Early E-modulus of healing Achilles tendons correlates with late function: Similar results with or without surgery Torsten Schepull, Joanna Kvist and Per Aspenberg Linköping University Post Print N.B.: When citing this work, cite the original article. This is the authors’ version of the following article: Torsten Schepull, Joanna Kvist and Per Aspenberg, Early E-modulus of healing Achilles tendons correlates with late function: Similar results with or without surgery, 2012, Scandinavian Journal of Medicine and Science in Sports, (22), 1, 18-23. http://dx.doi.org/10.1111/j.1600-0838.2010.01154.x Copyright: John Wiley and Sons http://www.wiley.com/ Postprint available at: Linköping University Electronic Press http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-75106 Early E-modulus of healing Achilles tendons correlates with late function. Similar results with or without surgery Thorsten Schepull*1, Joanna Kvist2, Per Aspenberg1 1 Section for Orthopaedics and Sports Medicine, Department of Neurosciences and Locomotion, Faculty of Health Sciences, SE 581 85Linköping, Sweden 2 Section for Physiotherapy, Department of Medical and Health Sciences, 581 85 Linköping, Sweden * Corresponding author: Thorsten Schepull; University Hospital, 58185 Linköping, Sweden; e-mail: [email protected]; telephone: 0046-13-224299; fax: 0046-13-224305 Abstract Non-operative treatment of Achilles tendon ruptures is associated with an increased risk of rerupture. We hypothesized that this is due to inferior mechanical properties during an early phase of healing, and performed a randomized trial, using a new method to measure the mechanical properties. Tantalum markers were inserted in the tendon stumps, and tendon strain at different loadings was measured by stereo-radiography (RSA) at 3, 7 and 19 weeks and 18 months after injury. 30 patients were randomized to operative or non-operative treatment. The primary out-come variable was an estimate for the modulus of elasticity at 7 weeks. Strain per force, cross-sectional area and tendon elongation were also measured. The functional outcome variable was the Heel-Raise index after 18 months. There was no difference in the mean modulus of elasticity or other mechanical or functional variables between operative and non-operative treatments at any time-point, but strain per force at 7 and 19 weeks had significantly larger variation in the non-operative group. This group therefore might contain more outliers with poor healing. The modulus of elasticity at 7 weeks correlated with the Heel-Raise index after 18 months in both treatment groups (r2=0.75; p=0.0001). This correlation is an intriguing finding. Introduction Despite decades of debate, we still have no consensus about the appropriate treatment of acute Achilles tendon ruptures (Bhandari et al., 2002; Khan et al., 2005). Operative treatment with many variations and non-operative treatment are evenly supported in the literature (Aktas et al., 2009; Gigante et al., 2008; Lynch, 2004; Moller et al., 2001; Nistor, 1981). Postoperative methods are also numerous, and in recent studies early mobilisation has become popular because of its favourable effects on tendon healing (Enwemeka et al., Mortensen et al., 1999; Suchak et al., 2008). In animal studies locally applied platelet concentrates have accelerated tendon healing (Aspenberg et al., 2004), and similar results are reported with different growth and differentation factors (Forslund et al., 2003; Forslund et al., 2003; Virchenko et al., 2004). The criteria for treatment success have to be based on functional outcome and complications (Pajala et al., 2002). Functional results and complication rates often have a low statistical power for comparisons of different treatments. Moreover, they do not give information about the properties of the healing tendon at a given time point during the healing process. Healing of a tendon depends on early factors, such as type of injury, type of surgery and individual repair capacity. It also depends on late factors, such as rehabilitation programs or the patients´ motivation for training. A useful measure of early results would make it possible to study the early factors separately. In a pilot study, we used Roentgen stereophotogrammetric analysis (RSA) (Selvik, 1990) with simultaneous mechanical loading to describe the mechanical properties of a healing Achilles tendon. We found that an estimate for the modulus of elasticity during early stages of healing correlated with the late functional outcome (Schepull et al., 2007). We found that an estimate for the modulus of elasticity during early healing correlated with the late functional outcome. According to a meta-analysis, non-operatively treated tendons have a higher risk of re-rupture than operatively treated ones (Khan et al., 2005). We speculated that this difference would be caused by inferior mechanical properties in the non-operatively treated tendons at early stages of healing. The specific hypothesis for this study was that the modulus of elasticity at the time of plaster removal (7 weeks) would be lower in the non-operatively treated group than in the operatively treated one. Methods All patients between 18 and 65 years presenting with an acute rupture of the Achilles tendon at our hospital were asked to participate. Exclusion criteria were diabetes mellitus, history of cancer, lung or heart diseases and rheumatoid arthritis. Between May 2005 and April 2007 we included 30 consecutive patients (5 women). Two patients refused to participate. All patients were injured during sports or sports related activities. Randomization was done using sealed envelops. Patients consented in writing and the study was revised and approved by the Regional Ethics Committee. Operative treatment Patients randomized to operative treatment were operated within 5 days after injury. Operation was performed in local anaesthesia using an open technique with a dorso-medial approach. We adapted both tendon ends with a resorbable suture (Vicryl size 1) using the single loop Kessler technique. We implanted 2 tantalum beads (size 0.8 mm) in the distal part of the tendon, and 2 tantalum beads in the proximal part. We then closed the paratenon and sutured the skin with a resorbable intracutaneous suture. A short leg cast was applied with the foot in equinus position. At 3.5 weeks, the cast was removed and a new cast was applied with the ankle in a neutral position for another 3.5 weeks. Full weight bearing was allowed from the beginning. The cast was removed at 7 weeks in total, and the patients were instructed to use shoes with a 2 cm elevation of the heels for another 6 weeks. Physiotherapy started after cast removal, following our previous hospital routines. Full activity, including sports, was allowed after approximately 5 months. Non-operative treatment Patients randomized to non-operative treatment were treated immediately in the emergency room. The rupture site was palpated and marked with a permanent marker pen. A short leg cast was then applied with the foot in equinus position. At 3.5 weeks, this cast was removed. Using a special injection needle, 2 tantalum beads 0.8 mm were injected into the distal part of the tendon and 2 beads into the proximal part. We used our earlier marking as reference to distinguish between the proximal and distal tendon stumps. A new cast was applied with the foot in the neutral position for another 3.5 weeks. Also in this group, full weight bearing was allowed. The cast was removed at 7 weeks in total, and after cast removal, these patients followed the same regimen as the operated group, as regards instructions, shoes and physiotherapy. Follow-up: Mechanical properties We used Roentgen stereophotogrammetric analysis (RSA) to measure strain under defined loading, and CT and ultrasound to measure the transverse area of the tendon at the rupture site. This allowed calculation of the modulus of elasticity (Young’s modulus). RSA RSA provides the possibility to measure the distance between tantalum beads in 3 dimensions with high accuracy. A change in position, e.g. ankle flexion, does not influence the measurements if the tendon tissue is not deformed. During RSA, simultaneous radiographs are taken in two planes using extra-corporal calibration markers in a standardized cage. We performed RSA at 3.5 weeks, 7 weeks (within 48 hours after cast removal), 19 weeks, and 18 months. At 3.5 weeks there was just a single x-ray exposure, taken after the plaster had been changed to a new one in neutral position. At 7 weeks, 19 weeks and 18 months, RSA-examinations were combined with mechanical loading. Patients sat on an examination table with the foot in a specially designed frame, and with 8 degrees of plantar flexion. The frame allowed us to apply a pedal to the forefoot and load it with weights. The patients were then asked to keep the foot in position and to resist the force of the pedal. The first force applied to the pedal was 25 N and the second was 150 N (Figure 1). The 25 N loading was intended to provide a base-line value (a reasonable relaxation of the dorsal flexor muscles) and 150 N was the main loading (sufficient loading to produce strain). The patients had to resist the force for 15 seconds before the radiographs were taken. Between all x-ray exposures there was a break for 3 minutes. These first two x- ray exposures were used as control examination. Moreover, these exposures served as preconditioning loading of the Achilles tendon. After another 3 minute break, the main examination was performed, again with 25 N and 150 N. When not otherwise stated, all results refer to the second (main) examination. Strain per force values (assuming linear relationship) were calculated with correction for the lever arms of the forefoot and the calcaneus, and are expressed as % per 100 N tendon force. The 4 beads were numbered from proximal to distal. Elongation between the different times for follow-up was based on the change in distance between the beads 2 and 3 at the second (main) loading with 150 N. We measured the elongation of the tendon during the second cast period (in neutral position) by taking RSA images directly after the cast had been applied at 3.5 weeks and just prior to cast removal at 7 weeks. For RSA analysis, we used the UmRSA 4.1 system and software to calculate the distances between the single beads. Tendon force was calculated from pedal force. The pedal pivoted around an axis so that the force had a defined loading point in a lateral projection. Lever arms were calculated from lateral radiographs of the CT scan with the centre of the talar trochlea as pivot point. Figure 1. RSA examinations performed at 7 and 19 weeks and 18 months A final RSA was done aft 18 months. This examination differed slightly from the previous. Also here the patients had to resist the applied loading for 15 seconds with 3 min intervals, but the forces were 25 N, 125 N, 225 N, 325 N and 425 N. CT and Ultrasound We measured the transverse (cross-sectional) area at mid-distance between the proximal and distal markers at 7 weeks using CT, and at 19 weeks using ultrasound. CT was used at 7 weeks because we also wanted to determine the position of the beads within the tendon (Figure 2). Beads lying outside the tendon on the CT-scans were excluded. The ultrasound examination at 19 weeks was performed by one experienced radiologist. Figure 2. CT examination to confirm correct position of the tantalum beads. The two tantalum markers on each side of the healing rupture appear enlarged due to artefacts. Follow-up: Functional outcomes The patients were examined 18 months after injury by a physiotherapist (JK), who had not previously been involved in the treatment. A number of muscle performance tests were performed, but only the primary variable (heel raise index) is reported here. Heel raise test has been recommended for evaluating calf muscle function (Möller et al., 2005; Schepull et al., 2007; Silbernagel et al., 2009). We previously created a Heel-Raise index, defined as the number of heel raises the patient could do, multiplied with heel raise height, as percentage of the other side (Schepull et al 2007). Patients also filled in the Achilles Tendon Rupture Score (ATRS) form (Nilsson-Helander et al., 2007).
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