groups

Regarding the NRS pain scores, no significant difference were observed between the pain scores of the two groups at baseline (P = 0.59), but after three months follow-up, pain scores was significantly lower in the ESWT group than in the placebo group (P = 0.04). Both groups showed significant pain improvement over the course of the study, although reduction of NRS score in the intervention group was significantly greater than in the placebo group (-4.2 ± 2.9 vs. -2.7 ± 1.8, P = 0.049).

To find factors associated with better response to ESWT, we splatted the groups and analyzed data from the ESWT group. Results showed a significant inverse correlation between plantar fascia thickness change and BMI (r = -0.597, P = 0.005). The association between change in pain score and change in plantar fascia thickness was not significant (r = 0.365, P = 0.114).

DISCUSSION

There are various options for the treatment of plantar fasciitis, but a lot of them are not satisfactory effective and some of them are associated with risks.[7] For example, glucocorticoid injections can provide temporary pain relief; however, repeated injections may cause atrophy of the heel pad,[26] and even plantar fascia rupture.[27] Surgical interventions, on the other hand, can alter the biomechanics of the foot[28] and prolonged the healing process.[29] Accordingly, ESWT has been proposed as a therapeutic option for plantar fasciitis, as well as some other musculoskeletal complaints.[18] During the past decade, ESWT has become increasingly used worldwide, and based on some well-controlled trials; recently it was approved by the FDA for treatment of plantar fasciitis in the USA.[30] A placebo-controlled multicentre trial of ESWT by Haake and colleagues in subjects with chronic plantar fasciitis indicated superior improvement in the active treatment than the placebo group.[20] In another randomized trial, Rompe et al., assigned patients to stretching or low energy shock wave therapy and at the 2-month assessment authors found a greater mean change in Foot Function Index cumulative score and a higher patient satisfaction for those who were treated with stretching. These results were stable at the 4-month follow-up, but no difference found between the groups at the 15-month follow-up, though use of NSAIDs was more common among patients treated with shock wave therapy.[31] In another placebo-controlled trial by Speed et al., on adults with plantar fasciitis, no beneficial effects were observed for shock wave therapy (0.12 mJ/mm2) versus the sham placebo over a 6-month period.[23] These results, however, might be due to the moderate dose ESWT effects comparable with placebo effects. The differences between various studies in the efficacy of ESWT in plantar fasciitis may be related to a number of factors including differences in study populations, heterogeneity of treatment parameters such as shock wave intensity, geometry of the shock wave focus, focal energy, different placebos and different machine design. Use of different outcome measures can also prevent direct comparisons between studies.

There is no consensus on the appropriate ESWT dosage and treatment parameters remain empirical. An emphasis is placed upon the use of a feasible regime with minimal side effects. Although the technique is widely reported to be safe, there is a potential for hemorrhage and local soft tissue damage through cavitations.[32] This appears to be more likely with the high doses. For this reason, a moderate radial and focus dose regime using an electromagnetic generator was chosen in our study, which avoided the need for administration of local anesthetic or significant post- treatment rest. Significant adverse effects were not noted in our study, in agreement with the experience of others[33] and the results indicated that moderate dose of ESWT has significant beneficial effects over placebo. Although, pain intensity in the sham group was significantly reduced over the experimental period, ultrasonograghy showed slightly increase in plantar fascia thickness. These results indicate that other factors can lead to false impressions of a placebo effect, such as spontaneous improvement and fluctuation of symptoms.

CONCLUSIONS

In summary, while ultrasound imaging is able to depict the morphologic changes related to plantar fasciitis, ESWT can contribute to healing and pain reduction in plantar fasciitis. Further studies are required to find the mechanisms of action of ESWT in the treatment of plantar fasciitis.