The results of revision
Aims. The goal of the current systematic review was to assess the impact of implant placement accuracy on outcomes following total knee arthroplasty (TKA). Methods. A systematic review was performed in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines using the Ovid Medline, Embase, Cochrane Central, and Web of Science databases in order to assess the impact of the patient-reported outcomes measures (PROMs) and implant placement accuracy on outcomes following TKA. Studies assessing the impact of implant alignment, rotation, size, overhang, or condylar offset were included. Study quality was assessed, evidence was graded (one-star: no evidence, two-star: limited evidence, three-star: moderate evidence, four-star: strong evidence), and recommendations were made based on the available evidence. Results. A total of 49 studies were identified for inclusion. With respect to PROMs, there was two-star evidence in support of mechanical axis alignment (MAA), femorotibial angle (FTA), femoral coronal angle (FCA), tibial coronal angle (TCA), femoral sagittal angle (FSA), femoral rotation, tibial and combined rotation/mismatch, and implant size/overhang or offset on PROMs, and one-star evidence in support of tibial sagittal angle (TSA), impacting PROMs. With respect to survival, there was three- to four-star evidence in support FTA, FCA, TCA, and
Indications for total shoulder arthroplasty (TSA) require that the patient have a functioning rotator cuff to stabilise the glenohumeral joint. Without rotator cuff integrity the prosthesis will be unstable and the functional result will be less than expected. Physical exam can be difficult in the arthritic shoulder as contractures will limit the range of motion needed to adequately exam the rotator cuff status. The diagnosis can help as osteoarthritis has a 5% incidence of rotator cuff tear while rheumatoid arthritis has an incidence of greater than 40%. MRI can be obtained to determine the rotator cuff status before arthroplasty is performed but may not be necessary. Most total shoulder implant companies have both reverse and anatomic implants available. More recently the uses of platform stems that can be used with either RSA or
We know little regarding the long head of the biceps tendon's function but it is generally felt that it serves as a humeral head stabiliser by resisting superior migration during shoulder elevation. In total shoulder arthroplasty (TSA) the long head tendon is most commonly tenodesed as some have reported post-operative pain generated from an intact long head tendon. How does tenotomy or tenodesis of the long head tendon after
The current standard of care in the United States for the treatment of an infected arthroplasty, whether it be a TKA, THA or
Scapular spine fracture is a serious complication of reverse total shoulder arthroplasty (RTSA) often caused by a fall on an outstretched arm or a forced movement to the shoulder. The incidence of scapular fractures occurring after RTSA is reported between 5.8% and 10.2%. These fractures have been classified into 3 discrete fracture patterns. Avulsion of the anterior acromion (Type I), Acromion fractures (Type II) and Scapular spine fractures (Type III). This discussion will review the incidence of these post-operative peri-prosthetic fractures of the scapula after reverse
There are unfortunately many reasons a
INTRODUCTION. The glenoid version assessment is crucial step for any Total Shoulder Arthroplasty (TSA) procedure. New methods to compute 3D version angle of the glenoid have been proposed. These methods proposed different definitions of the glenoid plane and only used 3 points to define each plane on the 3D model of the scapula. In practice, patients often come to consultation with their CT-scans. In order to reduce the x-ray dose, the scapulae are often truncated on the inferior part. In these cases, the traditional scapula plane cannot be calculated. We hypothesised that a new plane definition, of the scapula and the glenoid, that takes into account all the 3D points, would have the least variation and provide more reliable measures whatever the scapula is truncated or not. The purpose of the study is to introduce new fully automatic method to compute 3D glenoid version for
The April 2023 Shoulder & Elbow Roundup360 looks at: Arthroscopic Bankart repair in athletes: in it for the long run?; Functional outcomes and the Wrightington classification of elbow fracture-dislocations; Hemiarthroplasty or ORIF intra-articular distal humerus fractures in older patients; Return to sport after total shoulder arthroplasty and hemiarthroplasty; Readmissions after shoulder arthroplasty; Arthroscopic Bankart repair in the longer term; Bankart repair with(out) remplissage or the Latarjet procedure? A systematic review and meta-analysis; Regaining motion among patients with shoulder pathology: are all exercises equal?
Accurate glenoid component placement continues to be a challenge. Knowledge that glenoid loosening is affected by malpositioning of the glenoid component has led to the development of patient specific instrumentation (PSI) in an attempt to optimise glenoid positioning. The ideal PSI would be reusable, reliable, cost-effective and robust enough to tolerate the stresses applied by the surgeon in the context of difficult glenohumeral exposure. The VIP system is a CT scan-based PSI with a reusable instrument. The subtle nuances of pre-operative planning will be discussed in a separate short video. The live surgery will incorporate use of the patient specific instrumentation during glenoid placement and the use of a short stemmed fourth generation total shoulder arthroplasty.
Anatomic and accurate placement of components is a primary goal in all arthroplasty procedures. Unique to total shoulder arthroplasty, challenging glenoid exposure and osteoarthritic glenoid deformity offer significant challenges and impediments to this goal. Despite thorough pre-operative planning strategies and contemporary cannulated pin-based shoulder systems, it is often times still difficult to accurately aim the guide pin to the medial border of the scapula when the deformity is substantial or exposure is difficult. Even small errors in guide pin position can result in problems with final component version, inclination and glenoid vault perforation. In addition, a malpositioned glenoid component has been shown to have a negative impact on implant longevity and clinical performance. Image-based patient specific instrumentation has been available in the lower extremity for nearly a decade with reliable results. The application of similar technology in the shoulder has demonstrated reliable positioning of the guide pin to a pre-operative plan with subsequent accurate placement of the glenoid component. This surgical demonstration will feature one of the currently available CT-based patient specific glenoid guides using a standard deltopectoral approach.
Complication rate after total shoulder arthroplasty ranges around 10%. These can be divided into intra-operative and post-operative complications. Intra-operative complications are periprosthetic fracture, nerve injury and malpositioning of components. Post-operative complications are instability, infection, rotator cuff tear, periprosthetic fracture, aseptic loosening, stiffness, heterotopic ossification and implant dissociation. The most effective means of preventing a complication are meticulous pre-operative planning, experience of the surgeon, adherence to sound surgical technique and intelligent patient selection and education.
Revision shoulder arthroplasty for failure secondary to soft tissue problems has improved with the availability of the reverse total shoulder system. The initial concept of a platform (convertible) stem was introduced in 2006. Removal of a well-fixed humeral stem can be a significant challenge and may require the surgeon to use osteotomy windows to successfully remove the implant. The increased time in the operating room, potential for complications and the cost of replacing the humeral component are all factors that make platform stem use a important consideration. The first report on total shoulder arthroplasty revision utilizing the platform stem concept confirmed improvements in patient morbidity and decreased costs. However, the overall functional improvement did not reveal a statistically significant improvement in pain relief or range of motion compared to those patients that had the humeral stem revised. Almost all major companies have adopted this concept of a convertible stem system for shoulder arthroplasty.
Analysis of orthopaedic malpractice claims has shown that highest impact allegations (highest payment dollars per claim) were those that were related to failure to protect anatomic structures in surgical fields. The prevalence of subclinical peripheral neurologic deficit following reverse and anatomic shoulder arthroplasty has been reported to be 47% and 4%, respectively. We propose the following five rules in order to avoid neurovascular injury during shoulder arthroplasty cases:
Pre-operative planning would assure a smooth operation without intra-operative difficulties. Adequate planning would include appropriate imaging, obtaining previous operative reports, complete pre-operative neurovascular examination and requesting the necessary operative equipment. Tug test: It is crucial to palpate the axillary nerve and be aware of its location. The tug test is a systematic technique for locating and protecting the axillary nerve. Neuromonitoring has been utilised in shoulder surgery in the past. Nagda et al showed that nerve alerts during shoulder arthroplasty occurred 56.7% of the time and 50% of the events were with the arm in abduction, external rotation and extension; 76.7% of signals returned to normal with retractor removal and change in arm positioning. We recommend removing all retractors and returning the arm to neutral position several times during surgery, especially during the glenoid exposure when the arm is in abduction and external rotation. Newer commercially available nerve stimulators are extremely useful in locating and protecting neurovascular structures. We recommend brachial plexus exploration and axillary nerve dissection with the aid of a nerve stimulator in all revision cases. Availability of a nerve/microvascular surgeon as an assistant in revision cases for brachial plexus exploration using a microscope is crucial for successful revision surgery.
Aseptic loosening of the glenoid after total shoulder replacement is a challenging problem to manage clinically. In the right circumstances, arthroscopic retrieval of loose polyethylene glenoids can be a valuable tool in the shoulder surgeon's repertoire for dealing with this uncommon problem. The purpose of this talk is to demonstrate the technique for arthroscopic removal of a loose glenoid and review the clinical circumstances where this procedure may play a valuable role.
Reverse total shoulder arthroplasty has become popular for primary replacement in complex proximal humerus fractures. Hemiarthroplasty and open reduction and internal fixation (ORIF) with locked plating were the treatment of choice but with variable functional outcomes and concerns of glenohumeral arthritis, rotator cuff problems, and tuberosity healing difficulties. This is especially concerning in the older population that has a higher incidence of rotator cuff problems and poor bone quality. Reverse total shoulder arthroplasty has resulted in excellent pain relief and seems to have a more consistent functional outcome in early reports when compared to hemiarthroplasty.
The infected shoulder arthroplasty is a devastating complication that can be very difficult to diagnose and treat. This presentation will compare the data on two-stage and single-stage exchange arthroplasty as pertains to functional outcomes and efficacy of eradication of the infection. Traditionally, the two-stage exchange arthroplasty has been the gold standard in the United States for the treatment of infected total shoulder replacements. In Europe, the trend seems to be moving towards a single-stage exchange with results that are reportedly comparable for eradication of infection to those of two-stage exchange although with seemingly better results for shoulder function. The surgeon's clinical experience with both techniques will be highlighted. A lively debate of the virtues and pitfalls of both approaches is the goal.
Despite reverse total shoulder arthroplasty (RTSA) being primarily indicated for massive rotator cuff tears, it is often possible to repair portions of the infraspinatus and subscapularis of patients undergoing this procedure. However, there is disagreement regarding whether these tissues should be repaired, as their effects remain unclear. Therefore, we investigated the effects of rotator cuff repair and changes in humeral and glenosphere lateralisation (HLat & GLat) on deltoid and joint loading. Six shoulders were tested on an in-vitro muscle driven active motion simulator. Cuff tear arthropathy was simulated in each specimen, which was then implanted with a custom adjustable RTSA fitted with a six axis load sensor. We assessed the effects of 4 RTSA configurations (i.e. all combinations of 0&10mm of HLat & GLat) on deltoid force, joint load, and joint load angle during abduction with/out rotator cuff repair. Deltoid and joint loads recorded by the load cell are reported as a % of Body Weight (%BW). Repeated measures ANOVAs and pairwise comparisons were performed with p<0.05 indicating significance. Cuff repair interacted with HLat & GLat (p=0.005, Fig. 1) such that with no HLat, GLat increased deltoid force without cuff repair (8.1±2.1%BW, p=0.012) and this effect was significantly increased with cuff repair (12.8±3.2%BW, p=0.010). However, adding HLat mitigated this such that differences were not significant. HLat and GLat affected deltoid force regardless of cuff status (−2.5±0.7%BW, p=0.016 & +7.7±2.3%BW, p=0.016, respectively). Rotator cuff repair did significantly increase joint load (+11.9±2.1%BW, p=0.002), as did GLat (+13.3±1.5%BW, p<0.001). The increases in deltoid and joint load caused by rotator cuff repair confirm that it acts as an adductor following RTSA and increases deltoid work. Additionally, cuff repair's negative effects are exacerbated by GLat, which strengthens its adduction affect, while Hlat increases the deltoid's abduction effect thus mitigating the cuff's antagonistic effects. Cuff repair increases concavity compression within the joint; however, Hlat produces a similar effect by wrapping the deltoid around the greater tuberosity – which redirects its force – and does so without increasing the magnitude of muscle and joint loading. The long-term effects of increased joint loading due to rotator cuff repair are unknown, however, it can be postulated that it may increase implant wear, and the risk of deltoid fatigue. Therefore, RTSA implant designs which improve joint compression without increasing muscle and joint loading may be preferable to rotator cuff repair.
Total shoulder arthroplasty is becoming increasingly common. A biceps tenodesis or tenotomy has become a routine part of the operation. There are several advantages to a tenodesis or tenotomy. First, the long head of the biceps tendon is routinely pathologic. One study has shown that there are differences in gene expression and mechanical properties in the long head of the biceps tendon in the setting of glenohumeral joint arthritis. Clinically, we often see inflammation, tearing, adhesions, or other pathology. Second, it is largely accepted that the long head of the biceps tendon has minimal function at the shoulder. The biceps muscle primarily functions at the elbow. Therefore, there is little downside to performing a tenodesis if there is a chance of it generating pain after surgery. Another major reason to perform a tenodesis or a tenotomy is that the technique of total shoulder arthroplasty requires a subscapularis takedown or lesser tuberosity osteotomy. The ligaments and tendon associated with the subscapularis contribute to the stability of the biceps tendon and after subscapularis takedown, it is unlikely that the tendon would remain reduced in the groove. In addition, it is part of a technique to incise and release the rotator interval, additionally creating scarring and/or instability associated with the biceps tendon. Given those reasons, this is a very common and reasonable routine part of the procedure of total shoulder arthroplasty.
The functional importance of the long head of biceps tendon remains controversial, but it is well accepted as an important source of anterior shoulder pain. Both biceps tenotomy and tenodesis have well-documented results in the native shoulder. Management of the long head of biceps tendon during shoulder arthroplasty remains controversial. The existing literature supports surgical treatment of the biceps during shoulder arthroplasty. Walch et al. reported the largest series in multicenter study of over eight hundred shoulder arthroplasty patients with or without biceps tenodesis. The authors found more reproducible pain relief with biceps tenodesis and no difference in range of motion. Similarly, Soliman et al. reported on a prospective review of 37 patients undergoing hemiarthroplasty for fracture randomly assigned to biceps tenodesis vs. no treatment. The authors found a statistically significant improvement in Constant score and shoulder pain with biceps tenodesis. If left untreated during shoulder arthroplasty, the intact biceps tendon may be a source of anterior shoulder pain requiring revision surgery. Tuckman et al. reported excellent pain relief after biceps tenotomy or tenodesis for biceps-related pain after previous shoulder arthroplasty. The decision to perform a biceps tenotomy versus a tenodesis during shoulder arthroplasty also remains controversial. Tenotomy may increase the risk of cosmetic pop-eye deformity and muscle cramping or fatigue over tenodesis. Therefore, routine long head of biceps soft tissue tenodesis is recommended during shoulder arthroplasty as it safe, reproducible, cost-effective, associated with improved outcome scores, and minimises the risk of cosmetic deformity and pain associated with biceps tenotomy.