Particulated Juvenile Articular Cartilage Allograft Transplantation with Bone Marrow Aspirate Concentrate for Treatment of Talus Osteochondral Defects Mark C

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Particulated Juvenile Articular Cartilage Allograft Transplantation with Bone Marrow Aspirate Concentrate for Treatment of Talus Osteochondral Defects Mark C SPECIAL FOCUS Particulated Juvenile Articular Cartilage Allograft Transplantation With Bone Marrow Aspirate Concentrate for Treatment of Talus Osteochondral Defects Mark C. Drakos, MD and Conor I. Murphy, BA conservative treatment options frequently ineffective.7–9 Used Abstract: Osteochondral defects (OCDs) of the talus are potential techniques include bone marrow stimulation, osteochondral sequelae of traumatic ankle injury and chronic ankle instability. Con- autograft transfer, fresh osteochondral allograft transfer, and servative treatment may fail thus requiring surgical intervention. Pri- matrix-induced autologous chondrocyte implantation. mary surgical intervention has classically entailed bone marrow Primary surgical treatment has classically involved bone stimulation, which may include drilling, microfracture, and/or abrasion marrow stimulation techniques, including microfracture, drill- arthroplasty, filling in the defect with fibrocartilage. Clinical data has ing, and abrasion arthroplasty, which attempt to fill in the OCD revealed good short-term success but the long-term effects and follow- with fibrocartilage by promoting an inflammatory response and up have been questioned. Newer techniques, such as osteochondral formation of a fibrin clot within the defect. Although this autograft transfer, fresh osteochondral allograft transfer, and autolo- technique is low-cost, technically undemanding, and minimally gous chondrocyte implantation, have shown initial promise in restoring invasive, the resulting fibrocartilage scar may degenerate with physiological hyaline cartilage but each procedure carries increased time because the intrinsic characteristics of the repair tissue are morbidity as arthrotomy, osteotomy, or a second procedure are often more akin to disorganized type-I cartilage as opposed to the necessary. Juvenile articular cartilage allograft transplantation has type-II cartilage composing articular cartilage.10,11 shown initial promising results in treating smaller sized OCDs and Tissue transplantation techniques, both osteochondral restoring physiological hyaline cartilage without the increased mor- autograft transfer and allograft transfer, are amenable options bidity of osteotomy or 2-step procedures. Augmentation with bio- when primary bone marrow stimulation fails for treating larger logical adjuncts has been shown to further aid in healing and regen- lesions. Unfortunately, these procedures carry a high risk of eration of physiological articular cartilage. The purpose of this article associated morbidity as malleolar osteotomy may be necessary is to describe a novel surgical all-arthroscopic technique for trans- to access the surgical site and transplant the graft. Both pro- plantation of juvenile articular cartilage allograft augmented with bone cedures also demand a high level of skill to properly size and marrow aspirate concentrate for the treatment of OCDs. position the graft to restore congruency to the articular surface. Osteochondral autograft transfer requires harvesting one or Level of Evidence: Diagnostic Level 4. See Instructions for Authors more osteochondral plugs, often from the knee, which can for a complete description of levels of evidence. result in donor-site morbidity.12 Allograft transfer carries its Key Words: osteochondral defect, BMAC, DeNovo cartilage, own unique disadvantages including high-cost, limited avail- arthroscopic repair ability, and a theoretical risk of disease transmission. Although these techniques replace the defect with hyaline cartilage, the (Tech Foot & Ankle 2015;14: 88–93) associated morbidities are significant. Matrix-induced autologous chondrocyte implantation is HISTORICAL PERSPECTIVE an attractive option because it allows the transplantation of Osteochondral defects (OCDs) of the talus are frequent cultured chondrocytes to restore normal hyaline cartilage to the sequelae of traumatic ankle injury and chronic ankle damaged articular surface. However, a 2-stage procedure is instability. Ankle sprains in the general population are required to harvest the chondrocytes, grow them in culture, and common with approximately 2,000,000 injuries occurring implant them to repair the OCD. There is also a potential for every year in the United States.1,2 A total of 10% to 30% of overgrowth of the chondrocytes at the site of implantation. all acute ankle sprains may have persistent disability and New techniques and technologies have emerged that avoid possible OCDs.3 Damage to the articular cartilage of the talus the morbidities of current surgical approaches.13–16 The DeNovo may also occur in cases of chronic lateral ankle instability, NT Graft (Zimmer Inc., Warsaw, IN) is an off-the-shelf, pre- distal fibular fracture, and deltoid ligament tear.4–6 packaged allograft of particulated juvenile articular cartilage Conservative treatment options, such as rest, physical from the patella of donors below 13 years old, more often below therapy, ankle bracing, and glucocorticoid injections, should 2 years old. The juvenile chondrocytes in the implant demon- be utilized initially as some patients may experience temporary strate a higher metabolic activity level, a higher cellular density, symptomatic relief. But, these injuries create a difficult clinical and a greater potential to regenerate hyaline-like cartilage.9,17–20 problem for orthopedic surgeons because the poor blood sup- Each package is marketed to repair an OCD up to 2.5 cm2 in size. ply and limited healing potential of articular cartilage makes In practice, this technique is not routinely used for treating lesions larger than 1.5 cm2. This method of repair is a single-step From the Department of Orthopaedic Surgery, Hospital for Special Sur- procedure that may eliminate the need for osteotomy because the gery, New York, NY. particulated nature of the allograft allows the entire procedure to The authors declare no conflict of interest. be performed arthroscopically. Address correspondence and reprint requests to Conor I. Murphy, BA, Hospital for Special Surgery, 535 East 70th Street, New York, Furthermore, recent literature has begun to expound the NY 10021. E-mail: [email protected]. beneficial effects of biological adjuncts used in conjunction Copyright r 2015 Wolters Kluwer Health, Inc. All rights reserved. with surgical repair for OCDs.21 Bone marrow aspirate 88 | www.techfootankle.com Techniques in Foot & Ankle Surgery Volume 14, Number 2, June 2015 Copyright © 2015 Wolters Kluwer Health, Inc. Unauthorized reproduction of this article is prohibited. Techniques in Foot & Ankle Surgery Volume 14, Number 2, June 2015 Special Focus: Cartilage Transplant for OCDs of the Talus concentrate (BMAC) obtained from centrifugation of bone Lateral and anteroposterior stress x-ray images provide base- marrow aspiration contains high concentrations of platelets, line objective data categorizing ligamentous stability of the growth factors, and mesenchymal stem cells.22 In vivo models ankle and help decipher if further surgical intervention is have demonstrated that BMAC combined with surgical repair necessary to restore the lateral soft tissue integrity of the ankle. of OCDs results in better healing of cartilage injuries than Surface cartilage lesions are best identified with MRI (Figs. 1, surgery alone.23,24 Also, the repair tissue is composed pri- 2). Coinciding soft tissue injuries are also easily assessed with marily of type-II cartilage that more closely resembles the MRI. Cystic bony lesions underlying the articular cartilage are natural physiological articular cartilage.23 best evaluated with CT imaging. The dimensions of cystic The purpose of this article is to describe a novel surgical bony components are better established with CT imaging as technique using an entirely arthroscopic approach for treating MRI can often overestimate the size of the lesions due to OCDs with juvenile particulated articular cartilage allograft enhancement of surrounding bony edema.26 augmented with BMAC. This is the first published article detailing an all-arthroscopic technique using both juvenile TECHNIQUE particulated articular cartilage allograft and BMAC to treat an The patient is placed on the operating table in a supine position OCD of the talus. with a pneumatic tourniquet applied to the proximal thigh. After induction of general anesthesia and nerve block, the INDICATIONS AND CONTRAINDICATIONS patient is prepped for bone marrow aspiration, identifying the The indications for surgical treatment of patients with an OCD anterior superior iliac spine as the anatomic landmark. are expanding as technologies and techniques continue to Approximately 60 mL of blood is aspirated through the improve. A patient diagnosed both clinically and radiographi- anterior superior iliac spines using a bone marrow needle. cally with a symptomatic OCD that has failed conservative Redirecting of the needle is encouraged to prevent withdrawal treatments is an ideal candidate. Furthermore, patients that have of the entire venous blood. The bone marrow aspirate is then failed surgical treatment with bone marrow stimulation techni- prepped and concentrated in the Magellan Autologous Platelet ques are also good candidates for surgery. The shelf-life of the Separator (Arteriocyte Medical Systems, Cleveland, OH) to DeNovo NT graft is 49 days from the start of processing. Should yield approximately 3 mL of BMAC. the intraoperative assessment of the OCD be contrary to the At this point, depending on the preoperative identification preoperative assessment and dictate
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