The Double-Pulley Technique for Double-Row Rotator Cuff Repair

In an effort to maximize the area of footprint coverage, we developed the “double-pulley technique” for double-row rotator cuff repairs. Two suture anchors are inserted at the articular margin of the greater tuberosity (one anterior and one posterior). All 4 suture strands from each anchor are passed through a single medial point on the torn cuff. In this way, the 4 suture strands from the anteromedial anchor pass through 1 point in the cuff and the 4 strands from the posteromedial anchor pass through a different point in the cuff. A suture strand from 1 anchor is tied extracorporeally to a suture strand of the same color from the other anchor. The other ends of those 2 strands are then pulled, thereby delivering this extracorporeal knot into the joint and over the medial footprint. These 2 free suture strands are then tied together as a static knot. The procedure is repeated with the other sutures. This technique creates a double mattress suture medially, which compresses the intervening tendon bridge against its bone bed. We call this procedure the double-pulley technique because it uses the anchor eyelets as pulleys to deliver the extracorporeal knot into the shoulder. After the lateral row repair is performed, the rotator cuff footprint will be completely reconstituted.     

A Modified Suture-Bridge Technique for a Marginal Dog-Ear Deformity Caused During Rotator Cuff Repair

Recently, the suture-bridge technique was found to maximize the utility of a single-row construct by using the suture limbs from the medial mattress sutures to bridge and compress the repaired tendon. However, the formation of marginal dog-ear deformities at a repaired rotator cuff is not uncommon with the suture-bridge technique. If a dog-ear deformity is observed at the margin after completion of the rotator cuff repair, the detached marginal cuff is pierced via a suture hook. One strand of the uncut suture in the lateral row is transported through the deformed cuff. A nonsliding knot is seated on top of the detached cuff and presses this area of soft tissue firmly onto the bone. If necessary, these steps are repeated for the other side of the detached rotator cuff. After completion of the rotator cuff repair, a “zigzag” pattern of compression of the cuff against the bone footprint without detachment of the rotator cuff is observed. After repair of the rotator cuff tear via the suture-bridge technique, the benefit of our simple technique for treating a marginal detached cuff is that the footprint contact area of the rotator cuff is restored completely, without the need for additional suture anchors.     

Arthroscopic Rotator Cuff Repair Using a Triple-Loaded Suture Anchor and a Modified Mason-Allen Technique (Alex Stitch)

Surgical repair of the rotator cuff must have good resistance and should restore the tendon footprint. To attain this goal, a stitch with a strong biomechanical profile that avoids tissue strangulation should be used. We describe an arthroscopic suture technique undertaken to repair rotator cuff tears with a single triple-loaded suture anchor. The technique consists of a combination of a horizontal mattress and 2 vertical simple sutures that are positioned medial to the mattress suture. The suture anchor used is the 5-mm self-tapping ThRevo (Linvatec). This anchor is loaded with 3 sutures: 2 No. 2 nonabsorbable braided polyester sutures of different colors and a central high-strength No. 2 polyethylene suture. The shape of the anchor eyelet permits all 3 sutures to glide freely. A modified Mason-Allen technique (Alex stitch) that combines a horizontal side-to-side suture and 2 simples sutures as vertical loops is used. With use of the Spectrum suture passing device and shuttle relay system (Linvatec), both limbs of the centrally located polyethylene suture are passed through the cuff from bottom to top, approximately 1 cm from the tendon edge. This suture is not immediately tied. Next, with use of the same system, the other 2 sutures are placed medially and over the previous horizontal suture. Simple sutures are placed at an approximately 30° angle from the center of the anchor; 1 is placed anterior and the other posterior. The sutures are tied through the lateral portal. The mattress horizontal central stitch is always tied first, followed by the 2 vertical sutures. The horizontal mattress suture serves as a “rip stop stitch” and theoretically reduces the possibility of cutting out of the simple sutures.     

Arthroscopic double-pulley suture-bridge technique for rotator cuff repair

After preparation of the bone bed, two doubly loaded suture anchors with suture eyelets are inserted at the articular margin of the greater tuberosity. A retrograde suture-passing instrument penetrates the rotator cuff to retrieve the sutures through the modified Neviaser or subclavian portal. An ipsilateral pair of suture eyelets in the suture anchor is passed through the margins of the rotator cuff tear. The blue suture of the second and third pair is pulled out of the lateral cannula, and the threaded blue suture of the third pair in the needle is passed through the blue suture of the second pair. After retrieving the blue suture of the first pair through the anterior portal, it is pulled out to pass the blue suture of the third pair through the eyelet of the anteromedial anchor. The blue suture is linked between two anchors. The medial row of suture-bridge is repaired with a sliding knot, and the sutures are not cut. Once the rotator cuff repair using the suture-bridge technique has been performed, the two blue strands in the anterior portal are tied. We describe our technique that possesses the advantages of both the double-pulley and suture-bridge techniques, which improves the pressurized contact area and maximizes compression along the medial row.     

Tissue fixation security in transosseous rotator cuff repairs: A mechanical comparison of simple versus mattress sutures

The primary purpose of this investigation was to compare tissue fixation security by simple sutures versus mattress sutures in transosseous rotator cuff repair. These two repair techniques were each performed in 17 human cadaver shoulders, with two bone tunnels being used for the repair by two simple sutures and two other bone tunnels being used for the repair by one mattress suture. The repairs were loaded to failure in a servohydraulic materials test system. Rotator cuff repair by simple sutures was found to be significantly stronger than repair by mattress sutures (P = .0007). The average ultimate load to failure for the simple suture construct (189.62 N) was 39.72% greater than that for the mattress suture construct (135.71 N). Most of the failures occurred by suture breakage at the knot. Load-sharing by multiple suture tails and multiple knots in the simple suture configuration likely contributed to its superior strength characteristics compared with the mattress suture configuration.     

Arthroscopic bone tunnel augmentation for rotator cuff repair

Transosseous repair of the rotator cuff has been shown to recreate the anatomic rotator cuff footprint in a secure and cost-efficient manner. However, the potential for sutures cutting through bone remains a concern with this strategy. Devices have been used successfully during open transosseous rotator cuff repair to augment the bone tunnels, potentially avoiding suture cut-out through the weak bone of the greater tuberosity. Recently, arthroscopic transosseous fixation of rotator cuff tears has become an alternative to arthroscopic suture anchor and open transosseous techniques. This method is expected to have the same potential pitfalls at the bone-suture interface as the open technique. The authors describe a technique for rotator cuff repair using a secure method of arthroscopic bone tunnel augmentation.     

Subacromial Internal Spacer for Rotator Cuff Tendon Repair: “The Balloon Technique”

Lateral reattachment of the rotator cuff and the more recent introduction of the double-row rotator cuff repair technique require adequate visualization to define the rotator cuff footprint and the greater tuberosity. In many cases extensive debridement in this area is required to remove the overlying subdeltoid bursa, which can impair visualization laterally on the proximal humerus. Inadequate visualization laterally may lead to improper placement of the lateral row of fixation, compromising the reduction and fixation of the repaired rotator cuff tendon. We describe a surgical technique used to improve lateral visualization of the proximal humerus for placement of lateral anchors during arthroscopic rotator cuff repair using a Foley catheter. The end of a 14F-diameter Foley catheter is cut just proximal to the balloon end. One to three catheters are introduced in the subacromial space through small anterolateral or posterolateral portals and inflated with 15 mL of air. Adequate distension of the subacromial space allows better visualization, triangulation of the arthroscopic instruments, and anatomic repair of the rotator cuff tendon.     

Arthroscopic Rotator Cuff Repairs: An Anatomic and Biomechanical Rationale for Different Suture-Anchor Repair Configurations

The goal of rotator cuff repairs is to achieve high initial fixation strength, minimize gap formation, maintain mechanical stability under cyclic loading, and optimize the biology of the tendon-bone interface until the cuff heals biologically to the bone. We have seen an evolution in our approaches to fixing rotator cuff tears from open to mini-open to all arthroscopic. In our arthroscopic techniques, we have also seen a change in the types of anchors and sutures we use and our repair techniques including an evolution in techniques that include single row, double row, and, most recently, transosseous equivalent fixation. Single-row repairs are least successful in restoring the footprint of the rotator cuff and are most susceptible to gap formation. Double-row repairs have an improved load to failure and minimal gap formation. Transosseous equivalent repairs have the highest ultimate load and resistance to shear and rotational forces and the lowest gap formation. This review will discuss the anatomy and biomechanics of a normal rotator cuff, the biomechanical factors that play a role in rotator cuff repairs, the initial fixation repair mechanics, and finally propose an algorithm for rotator cuff fixation based on tissue quality and tear configuration.     

Reconstructive surgery for massive rotator cuff tear

Surgical Principles The rotator cuff is repaired with transosseous sutures if possible. If the defect is too large for direct repair, local muscle or tendon transfers are used. An anterior acromioplasty with resection of the coraco-acromial ligament is performed in every case. In absolutely irreparable tears the authors recommend an open or arthroscopic debridement combined with an anterior acromioplasty and a resection of the lateral end of the clavicle. Should a cuff tear arthropathy exist, shoulder replacement or an arthrodesis should be considered. Revised Version from: Operat. Orthop. Traumatol. 4 (1992), 161–178 (German Edition).     

Medial Rotator Cuff Failure After Arthroscopic Double-Row Rotator Cuff Repair

Persistent tendon defects after rotator cuff repair are not uncommon. Recently, the senior author has identified a subset of 5 patients (mean age, 52 years; range, 42 to 59 years) after arthroscopic double-row rotator cuff repair who showed an unusual mechanism of tendon failure. In these patients the tendon footprint appears well fixed to the greater tuberosity with normal thickness. However, medial to the intact footprint, the tendon is torn with full-thickness defects through the rotator cuff. All patients were involved in Workers' Compensation claims. Magnetic resonance arthrography showed an intact cuff footprint but dye leakage in all patients. Revision surgery was performed at a mean of 8.6 months after the index procedure and showed an intact rotator cuff footprint but cuff failure medial to the footprint. Four patients had repair of the defects by tendon-to-tendon side-to-side sutures, whereas one did not undergo repair. Medial-row failure of the rotator cuff is a previously unreported mechanism of failure after double-row rotator cuff repair. Given the small number of patients in this study, it is unclear whether these defects are symptomatic. However, repair of these defects resulted in improvement in pain in 4 of 5 patients.     

A biodegradable button to augment suture attachment in rotator cuff repair

Recent experimental studies suggest that the use of suture anchors for rotator cuff tear (RCT) repair transfers the "weak link" to the suture-tendon interface where failure occurs as the sutures cut through the tendon. The purpose of this study was to evaluate the effect of using a suture augmentation button on the fixation strength of rotator cuff tendon repair. A 1.5 cm by 2 cm defect was created in the supraspinatus tendon of seven cadaveric shoulder pairs and two suture anchors inserted in each humerus for suture attachment. For one of each pair, the defect was repaired with sutures placed in a horizontal mattress configuration. The other side was repaired with the sutures being passed through low profile, bioabsorbable buttons placed on the bursal tendon surface prior to knot tying. The supraspinatus tendon was cyclically loaded at a physiologic rate and load (33 mm/sec and 180 N, respectively). The number of loading cycles was recorded when the specimens developed 0.75 cm and 1.5 cm gaps at the repair site. The specimens were then tested to failure. Specimens in the unaugmented group developed 0.75 cm and 1.5 cm gaps at an average of 135 cycles and 362 cycles, respectively. The button augmented group developed these gaps at average of 420 cycles and 708 cycles, respectively. These differences were statistically significant (p < 0.05). The gaps progressively increased in all specimens, which eventually failed by suture cutting through tendon in all specimens. This study demonstrates that in vitro, suture augmentation with a low profile, bioabsorbable button provides significantly enhanced fixation when using suture anchors to repair torn rotator cuff tendon. This device may be a useful adjunct to current methods of rotator cuff repair.     

Arthroscopic Intratendinous Repair of the Delaminated Partial-Thickness Rotator Cuff Tear in Overhead Athletes

A distinct type of partial-thickness rotator cuff tear has been observed in overhead athletes, characterized by partial failure of the undersurface of the posterior supraspinatus and anterior infraspinatus tendons with intratendinous delamination. We present a technique of percutaneous intratendinous repair using nonabsorbable mattress sutures designed for the management of articular-side delaminated partial-thickness tears. After tear evaluation and preparation, the torn rotator cuff undersurface is held in a reduced position with a grasper through an anterolateral rotator interval portal while viewing intra-articularly. Two spinal needles are then placed percutaneously through the full thickness of the torn and intact rotator cuff. A polydioxanone suture is passed through each needle, retrieved out the anterior portal, and used to shuttle a single nonabsorbable No. 2 suture through the tissue, creating a mattress suture. Multiple mattress sutures can be placed as dictated by tear size and morphology, with suture retrieval and knot securing then proceeding in the subacromial space. We have adopted this approach with the goals of anatomically re-establishing the rotator cuff insertion and sealing the area of intratendinous delamination while preventing significant alteration to the anatomy of the rotator cuff insertion, which could lead to motion deficits, internal impingement, and potential tear recurrence.     

Anatomic Reduction and Next-Generation Fixation Constructs for Arthroscopic Repair of Crescent,L-Shaped,and U-Shaped Rotator Cuff Tears

Emerging techniques and instrumentation have allowed orthopaedic surgeons to achieve rotator cuff repair through an all-arthroscopic technique. The most critical steps in rotator cuff repair consist of proper identification of the cuff tear pattern and anatomic restoration of the torn tendon footprint. With anatomic reduction of the rotator cuff tendons, a sound fixation construct can help restore rotator cuff contact pressure and kinematics, allowing for decreased repair tension and optimal healing potential. We provide surgical methods to recognize tear patterns and present a repair construct that will restore the anatomic footprint of the torn rotator cuff tendon. The key, initial maneuver to restore the anatomic footprint of the cuff includes placement of a suture anchor at the anterolateral corner for L-shaped tears and at the posterolateral corner for reverse L–shaped and U-shaped tears. After insertion of the medial-row anchors, the tendon stitches should be planned by use of a grasper to hold the tendon in a reduced position and guide location of the stitch. The lateral row with suture bridge can be visualized, and the final repair construct should produce an anatomic restoration of the rotator cuff footprint.     

关节镜下肩袖损伤缝合技术研究进展

关节镜下肩袖修补术已非常普遍.许多单排锚钉、双排锚钉和经骨隧道修复技术应用于临床,但肩袖修复的最佳方法仍不清楚.生物力学研究证明相比于单排,双排锚钉修复的力度更强,而单排锚钉中的巨大肩袖缝合技术和改良Mason-Allen缝合技术力学性能最佳.临床研究显示双排锚钉修复能改善肩袖愈合率,但各种缝合技术的预后功能评分无明显...     

关节镜下不同穿骨技术修复肩袖损伤的有限元分析

目的:应用有限元方法比较并分析关节镜下不同穿骨技术修复肩袖损伤的生物力学差异。方法:根据1名健康成年人的肩关节CT数据分别建立传统关节镜下穿骨(arthroscopic transosseous,ATO)技术,巨针技术(giant needle technique)及ArthroTunneler(AT)技术的有限元模型。对3种技术模型上的缝合线均分别施加10 N及20 N载荷,比较并分析3种模型骨隧道及缝合线的应力变化。结果:在相同载荷下,传统ATO技术模型外侧骨隧道及缝合线所受应力均最大,其次为巨针技术模型;AT技术模型中段骨隧道及缝合线所受应力均最大,其次为巨针技术模型。在不同载荷下,3种模型的高应力区均主要集中于缝合线与骨隧道的接触部位。与传统ATO技术模型相比,巨针技术及AT技术模型外侧骨隧道及缝合线的应力分布均较分散,但AT技术模型的中段骨隧道及缝合线均存在明显的应力集中现象。结论:相对于传统ATO技术,巨针技术及AT技术均可降低缝合线切割骨隧道的风险,可能是较佳的修复方式。但AT技术相对于巨针技术,其在骨质疏松患者中的应用可能有限。     

Mattress suture-bridge technique for bursal-side partial-thickness rotator cuff tears

The standard procedure used to repair partial-thickness tears involves initial progression of the lesion to a full-thickness tear prior to tendon repair. However, the option for a bursal-side partial-thickness rotator cuff tear includes the preservation of as much of the remaining intact fibers as possible. Instead of inserting suture anchors in the medial row, as in the conventional suture-bridge technique, two mattress sutures are inserted into the rotator cuff. Full-thickness access is achieved using a percutaneous spinal needle and medial mattress sutures to preserve the articular bone attachment of the remnant fibers and to compress the repaired tendon on the footprint. Our method can help preserve the remnant rotator cuff tendon without tissue damage and can restore the normal rotator cuff footprint.     

Arthroscopic Grafting of Greater Tuberosity Cyst and Rotator Cuff Repair

Cysts of the greater tuberosity can be a normal finding independent of age and concurrent rotator cuff tear. The presence of a large greater tuberosity cyst can present a challenge at the time of rotator cuff repair. We present a 1-step arthroscopic technique to address these defects at the time of rotator cuff repair using a synthetic graft (OsteoBiologics, San Antonio, TX) originally designed to address osteoarticular defects. With the viewing portal established laterally, a portal allowing perpendicular access to the cyst is established. The cyst is thoroughly debrided, and a drill sleeve is then introduced perpendicular to the surrounding bone, serving as a guide for the matching drill to create a circular socket. A correspondingly sized TruFit BGS cylindrical implant (OsteoBiologics) is then implanted by use of the included instrumentation. The scaffold is placed flush with the surrounding bone. Because our arthroscopic rotator cuff protocol uses a tension-band technique with placement of suture anchors distal and lateral to the rotator cuff footprint, we are subsequently able to proceed with routine rotator cuff repair.     

Artrhoscopic Rotator Cuff Repair with Augmentation: The V‐sled Technique

Numerous techniques have been described for patch positioning in rotator cuff shoulder arthroscopic surgery. These techniques seem to be difficult challenges for the majority of arthroscopic surgeons, and because of that they are called “highly demanding” techniques. Without the use of dedicated instruments and cannulas, the authors propose a V‐sled technique that seems to be more reproducible, quicker and less difficult to perform for arthroscopic shoulder surgeons. The patient is placed in the lateral position. All arthroscopic procedures are performed without the use of cannulas. The standard posterior portal is used for the glenohumeral (GH) joint arthroscopy with fluid inflowing through the scope. After an accurate evaluation of the GH space, the scope is then introduced into the subacromial space. With the use of a spinal needle, a lateral portal is performed. The great tuberosity is prepared with a bur to place two 5.5 mm triple‐loaded radiolucent anchors. In addition, two free high strength sutures are passed through the muscle, respectively. The repair is performed using two high strength sutures from each anchor. The third wire from each anchor is retrieved out of the accessories portals used for the insertion of the anchors. In addition, two free high strength sutures are passed through the muscle, and the patch sizing is done using a measuring probe introduced through the lateral portal. Next, the patch is then prepared and is introduced into the subacromial space, and then the patch is stabilized, and the free sutures are tied.     

Cyclic loading of anchor-based rotator cuff repairs: Confirmation of the tension overload phenomenon and comparison of suture anchor fixation with transosseous fixation

Previous experimental studies of failure of rotator cuff repair have involved single pull to ultimate load. Such an experimental design does not represent the cyclic loading conditions experienced in vivo. We created 1 ×2 cm rotator cuff defects in 16 cadaver shoulders, repaired each defect with three MitekRC suture anchors (Mitek Surgical Products, Inc, Westwood, MA) using simple sutures of No. 2 Ethibond, and cyclically loaded the repairs by a servohydraulic materials test system actuator at physiological rates and loads (rate of 33 mm/s, load 180 N). A progressive gap was noted in each specimen, for a 100% rate of failure of the repairs. The central suture always failed first and by the largest magnitude, confirming tension overload centrally. One specimen exhibited combined bone and tendon failure, but the other 15 specimens failed through the tendon. Overall, the repairs failed to 5 mm and 10 mm at an average of 61 cycles and 285 cycles, respectively. Half the specimens were less than 45 years of age and had a 5-mm and 10-mm failure at an average of 107 and 478 cycles, respectively. The other half were over 45 years of age and failed to 5 mm and 10 mm at an average of 17 and 91 cycles, respectively, indicating more rapid failure of the rotator cuff tendons in the older group, and this was statistically significant (P ≤ .02). Comparison of suture anchor fixation in this study with transosseous bone tunnel fixation in a previous cyclic loading study at this institution indicates that bone fixation by suture anchors is significantly less prone to failure than bone fixation through bone tunnels (P = .0008). Changing the bone fixation from bone tunnels to suture anchors effectively transferred the weak link from bone to tendon.     

Rotator cuff repair techniques: Current concepts

Arthroscopic rotator cuff repair is being performed by an ever-increasing number of surgeons. With an ageing population and growing patient expectations it is crucial that clinical outcomes are optimised. Anatomical reduction of the tendon back to its footprint with minimal tension contributes to this, but this can only be achieved if key biomechanical factors are taken into consideration. In this review of the technical aspects of a rotator cuff repair, we focus on: (1) patient positioning, (2) biomechanical principles, (3) optimal visualisation, and (4) repair techniques for both anterior and postero-superior tears.