Addition of a Vertical Tensioned Locking Loop for Krackow Suture Fixation of Achilles Tendon Repairs: A Biomechanical Comparison
Methods: Ten matched pairs of human cadaveric Achilles tendons were transected to simulate acute rupture. In each pair, one side was repaired using a standard Krackow technique, while the other side was repaired using a Krackow technique augmented with a vertically oriented locking-loop suture. Five matched pairs were tested for stiffness and ultimate load to failure; the remaining matched pairs were assessed for gap formation at 100, 500, and 1,000 loading cycles.
Results: Mean stiffness and peak load were higher for the augmented Krackow repair than the standard Krackow repair groups (26.92±11.43 N/mm vs 9.41±2.99 N/mm, p=0.043; 497.55±134.44 N vs 202.61±94.34 N, p=0.043, respectively). Smaller gap formation was observed in the augmented repair at 500 cycles (p=0.042). No tendon failures occurred during cyclic loading in the augmented repair group, whereas four tendons failed in the standard repair group (p=0.032).
Discussion: The addition of a vertically oriented locking loop to a standard Krackow repair yielded higher stiffness, peak load, and resistance to gap formation. This repair option may allow early rehabilitation protocols with minimal additional operative time or morbidity for the patient. Keywords: Achilles tendon rupture; Tendon repair; Krackow suture.
Achilles tendon ruptures are common injuries that pose a treatment dilemma for the surgeon. The incidence of these injuries is 18 per 100,000 and is increasing [1-3]. The injury is more common in males than females, with the average age of 46.4 years . The Achilles tendon is at risk for rupture during rapid, eccentric loading of the gastrocsoleus complex . Achilles tendon ruptures are commonly sustained during athletic activity, and the mechanism of injury typically involves forceful push-off of the foot with an extended knee, unanticipated sudden forced ankle dorsiflexion, or violent dorsiflexion of a plantar flexed foot . These injuries have great potential to have a continued negative impact on athletic performance and function even with currently accepted treatments. Recent studies have shown that 32% of National Football League players who suffered Achilles tendon rupture never returned to play  and only 44% of National Basketball Association players who suffered a complete rupture of the Achilles tendon and underwent surgical repair returned to play for longer than one season .
Debate remains regarding the most effective management of acute Achilles tendon rupture. Current treatment options include closed management, open operative repairs, and minimally invasive or percutaneous operative repairs. A recent meta-analysis of prospective, randomized, controlled trials comparing open operative repair of acute Achilles tendon rupture to nonoperative management demonstrated that open operative repair significantly reduces the risk for rerupture (3.6% vs 8.8%; odds ratio, 0.425; 95% confidence interval, 0.222-0.815) . There are, however, higher incidences of deep infection, noncosmetic scar complaints, and sural nerve sensory disturbance in patients treated with open operative repair .
Early accelerated functional rehabilitation protocols have been demonstrated to accelerate healing and lead to improved patient outcomes in the treatment of acute Achilles tendon rupture [8-18]. Such protocols can prevent adhesion formation, joint stiffness, and muscle atrophy, and biomechanical studies have shown early mobilization and range of motion interventions during healing to improve tensile strength and tendon vascularity [19-21]. In vivo testing demonstrates that knee flexion does not significantly reduce force transmission across operatively repaired Achilles tendons, whereas in intact Achilles tendons there is a significant reduction in force with knee flexion of 45-50 deg . The lack of significant reduction in tension seen with knee flexion in the repaired Achilles tendons was hypothesized to be due to tendon lengthening following the repair . In a study by Benum et al., forces transmitted across repaired Achilles tendons were estimated to be 553 N during normal ambulation, 369 N immobilized in a walking cast with ankle at neutral, 282 N immobilized with a 0.5-in heel lift, and 191 N immobilized with a 1-in heel lift [22,23]. It is critical, therefore, in subjects allowed early rehabilitation that the repair technique demonstrate strength, stiffness, and resistance to gap formation capable of withstanding such a postoperative regimen.
Several biomechanical studies exist in the literature comparing the strengths of various suture repair configurations. The Krackow technique is very commonly utilized clinically and has been shown to increase load to failure compared with other suture repair techniques . A biomechanical cadaveric study by Lee et al., however, demonstrated that non-augmented Krackow suture-repaired tendons failed during cyclic loading at a force of 190 N, which corresponds clinically to the force transmitted across the repair during weight bearing with a 1-in heel lift . The researchers showed that a Krackow repair augmented with an epitendinous cross-stitch weave suture significantly increased the strength of the repair and resistance to gap formation, tolerating cyclic loading simulating clinical early rehabilitation protocols. An increased number of suture strands crossing the rupture site have been demonstrated to increase strength and minimize gap repair in biomechanical models [25,26]. Increasing suture caliber also increases repair strength . Increasing the number of strands and suture caliber crossing the repair site risks further damage to the frayed tendon ends and can also impair healing by impeding circulation to the tendon; these risks must be weighed against their benefits by the surgeon performing the repair.
To decrease gap formation, minimize further tissue damage, and increase strength of the open suture repair construct, we tested another modification to a traditional locking-loop Krackow suture construct. The addition of a vertically oriented suture traversing over the second loop of the construct theoretically would protect the susceptible first loop/suture interface during stress across the repair. We hypothesized that the addition of this vertically oriented loop would serve to stiffen the entire construct by converting a two-strand construct to a four-strand construct, thereby increasing the strength and minimizing gap formation. MATERIALS & METHODS
Ten matched human cadaver Achilles tendons with attached calcaneal bone blocks were harvested (donors aged 61-94 years, average age 75.8 years; eight males and two females), wrapped in saline-soaked gauze, and stored frozen until tested. The 10 pairs were assigned to two groups. Group A consisted of five matched pairs (donors aged 61-84 years, average age 68.4 years; four males and one female), which were examined using an ultimate load-to-failure protocol. Group B consisted of five matched pairs (donors aged 71-94 years, average age 83.2 years; four males and one female), which were examined using a cyclic loading protocol with measurement of gap formation.
The results for group A are presented in Table 1. In group A, the mean peak force was significantly higher in the study repair (augmented Krackow ) specimens than the control repair (standard Krackow) specimens. The stiffness was also significantly higher in the study repair specimens. The results for group B are presented in Tables 2 and 3. In group B, a trend toward higher ultimate loads in the study repair group was found; however, this failed to reach statistical significance. The stiffness values of the control and study repair constructs were not significantly different. The stiffness values were higher in group B than in group A because the loading rate was 200 N/s, which was at least 2.5 times the loading rate used in group A.
Gap formation was measured using digital calipers at 100, 500, and 1,000 cycles. The formation of a 5-mm gap defined clinical failure. Gap formation was found to be significantly higher in the control group at 500 cycles. Of the control specimens, one of five failed by 100 cycles, and four of five failed by 500 cycles. One specimen in the control group had a gap of <5 mm by 1,000 cycles. In contrast, a 5-mm gap did not form in any of the study specimens in group B at any point during cyclic loading, which was a significant improvement over the control repair (p=0.032).
Achilles tendon repairs need to be able to withstand the forces of the postoperative rehabilitation protocol used. The Achilles tendon is exposed to an average of 550 N during normal walking, 370 N when walking with the ankle immobilized at neutral, 280 N when walking with the ankle immobilized with a 0.5-in heel lift, and 190 N when walking with the ankle immobilized with a 1-in heel lift [1,22]. Passive ankle flexion range of motion exposes the Achilles tendon to 86-100 N of force [1,20,22,31]. Based on these values established in the literature, the addition of a vertically oriented locking loop to a traditional Krackow suture repair technique, as described in this study, would be able to withstand both passive ankle range of motion and walking with the ankle immobilized with a 1-in heel lift.
There were limitations in our study design. The age of the cadavers (average age 75.8 years) used for the study is greater than that of the population most vulnerable to this injury. As a result of increased age, the specimens in our study may not have had the same tissue characteristics as those from younger donors. Our stiffness and peak force values are similar to those in a study by Labib et al. , whose average donor age was 88 years, and to those in Lee et al. , whose average donor age was 52 years. This suggests that the donor age may not contribute to an important difference in results. The use of matched pairs further minimizes any influence age may have on study data. The simulated acute Achilles rupture in this study was created by sharp transection. In contrast, shredding and fraying of the tendon ends at the rupture site tends to occur in the clinical setting, thereby affecting the ability of the suture repair to achieve purchase in the tendon. A similar study attempted to create a traumatic tendon rupture in a cadaveric Achilles model and found that the “mop end” rupture encountered clinically could not be replicated, as the specimen failed at the tendon-clamp interface at forces greater than 900 N . It would be difficult to reproduce the same degree of shredding and tissue damage in matched pairs, which may affect the data collected and therefore the statistical comparison of the investigational repair vs the control group.
Further areas for research include retrospective case review to determine the clinical re-rupture and complication rates of this technique. Another area of interest would be to evaluate the effect of rehabilitation protocols and early mobilization on the clinical outcomes of this repair in a prospective, randomized fashion. CONCLUSIONS
Operative treatment of acute Achilles tendon ruptures has lower rates of re-rupture than nonoperative management. Early mobilization and rehabilitation protocols demonstrate improved outcomes in the treatment of acute Achilles tendon ruptures. The addition of a vertically oriented locking loop to a traditional Krackow suture repair technique increases stiffness, peak load, and resistance to gap formation of the construct when compared with the traditional Krackow. The addition of a vertical locking loop to a standard Krackow suture technique may allow early mobilization rehabilitation protocols given its increased stiffness and resistance to gap formation with minimal additional operative time or morbidity for the patient. ACKNOWLEDGMENTS
The authors would like to thank Paul Fritz, MA, for creating the figures for this manuscript. REFERENCES
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