"Double-Row Rip-Stop" Technique for Arthroscopic Rotator Cuff Repair

"Double Row Rip-Stop" Arthroscopic Repair Technique for Acute, Retracted Rotator Cuff Tears

Acute, retracted rotator cuff tendon tears are important to recognize and can present unique technical challenges to repair. Various arthroscopic techniques and suture configurations have been proposed for repair of acute tears with aims to maximize the repair footprint and optimize tendon fixation. The double row rip-stop configuration was designed and has been used for rotator cuff repair due to its potential advantages related to suture pullout, footprint reapproximation and load sharing. The purpose of this article is to present the author's arthroscopic technique for repair of acute, retracted rotator cuff tendon tears using a double-row, rip-stop suture configuration. The indications and authors' preferred arthroscopic technique for biceps tenodesis are also discussed.

Medialized Rip-Stop Convergence Technique for Retracted Rotator Cuff Tears

Attempts to restore the anatomical footprint during rotator cuff repair for retracted, relatively immobile tears can be difficult. In some cases, it can lead to excessive tension of the repair. Previous studies have noted improved clinical outcomes when repair tension is not excessive, and medialization of the anatomical footprint has been suggested as a technique that can help surgeons repair large, retracted tears without excessive tension and achieve improved clinical outcomes. Of note, excessive tension when restoring the rotator cuff tendon to the anatomical footprint is not limited to large, retracted tears. In some cases, restoring small- and medium-sized tears to the anatomical footprint also can lead to excessive tension. Therefore, it is not uncommon for the authors to employ some degree of footprint medialization even for repair of small- or medium-sized tears if repair to the anatomical footprint will lead to excess tension. The purpose of this article and video demonstration is to provide instruction for a reproducible rotator cuff technique using a medialized single-row rip-stop construct combined with convergence.

H-loop Knotless Double-Row Repair Versus Knotted Suture Bridge for Rotator Cuff Tears: A Biomechanical and Histological Study in an Animal Model

BACKGROUND

Knotted suture bridge repair (KSBR) has been widely proven to be an effective method for rotator cuff repairs. However, the occurrence of type 2 failure after suture bridge repair remains a frequent problem because of the stress concentration and disturbance of tendon perfusion in the medial row. The authors have developed the H-loop knotless double-row repair (HLDR) to counteract these problems.

PURPOSE

To compare the biomechanical and histological outcomes of HLDR and KSBR for rotator cuff tear in the rabbit model.

STUDY DESIGN

Controlled laboratory study.

METHODS

Acute bilateral supraspinatus tears were created on the shoulders of 46 New Zealand White rabbits. HLDR and KSBR were randomly performed on the left side or right side. Thirteen animals each were sacrificed at 2, 4, and 8 weeks after surgery (n = 39), with 6 rabbits used for histological evaluation and the other 7 rabbits for biomechanical testing. The remaining 7 animals from the original 46 were only used for initial biomechanical evaluation at week 0.

RESULTS

Macroscopically, all repaired tendons were connected to their footprint on the greater tuberosity without postoperative complications at 8 weeks after surgery. The HLDR group had significantly better histological bone-to-tendon integration compared with the KSBR group in terms of fibrocartilage regeneration, collagen composition, and fiber organization. The biomechanical outcomes in the HLDR group were demonstrated to be better than those of the KSBR group at time 0 and 8 weeks after surgery.

CONCLUSION

Both repair techniques were effective for rotator cuff tears in a rabbit rotator cuff tear model; however, HLDR demonstrated more advantages in improving biomechanical properties and histological tendon-to-bone healing compared with KSBR.

CLINICAL RELEVANCE

This animal study suggested that HLDR might be an alternative choice for rotator cuff tears in humans to increase tendon-to-bone healing and reduce the rate of failure to heal.

The Application of H-Loop in Arthroscopic Knotless Double-Row Rotator Cuff Repairs

Objective

To determine the functional outcomes after a novel method of H‐loop knotless double‐row technique in patients with rotator cuff tears.

Method

From June 2020 to September 2020, a total of six patients (five women, one man) with arthroscopic rotator cuff repair using the H‐loop knotless double‐row technique were enrolled in our study. The average age is 54 years (range: 50–61 years). The preoperative and final follow‐up clinical outcome were evaluated using the American Shoulder and Elbow Surgeons (ASES) score, visual analog scale (VAS), University of California Los Angeles (UCLA) score, and Constant–Murley score. The active shoulder range of motion (ROM) was also collected preoperatively and postoperatively at the final follow‐up (forward flexion and abduction). Accordingly, intraoperative and postoperative complications were observed as well.

Result

There were six patients that underwent arthroscopic rotator cuff repair using the H‐loop knotless double‐row technique. The average follow‐up period was 7.52 ± 0.70 months. The VAS, UCLA, ASES, and Constant–Murley scores improved from 5 ± 2.45, 15.67 ± 3.44, 47.67 ± 17.41 and 49.17 ± 8.98 preoperatively, to 0.83 ± 0.75, 36.27 ± 3.83, 91.67 ± 10.76 and 85.83 ± 4.31 at the final follow‐up, with statistical significances of P = 0.009, P < 0.001, P = 0.006, and P = 0.001, respectively. Meanwhile, the active shoulder ROM (forward flexion and abduction) improved from 135.00 ± 46.80 and 125 ± 56.48 preoperatively, to 173.67 ± 4.13 and 172 ± 3.27 at final follow‐up, respectively (P = 0.082, P = 0.088). During the follow‐up, there were no postoperative complications such as wound‐site infection, nerve or vessel damage, subcutaneous hematoma, and suture anchor problems.

Conclusion

With the benefit of reducing the possibility of strangulation and blood supply affection for the rotator cuff, The H‐loop knotless double row technique may be an alternative method to significantly improve subjective functional outcomes and increase the healing rate of medium‐sized rotator cuff tears with degeneration issues and poor tissue quality.

Achilles Tendon Rip-Stop SpeedBridge Repair

Achilles tendon injuries have been on the rise secondary to our increased participation in sports, increase in societal obesity rates, and the growing elderly population. There has been disagreement in recent years about whether to treat injuries such as Achilles tendon ruptures operatively or nonoperatively with aggressive functional rehabilitation. For those opting to surgically manage Achilles tendon ruptures, insertional Achilles tendonitis, or augment the described SpeedBridge Achilles tendon repair, we propose a modified rip-stop technique. The goal of this technique is to provide a biomechanical advantage to our current operative interventions for these injuries, a greater load-to-failure and a speedier, more reliable return to sport in our athletic populations.

Revision Rotator Cuff Repair: A Comprehensive Approach and Stepwise Technique

The indications for and techniques to accomplish revision rotator cuff repair continue to be challenging problems that surgeons face. Complexity of tears, poor tissue quality, retained hardware, and adhesions are routinely encountered during surgical intervention for failed rotator cuff repairs. A successful outcome for any revision rotator cuff repair is determined, in part, by the surgeon's ability to address these intraoperative issues in an optimum manner. The surgical technique described in this article outlines a comprehensive and stepwise approach that can aid the surgeon in developing an effective strategy to accomplish revision rotator cuff repair.

Biomechanical evaluation of a novel double rip-stop technique with medial row knots for rotator cuff repair: an in vitro study

Aims

Many biomechanical studies have shown that the weakest biomechanical point of a rotator cuff repair is the suture-tendon interface at the medial row. We developed a novel double rip-stop (DRS) technique to enhance the strength at the medial row for rotator cuff repair. The objective of this study was to evaluate the biomechanical properties of the DRS technique with the conventional suture-bridge (SB) technique and to evaluate the biomechanical performance of the DRS technique with medial row knots.

Methods

A total of 24 fresh-frozen porcine shoulders were used. The infraspinatus tendons were sharply dissected and randomly repaired by one of three techniques: SB repair (SB group), DRS repair (DRS group), and DRS with medial row knots repair (DRSK group). Specimens were tested to failure. In addition, 3 mm gap formation was measured and ultimate failure load, stiffness, and failure modes were recorded.

Results

The mean load to create a 3 mm gap formation in the DRSK and DRS groups was significantly higher than in the SB group. The DRSK group had the highest load to failure with a mean ultimate failure load of 395.0 N (SD 56.8) compared to the SB and DRS groups, which recorded 147.1 N (SD 34.3) and 285.9 N (SD 89.8), respectively (p < 0.001 for both). The DRS group showed a significantly higher mean failure load than the SB group (p = 0.006). Both the DRS and DRSK groups showed significantly higher mean stiffness than the SB group.

Conclusion

The biomechanical properties of the DRS technique were significantly improved compared to the SB technique. The DRS technique with medial row knots showed superior biomechanical performance than the DRS technique alone.

The Chinese Knot Stitch Technique Using a Footprint Ultrasuture Anchor for Rotator Cuff Repair

Management of the rotator cuff presents specific challenges to orthopaedic surgeons. Several locking suture methods have been reported but often fail for a number of reasons. We describe a different technique that is easy to perform and inspired by the Chinese knot, an arthroscopic double-locking suture using a footprint ultrasuture anchor. This technique is similar to the suture-bridge structure on the bursal side of the tendon in that it increases tissue grip and stabilizes initial tendon-to-bone fixation. This technique is especially suitable for the patients who have bursal-side partial-thickness or degenerative small- and medium-sized rotator cuff tears.

The 2019 Arthroscopy Association of North America Traveling Fellowship-Los Gallos: New Friends on an Old Town Road

We came in with high expectations, yet the Arthroscopy Association of North America (AANA) Traveling Fellowship far exceeded them. The 4 traveling fellows came from different backgrounds, different parts of North America, and different practice settings, including an independent private practice, a hybrid private-academic practice, the military, and academia. We were lucky to have been ushered along the way by our godfather, the distinguished John Richmond, M.D., Past-President of AANA and Associate Editor Emeritus of Arthroscopy, who was gracious enough to give his time to the expedition. Over the course of the journey, this gang came together quickly and forged relationships that will last a lifetime. We are extremely grateful to AANA for the privilege and will cherish the memories for years to come.

The Arthroscopic "Montgolfier Double-Row Knotless" Rotator Cuff Repair Technique

Contemporary arthroscopic double-row suture anchor rotator cuff repairs have superior biomechanics compared with prior iterations. Numerous techniques have been described, but consensus regarding value has yet to be established. We describe an effective and easily reproducible technique: the arthroscopic "Montgolfier double-row" repair technique. This knotless construct has an evenly distributed, load-sharing, radially oriented suture limb configuration much like the envelope cables of a Montgolfier hot-air balloon, its namesake. Other advantages include the ability to apply manual, progressive and calculated tension on each suture limb and easy intraoperative modification depending on tear size, shape, and delamination, as well as tissue tension and quality. Future studies are needed to validate the biomechanics and clinical outcomes of this technique.