What Is the Evidence for Rest, Ice, Compression, and Elevation Therapy in the Treatment of Ankle Sprains in Adults?

Definitions

Literature Search Strategy

Two independent researchers (M.P.J.v.d.B., L.W.) performed a search in the following databases: MEDLINE (from 1966 to July 2010), Cochrane Clinical Trial Register (from 1988 to August 2010), CINAHL (from 1988 to August 2010), and EMBASE (from January 1988 to August 2010) to identify all studies concerning the application of at least 1 of the components of RICE therapy for an acute ankle sprain. The search terms used were ankle injuries, rupture, ankle joint, lateral ligaments, sprains, randomized clinical trial, random allocation, placebo, rest, immobilization, ice, cold, therapy, cryotherapy, cooling, compression, and elevation (Table 1). References listed in the retrieved publications also were examined manually to identify additional studies. Papers in English were considered for this review, and papers in other languages were considered if translation was available. Abstracts from scientific meetings, unpublished reports, ongoing studies, and review articles were excluded.

Table 1A.  PubMed and MEDLINE Search Strategy for Rest

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Selection Criteria

Included Studies

Selection of Trials.

From the title and abstract, we reviewed the literature searches to identify potentially relevant articles. The full article was retrieved when the title, key words, or abstract revealed insufficient information to determine appropriateness for inclusion. For each selected article, the full article was retrieved for final assessment. All identified studies were assessed independently by 2 reviewers (M.P.J.v.d.B. and L.W.) for inclusion using the criteria described. Disagreements between reviewers were resolved by discussion and with arbitration by a third reviewer (C.N.v.D.) when differences remained.

After deduction of the overlaps among the different databases, evaluation of the abstracts, and contact with some authors, 24 potentially eligible trials remained. The full texts of these articles were retrieved and thoroughly assessed as described. This resulted in the inclusion of 11 trials involving 868 patients (Tables 2 and 3). The most common reason for exclusion was that the researchers did not describe a well-defined control group without the intervention of interest but described a control group with another form of intervention. The study by Tsang et al³² was excluded because the follow-up was too short. The publication dates spanned 34 years; Basur et al³³ was the earliest report, and Bleakley et al³⁴ was the most recent publication. Six studies were performed in Europe, 3 in North America, and 1 each in Australia and New Zealand (Tables 2 and 3).

Table 1B.  PubMed and MEDLINE Search Strategy for Ice

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Table 1C.  PubMed and MEDLINE Search Strategy for Compression

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Different inclusion criteria, durations of treatments, outcome measurements, and timing of outcome measurements among the trials prohibited pooling of the results and statistical comparison among the included trials.

The searches yielded 101 articles for the intervention rest. Full texts of 8 articles were retrieved for further analysis, and 5 articles were included in this review.^1,31,35,36 For the intervention ice, the searches yielded 28 articles. Full texts of 11 articles were retrieved for further analysis, and 5 articles were included in this review.^33,37–40 The searches yielded 68 articles for the intervention compression. Full texts of 5 articles were retrieved for further analysis, and 1 article was included in this review.⁴¹ For the intervention elevation, the computerized searches yielded 25 articles. Full text of 1 article was retrieved for further analysis. However, no articles were included in this review concerning the comparison of elevation and no elevation in the treatment of acute ankle sprains.

Data Extraction

The data from the included studies that could be meta-analyzed were extracted by 1 reviewer (M.P.J.v.) using a prepiloted data-extraction tool and were verified by the second reviewer (L.W.). Disagreements were resolved in a consensus meeting or, if necessary, by third-party adjudication (G.M.M.J.K.). Articles were not blinded for author, affiliation, or source.^42–44 If necessary and possible, the authors were contacted for additional information.

Methodologic Quality

Two independent reviewers (P.A.A.S. and L.B.) obtained the full text of all potentially eligible articles for independent methodologic assessment. Any disagreement was resolved by consensus or third-party adjudication (M.P.J.v.). Articles were not blinded for author, affiliation, or source.^42–44 The assessment was performed using a piloted, participant-specific modification of the generic evaluation tool used by the Cochrane Musculoskeletal Injuries Group.⁴⁵ The scoring scheme for the 10 items of internal and external validity covered by this tool is given in Table 4.

Table 1D.  PubMed and MEDLINE Search Strategy for Elevation

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Quantitative Analysis

If possible, the results of comparable studies were pooled using fixed- or random-effects models where appropriate. Individual and pooled statistics were reported as relative risks with 95% confidence intervals (CIs) for dichotomous outcomes and weighted mean difference or, where different scales had been used, standardized mean differences and 95% CIs for continuous outcomes measurements. Heterogeneity among trials was analyzed using a χ² test. If possible, sensitivity analyses were conducted to assess the effects of excluding the trials in which the quasi-randomization method was used.

Qualitative Analysis

Because the trial results were heterogeneous, the results were analyzed according to best evidence analysis using a rating system with levels of evidence based on the overall quality and the outcomes of the studies used.⁴⁶ Strong evidence was defined as generally consistent findings in multiple high-quality randomized controlled trials (RCTs). Moderate evidence was defined as generally consistent findings in 1 high-quality RCT and 1 or more low-quality RCTs. Limited evidence was defined as only 1 RCT (either high or low quality) or generally consistent findings in controlled clinical trials. No evidence was defined as no controlled clinical trials or no RCTs.

Rest

Green et al³⁵ showed that anteroposterior manipulation and RICE resulted in greater improvement in range of movement than the application of RICE alone for all measures taken after each of the treatment sessions (P < .01). Greater increases were found in stride speed within the first and third treatment sessions in the RICE and manipulation group than in the RICE-only group (P < .05). Karlsson et al³¹ reported a shorter sick leave (P < .05) and a faster return to sport participation (P < .05) after early functional treatment than after conventional treatment at a mean follow-up of 18 months.

The methodologic quality and the quality of reporting data were very poor in the trial published by Brooks et al.¹ Based on the data, they concluded that early mobilization with or without physiotherapy offered the most rapid return to functional activity. Patients who had their ankles immobilized required more days missed from work and more visits to a clinic for follow-up.

Eisenhart et al³⁶ reported that standard treatment (RICE with or without pain medications) and standard treatment with additional osteopathic manipulative treatment led to improvement at 1-week follow-up in patients with unilateral ankle sprains. Range of motion improved more in patients in the osteopathic manipulative treatment study group (−5.25° ± 8.8°) than in the patients in the standard treatment group (−13.5° ± 12.4°) when the injured and uninjured sides were compared (P = .01).

Bleakley et al^34,47 showed that the exercise group had better scores than did a standard intervention group on the Lower Extremity Functional Scale (P = .008); this finding was significant at both week 1 (baseline-adjusted difference in treatment = 5.28, 98.75% CI = 0.31, 10.26, P = .008) and week 2 (baseline-adjusted difference in treatment = 4.92, 98.75% CI = 0.27, 9.57, P = .008). Activity level was higher in the exercise group than in the standard intervention group as measured by time spent walking (1.2 hours [95% CI= 0.9, 1.4] and 1.6 hours [95% CI = 1.3, 1.9], respectively), step count (5621 steps [95% CI = 4399, 6843] and 7886 steps [95% CI = 6357, 9416], respectively), and time spent in light-intensity activity (53 minutes [95% CI = 44, 60] and 76 minutes [95% CI = 58, 95], respectively).

Ice

Sloan et al³⁷ compared a cooling anklet used with 45° of elevation and a dummy anklet used without elevation. The cooling anklet had a skin pressure of 30 mm Hg, produced a skin temperature ranging from 15°C to 29°C, and was worn for 30 minutes each day for 7 days. The authors observed no differences in outcome measures (pain, swelling, ROM, ability to bear weight) after a single application of cold, elevation, and compression in the accident and emergency department when a background therapy of nonsteroidal anti-inflammatory medication was given.

Laba³⁸ did not show differences in pain, swelling, or ankle function between ice therapy (ice-pack application = 20 minutes) and no ice therapy. Coté et al³⁹ observed that ankle sprains treated with cold therapy (cold immersion cylinder at 50°F–60°F [10°C–16°C] for 20 minutes 3 times in 5 days) had less edema than those treated with heat therapy (3.3 ± 11.3 mL and 25.3 ± 19.5 mL, respectively) (P < .05).

Basur et al³³ showed that cryotherapy (Cryogel [3M, Berkshire, United Kingdom] during 48 hours) and bandaging resulted in faster reduction of edema, pain, and disability in ankle sprains and reduced the period of disability when compared with bandaging alone. However, this study had low methodologic and reporting qualities. These authors did not mention α levels.

Hocutt et al⁴⁰ showed that cryotherapy (ice whirlpool at 40°F–50°F [4°C–10°C] for 12 to 20 minutes, 1 to 3 times per day, for 3 days) started within 36 hours after trauma was more effective than heat therapy (heating pad for 15 minutes, 1 to 3 times per day, for a minimum of 3 days) for recovery in terms of pain and return to full activity (P < .05). The group using cryotherapy returned to full activity at 13.2 days, and the group using heat therapy returned at 33.3 days.

Compression

Airaksinen et al⁴¹ reported the results of using intermittent pneumatic compression (IPC), which involved alternating between 30 seconds of inflation and 30 seconds of deflation of the device over 30 minutes. The treatment was applied once each day for 5 days. The authors observed differences in edema (P < .001), ROM (P < .001), pain (P < .001), and ankle function (P < .01) at 1 and 4 weeks after treatment with IPC and elastic bandage compared with pressure-bandage treatment only.

Methodologic Quality

The methodologic quality assessment comprised 10 items, each with a maximum of 2 points (Table 5). The average quality score was 8. Eight of the 10 selected studies had a minimum score of 4 and a maximum score of 13. The studies published before 1990 had a mean quality score of 7.4, and the studies published after 1990 had a mean quality score of 10.2. The lowest scores probably were mainly due to the lack of reporting instead of the low study quality.^33,40

Table 2. Study Characteristics

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Rest

Restrictions in ROM after ankle injury are common and often long lasting, with restrictions in posterior talar glide observed for up to 6 months.⁴⁸ These restrictions can contribute to the development of chronic ankle instability. Bleakley et al²² concluded that moderate evidence exists that manual therapy techniques applied in the acute phase of ankle sprains effectively increase ankle dorsiflexion.

van der Wees et al⁴⁹ reviewed the effectiveness of exercise therapy and manual mobilization in the treatment of acute ankle sprains and functional ankle instability by conducting a systematic review of RCTs. Most of these studies were not eligible for our review because the authors did not evaluate the interventions within the first 5 to 7 days after trauma. The overall conclusion of van der Wees et al⁴⁹ was that exercise therapy likely effectively reduces swelling and decreases time to return to work in the short term and prevents recurrent ankle sprains in the long term. Manual mobilization initially affects dorsiflexion of the ankle. Given only the short-term effect, the clinical relevance of these findings for general physiotherapy practice might be limited but might be useful in high-level athletes.⁴⁹

In the best methodologic study included in this review, Bleakley et al³⁴ concluded that an accelerated exercise protocol during the first week after ankle sprain improved ankle function. However, some limitations existed in performing this study and drawing the conclusions, as described in a letter to the authors.⁵⁰

McCulloch et al⁵¹ compared mobilization with immobilization and concluded that mobilization was more effective for reducing tenderness but produced no difference in ankle function. The use of nonsteroidal anti-inflammatory drugs was a co-intervention in this study. We excluded this study because the treatment duration was 8 days and the first assessment was at 10 days.

Although pooling is not realistic and the methodologic quality is low, a preliminary conclusion can be drawn. All included studies had a similar conclusion: some type of immediate posttraumatic mobilization is beneficial in the treatment of acute ankle sprains.^1,31,34–36

Ice

Despite its widespread clinical use, the precise physiologic responses to ice application have not been fully elucidated. Moreover, the rationales for its use at different stages of recovery are quite distinct. Using cryotherapy to manage acute soft tissue injury is based largely on anecdotal evidence.⁵² In a systematic review, Bleakley et al⁵³ assessed the evidence base for using cryotherapy in the treatment of acute soft tissue injuries. Although they included 22 trials, the authors concluded that many more high-quality trials were needed to provide evidence-based guidelines for the treatment of acute soft tissue injuries.⁵³

Based on the 4 studies included in their systematic review, Hubbard et al⁵⁴ concluded that cryotherapy positively affected return to work and sports. Bleakley et al⁵² performed a randomized controlled study to compare the effectiveness of 2 different, clinically appropriate cryotherapy protocols for patients with ankle sprains. Because they did not compare these treatments with a no-ice treatment, we did not include this study in our review. They concluded that in accordance with basic science research, the results highlighted that shorter, intermittent applications might enhance the analgesic effect of ice after acute ankle injury. Ice application seems relatively safe and seems to influence ankle function.^14,51,55 Cold application can be used before therapeutic exercise programs without interfering with normal sensory perception and can be used before strenuous exercise without altering agility.^14,55 Palmieri et al⁵⁶ reported that a 20-minute cryotherapy treatment applied to the ankle did not alter core temperature. Based on our review, evidence from RCTs to support the use of ice in the treatment of acute ankle sprains is limited.

Compression

Airaksinen et al⁴¹ suggested that a combination of elastic bandaging and IPC is better than elastic bandaging alone. When reviewing the use of a compression bandage for all soft tissue ankle injuries, Pollard and Cronin⁵⁷ concluded that little evidence is available to support this type of treatment. Based on their comparison of different modes of compression, they could not make uniform recommendations regarding the type and level of compression.⁵⁷

Based on our review, evidence from RCTs to support the use of compression in the treatment of acute ankle sprains is limited. No information can be provided about the best way, amount, and duration of compression or the position in which the compression treatment is given (recumbent or elevated).^29,41

Elevation

We did not include the study by Rucinkski et al²⁴ because they did not examine the intervention of interest but concluded that elevation is the most appropriate of the 3 used treatment protocols if the major therapeutic objective is to minimize edema in the postacute phase of rehabilitation. Based on expert opinions, several guidelines do recommend elevation in the treatment of acute ankle sprains.^19,29 No randomized trials were found and included in this review, so no evidence based on studies with high levels of evidence is available for the effectiveness of elevation.

Implications for Practice

Insufficient evidence is available from RCTs to determine the relative effectiveness of RICE therapy for acute ankle sprains in adults. Evidence that some type of immediate posttraumatic mobilization is beneficial in the treatment of acute ankle sprains is moderate. Evidence that ice provides no effect in the treatment of acute ankle sprains is limited. Evidence supporting the use of compression in the treatment of acute ankle sprains is limited. No evidence exists to support or reject the use of elevation in the treatment of acute ankle sprains. Treatment decisions must be made on an individual basis, carefully weighing the relative benefits and risks of each option, and must be based on expert opinions and national guidelines.

Implications for Research

Sufficiently powered, high-quality, and appropriately reported randomized trials of the different elements of RICE therapy for acute ankle sprains are needed. Concealed allocation and blinded outcome measurement would improve the quality and validity of future results. The use of well-defined and validated functional outcome measures, including patient-derived quality-of-life measures, is preferable. Finally, the recording of all relevant cost outcomes could be useful. A difficulty with trials in athletic patients is that these patients do not accept the risk of receiving a second-best treatment.