Christopher McCrum

Pectoralis major tendon transfer for the treatment of scapular winging due to long thoracic nerve palsy

BACKGROUND Painful scapular winging due to chronic long thoracic nerve (LTN) palsy is a relatively rare disorder that can be difficult to treat. Pectoralis major tendon (PMT) transfer has been shown to be effective in relieving pain, improving cosmesis, and restoring function. However, the available body of literature consists of few, small-cohort studies, and more outcomes data are needed. MATERIALS AND METHODS Outcomes of 26 consecutive patients with electromyelogram-confirmed LTN palsy who underwent direct (n = 4) or indirect transfer (n = 22) of the PMT for dynamic stabilization of the scapula were reviewed. All patients were followed up clinically for an average of 21.8 months (range, 3-62 months) with evaluations of active forward flexion, active external rotation, American Shoulder and Elbow Surgeons (ASES) score, visual analog scale (VAS) pain score, and observation of scapular winging. RESULTS Preoperative to postoperative results included increases in the mean active forward flexion from 112° to 149° (P < .001) an in mean active external rotation from 53.8° to 62.8° (P = .045), an improvement in the mean ASES score from 28 to 67.0 (P < .001), and an improvement in the mean VAS pain score from 7.7 to 3.0 (P < .001). Recurrent scapular winging occurred in 5 patients. There was no difference in outcome by length of follow-up. CONCLUSIONS PMT transfer is an effective treatment for painful scapular winging resulting from LTN palsy. This is the largest reported series of consecutive patients treated with PMT transfer for the correction of scapular winging.

Resection arthroplasty for failed shoulder arthroplasty

BACKGROUND As shoulder arthroplasty becomes more common, the number of failed arthroplasties requiring revision is expected to increase. When revision arthroplasty is not feasible, resection arthroplasty has been used in an attempt to restore function and relieve pain. Although outcomes data for resection arthroplasty exist, studies comparing the outcomes after the removal of different primary shoulder arthroplasties have been limited. MATERIALS AND METHODS This was a retrospective multicenter review of 26 patients who underwent resection arthroplasty for failure of a primary arthroplasty at a mean follow-up of 41.8 months (range, 12-130 months). Resection arthroplasty was performed for 6 failed total shoulder arthroplasties (TSAs), 7 failed hemiarthroplasties, and 13 failed reverse TSAs. RESULTS Patients who underwent resection arthroplasty demonstrated significant improvement in visual analog scale pain score (6 ± 4 preoperatively to 3 ± 2 postoperatively). Mean active forward flexion and mean active external rotation decreased, but this difference was not significant. Subgroup analysis revealed that postoperative mean active forward flexion was significantly greater in patients undergoing resection arthroplasty after failed TSA than after reverse TSA (P = .01). CONCLUSIONS Resection arthroplasty is effective in relieving pain, but patients have poor postoperative function. Patients with resection arthroplasty for failed reverse shoulder arthroplasty have worse function than those with failed hemiarthroplasty or TSA. Surgeons should be aware of this when assessing postoperative function. There is no difference in functional outcome between hemiarthroplasty and TSA.

The Safety of Controlled Hypotension for Shoulder Arthroscopy in the Beach-Chair Position

BACKGROUND The safety of controlled hypotension during arthroscopic shoulder procedures with the patient in the beach-chair position is controversial. Current practice for the management of intraoperative blood pressure is derived from expert opinion among anesthesiologists, but there is a paucity of clinical data validating their practice. The purpose of this study was to evaluate the effect of controlled hypotension on cerebral perfusion with use of continuous electroencephalographic monitoring in patients undergoing shoulder arthroscopy in the beach-chair position. METHODS Fifty-two consecutive patients who had undergone shoulder arthroscopy in the beach-chair position were enrolled prospectively in this study. All patients underwent preoperative blood pressure measurements, assignment of an American Society of Anesthesiologists (ASA) grade, and a preoperative and postoperative neurological and Mini-Mental State Examination (MMSE). The target systolic blood pressure for all patients was 90 to 100 mm Hg during surgery. Continuous intraoperative monitoring was performed with standard ASA monitors and a ten-lead portable electroencephalography monitor. Real-time electroencephalographic monitoring was performed by an attending-level neurophysiologist. RESULTS All patients violated at least one recommended limit for blood pressure reduction. The average decrease in systolic blood pressure and mean arterial pressure from baseline was 36% and 42%, respectively. Three patients demonstrated ischemic changes on electroencephalography that resolved with an increase in blood pressure. No adverse neurological sequelae were observed in any patient on the basis of the MMSE. CONCLUSIONS This study provides the first prospective data on global cerebral perfusion during shoulder arthroscopy in the beach-chair position with use of controlled hypotension. Our study suggests that patients may be able to safely tolerate a reduction in blood pressure greater than current recommendations. In the future, intraoperative cerebral monitoring may play a role in preventing neurological injury in patients undergoing shoulder arthroscopy in the beach-chair position.

Pain Management After Hip Arthroscopy: Systematic Review of Randomized Controlled Trials and Cohort Studies:

Background: Hip arthroscopy is often associated with significant postoperative pain and opioid-associated side effects. Effective pain management after hip arthroscopy improves patient recovery and satisfaction and decreases opioid-related complications. Purpose: To collect, examine, and provide a comprehensive review of the available evidence from randomized controlled trials and comparative studies on pain control after hip arthroscopy. Study Design: Systematic review. Methods: Using the Preferred Reporting Items for Systematic Reviews and Meta-analyses guidelines, a systematic review of the literature for postoperative pain control after hip arthroscopy was performed using electronic databases. Only comparative clinical studies with level 1 to 3 evidence comparing a method of postoperative pain control with other modalities or placebo were included in this review. Case series and studies without a comparative cohort were excluded. Results: Several methods of pain management have been described for hip arthroscopy. A total of 14 studies met our inclusion criteria: 3 on femoral nerve block, 3 on lumbar plexus block, 3 on fascia iliaca block, 4 on intra-articular injections, 2 on soft tissue surrounding surgical site injection, and 2 on celecoxib (4 studies compared 2 or more methods of analgesia). The heterogeneity of the studies did not allow for pooling of data. Single-injection femoral nerve blocks and lumbar plexus blocks provided improved analgesia, but increased fall rates were observed. Fascia iliaca blocks do not provide adequate pain relief when compared with surgical site infiltration with local anesthetic and are associated with increased risk of cutaneous nerve deficits. Patients receiving lumbar plexus block experienced significantly decreased pain compared with fascia iliaca block. Portal site and periacetabular injections provide superior analgesia compared with intra-articular injections alone. Preoperative oral celecoxib, compared with placebo, resulted in earlier time to discharge and provided significant pain relief up to 24 hours. Conclusion: Perioperative nerve blocks provide effective pain management after hip arthroscopy but must be used with caution to decrease risk of falls. Intra-articular and portal site injections with local anesthetics and preoperative celecoxib can decrease opioid consumption. There is a lack of high-quality evidence on this topic, and further research is needed to determine the best approach to manage postoperative pain and optimize patient satisfaction.

Postmeniscectomy Meniscus Growth with Stem Cells: Where Are We Now?

Arthroscopic meniscal repair and debridement are some of the most common procedures performed in the field of orthopedic surgery. Further, recent research has suggested poor long-term outcomes for patients with meniscectomies with increased incidence of osteoarthritis, leaving a need to develop technology to regenerate meniscal tissue following meniscectomy. Mesenchymal stem cells, are cells that can be harvested from multiple organs and retain the ability to differentiate into a variety of tissues, including osteoblasts, adipocytes, and chondroblasts. They have been shown to stimulate the regeneration of meniscal tissue in several animal models and recently in humans, as well. This study reviews the current research and clinical data regarding mesenchymal stem cells, specifically with regard to postmeniscectomy meniscus growth with stem cells.

Significant Chondrocyte Viability Is Present in Acetabular Chondral Flaps Associated With Femoroacetabular Impingement

Background: Patients presenting with cam deformity of the femoral head and neck sustain repeated trauma to the articular cartilage of the superior acetabulum, with chondral delamination injuries found during hip arthroscopy. Two previous studies reveal conflicting chondrocyte viability data in these traumatic cartilage injuries. The full-thickness nature of flaps may suggest that chondrocytes residing in the cartilage flap matrix in the joint environment would remain viable despite shear trauma. Hypothesis/Purpose: The purpose of this study is to determine the in vivo tissue viability of acetabular chondral flaps in patients with femoroacetabular impingement (FAI) when samples are analyzed immediately after biopsy. We hypothesize that the majority of the tissue in acetabular chondral flaps is viable in the joint microenvironment. Study Design: Descriptive laboratory study. Methods: Partially detached cartilage flaps from 10 patients undergoing arthroscopic hip surgery for FAI were biopsied in a minimally traumatic manner before chondroplasty and microfracture. Samples were placed in cold Hank’s Balanced Salt Solution without phenol red solution and immediately transported on ice to our laboratory. The edge of the samples was trimmed and further cut into 3 separate, 1-mm-thick sections. Sections were stained using a live/dead staining kit. Images were obtained with confocal microscopy, and the percentage of live cells was quantified. Results: Patients averaged 36 ± 11 years (range, 18-48 years), and 2 patients were female. The mean body mass index was 28.9 ± 5.6 kg/m2. The total proportion of live cells from all sections analyzed was 85.8%. The proportion of live cells per patient was 87% ± 10%. Conclusion: We determined that acetabular chondral flaps are approximately 87% live cells when analyzed immediately after biopsy, with 6 of 10 patients having greater than 90% live cells. These data point to the importance of laboratory techniques in making viability judgments in biologic systems. Clinical Relevance: Full-thickness cartilage loss is a difficult problem for all active people but particularly in the young population in whom joint preservation is key. We describe the viability of chondrocytes present in full-thickness acetabular-based chondral flaps encountered during hip arthroscopy. Identification of greater than 85% chondrocyte viability supports a foundation for evaluation and creation of novel clinical innovations for repair and replacement techniques using the flap as donor tissue, as alternatives to chondroplasty and microfracture.

Arthroscopic Anterior Ankle Decompression Is Successful in National Football League Players

Anterior ankle impingement is a frequent cause of pain and disability in athletes with impingement of soft-tissue or osseous structures along the anterior margin of the tibiotalar joint during dorsiflexion. In this study, we hypothesized that arthroscopic decompression of anterior ankle impingement would result in significant, reliable, and durable improvement in pain and range of motion (ROM), and would allow National Football League (NFL) players to return to their preoperative level of play. We reviewed 29 arthroscopic ankle débridements performed by a single surgeon. Each NFL player underwent arthroscopic débridement of pathologic soft tissue and of tibial and talar osteophytes in the anterior ankle. Preoperative and postoperative visual analog scale (VAS) pain scores, American Orthopaedic Foot and Ankle Society (AOFAS) hindfoot scores, and ankle ROM were compared; time to return to play (RTP), events missed secondary to surgery, and complications were recorded. All athletes returned to the same level of NFL play at a mean (SD) of 8.4 (4.1) weeks after surgery and continued playing for a mean (SD) of 3.43 (2.57) years after surgery. Mean (SD) VAS pain scores decreased significantly (P < .001), to 0.38 (0.89) from 4.21 (1.52). Mean (SD) active ankle dorsiflexion increased significantly (P < .001), to 18.86° (2.62°) from 8.28° (4.14°). Mean (SD) AOFAS hindfoot scores increased significantly (P < .001), to 97.45 (4.72) from 70.62 (10.39). Degree of arthritis (r = 0.305) and age (r = 0.106) were poorly correlated to time to RTP. In all cases, arthroscopic débridement of anterior ankle impingement resulted in RTP at the same level at a mean of 2 months after surgery. There were significant improvements in VAS pain scores, AOFAS hindfoot scores, and ROM. Arthroscopic débridement of anterior ankle impingement relieves pain, restores ROM and function, and results in reliable RTP in professional football players.

Return to Play After PRP and Rehabilitation of 3 Elite Ice Hockey Players With Ulnar Collateral Ligament Injuries of the Elbow

Background: Ulnar collateral ligament (UCL) injury is a well-described etiology of pain and decreased performance for the overhead athlete. Despite a growing volume of literature regarding the treatment of these injuries for overhead athletes, there is a paucity of such data regarding stickhandling collision sport athletes, such as ice hockey players. Purpose/Hypothesis: The purpose of this study was to characterize this injury among 3 elite ice hockey players and to describe the ability of these athletes to return to play, as well as to review the unique sport-specific implications of this injury, evaluation, nonsurgical management, and considerations for return to play. The authors hypothesized that elite ice hockey players will be able to return to play at the same level following nonoperative treatment of UCL injury. Study Design: Case series; Level of evidence, 4. Methods: Data from 3 elite professional ice hockey players who sustained a high-grade injury to the UCL were retrospectively reviewed. All athletes underwent 2 autologous conditioned plasma injections as part of their treatment and were evaluated with ultrasonography and magnetic resonance imaging. Results: Three consecutive elite ice hockey players were included in this study, and no patients were excluded. Players were cleared to full return to play at a mean 36 days postinjury. Follow-up examination at this time point demonstrated full range of motion of the elbow for all athletes, without tenderness to palpation over the UCL, including no tenderness over the humeral insertion site. Stability examination improved as well, demonstrating a soft to moderate endpoint with valgus stress, although this was not symmetric to the contralateral side. All athletes were able to continue to play at the same level of competition as before the injury occurred, without any complaints. No players had repeat injury during the same or following seasons. Conclusion: The authors present 3 elite-level ice hockey players who sustained a high-grade injury to the UCL. Successful return to play was possible after nonoperative treatment with injection of autologous conditioned plasma at a mean 36 days following injury. Athletes who injure either the top or bottom hand can return to play at the same elite level following this injury.

Osteotomies: Advanced and Complex Techniques

We started performing precise surgery based upon CT plans in the last century – the first embodiment of this approach was a robotic assistant built for total knee replacement, the “Acrobot” [1]. Abundant evidence now exists to confirm that assistive technologies enable surgeons to achieve their preoperative goals [2]. The concept of planned surgery is therefore not novel. Patient-matched instruments share several key elements with the robotic platform, and these formed the basis of this current project. The essential elements include image segmentation, planning, and registration. We applied the know-how of these dimensions to design and build patient-matched guides for a range of tasks using biocompatible polymer 3D printers. Having established a workflow for arthroplasty, the adaptation of the same principles to osteotomy was a short step, requiring software to be developed to deliver semiautomated useful information regarding limb segment alignment and the shapes of bones.

Maximizing Performance and Preventing Injury in Masters Athletes

Masters athletes exhibit persistently high levels of functional capacity helping them advance through a healthy aging process. When evaluating the trend of top performances among masters athletes, performance continues to improve within age categories [1, 2]. However, the capacity for performance in athletics does decrease as people age. The rate of decline has been evaluated by several studies. When examining the track and field performance of senior athletes, both male and female performance decreased at approximately 3.4% for each year after the age of 50 in a relatively linear fashion, until the age of 75, where performance begins to fall more precipitously, with a decline of greater than 7% in performance times annually [3]. Furthermore, the age of maximum performance increases with greater race distances, and the rate of slowing as athletes age decreases as competition distances increase [4]. This is consistent with known shifts that take place within skeletal muscle: the percentages of slow-twitch type I muscle fibers increase with increasing age [5–11]. Similar findings are noted in other sports as well [12]. Masters swimmers also demonstrate a modest, linear decrease in performance of 0.6–1% per year until age 70, when a more rapid decline is noted [13, 14]. In Ironman triathletes, age-related rates of decline in performance are 13% for men and 15% for women each decade until age 70; with greater declines noted in swimming and running than cycling [1].