MR imaging of cartilage repair surgery of the knee

Articular cartilage is a complex tissue with unique properties that are essential for normal joint function. Many processes can result in cartilage injury, ranging from acute trauma to degenerative processes. Articular cartilage lacks vascularity, and therefore most chondral defects do not heal spontaneously and may require surgical repair. A variety of cartilage repair techniques have been developed and include bone marrow stimulation (microfracture), osteochondral autograft transfer system (OATS) or osteochondral allograft transplantation, autologous chondrocyte implantation (ACI), matrix-assisted chondrocyte implantation (MACI), and other newer processed allograft cartilage techniques. Although arthroscopy has long been considered as the gold standard for evaluation of cartilage after cartilage repair, magnetic resonance (MR) imaging is a non-invasive method to assess the repair site and can be scored using Magnetic resonance Observation of Cartilage Repair Tissue (MOCART). MR also provides additional evaluation of the subchondral bone and for other potential causes of knee pain or internal derangement. Conventional MR can be used to evaluate the status of cartilage repair and potential complications. Compositional MR sequences can provide supplementary information about the biochemical contents of the reparative tissue. This article reviews the various types of cartilage repair surgeries and their postoperative MR imaging appearances.     

MR imaging of osteochondral grafts and autologous chondrocyte implantation

Surgical articular cartilage repair therapies for cartilage defects such as osteochondral autograft transfer, autologous chondrocyte implantation (ACI) or matrix associated autologous chondrocyte transplantation (MACT) are becoming more common. MRI has become the method of choice for non-invasive follow-up of patients after cartilage repair surgery. It should be performed with cartilage sensitive sequences, including fat-suppressed proton density-weighted T2 fast spin-echo (PD/T2-FSE) and three-dimensional gradient-echo (3D GRE) sequences, which provide good signal-to-noise and contrast-to-noise ratios. A thorough magnetic resonance (MR)-based assessment of cartilage repair tissue includes evaluations of defect filling, the surface and structure of repair tissue, the signal intensity of repair tissue and the subchondral bone status. Furthermore, in osteochondral autografts surface congruity, osseous incorporation and the donor site should be assessed. High spatial resolution is mandatory and can be achieved either by using a surface coil with a 1.5-T scanner or with a knee coil at 3 T; it is particularly important for assessing graft morphology and integration. Moreover, MR imaging facilitates assessment of complications including periosteal hypertrophy, delamination, adhesions, surface incongruence and reactive changes such as effusions and synovitis. Ongoing developments include isotropic 3D sequences, for improved morphological analysis, and in vivo biochemical imaging such as dGEMRIC, T2 mapping and diffusion-weighted imaging, which make functional analysis of cartilage possible.     

The role of mri in the early diagnosis of unilateral chondral overloading injuries of the athletic knee

Articular cartilage is essential for the normal use of the diarthrodial joints. Traumatic injury such as chondral orosteochondral fractures interfere with the normal function of this tissue. Conventional radiology, standard arthrography, and computer tomography arthrography do not allow visualization of the internal chondral architecture. Superior soft tissue contrast and direct visualization of the articular cartilage make magnetic resonance (MR) the most promising noninvasive method for the evaluation of articular cartilage injury. The majority of the research involves the knee, but with this technique it is possible to evaluate a large number of articular joints. This report describes the basic techniques of MR studies for the evaluation of the articular cartilage and the subchondral lesions.     

Articular cartilage: injury pathways and treatment options

Articular cartilage injury and degeneration is a frequent occurrence in synovial joints. Treatment of these articular cartilage lesions are a challenge because this tissue is incapable of quality repair and/or regeneration to its native state. Nonoperative treatments endeavor to control symptoms, and include anti-inflammatory medication, viscosupplementation, bracing, orthotics, and activity modification. Techniques to stimulate the intrinsic repair (fibrocartilage) process include drilling, abrasion, and microfracture of the subchondral bone. Currently, the clinical biologic approaches to treat cartilage defects include autologous chondrocyte implantation, periosteal transfer, and osteochondral autograft or allograft transplantation. Newer strategies employing tissue engineering being studied involve the use of combinations of progenitor cells, bioactive factors, and matrices, and the use of focal synthetic devices. Many new and innovative treatments are being explored in this exciting field. However, there is a paucity of prospective, randomized controlled clinical trials that have compared the various techniques, treatment options, indications and efficacy.     

Evaluation of chondral injuriesby magnetic resonance imaging: Repair assessments

Magnetic resonance (MR) is a versatile imaging modality that can be tailored to address many of the clinical andresearch questions encountered in musculoskeletal diseases. Developments in MR techniques for cartilage imaging have paralleled the advances in clinical approaches to cartilage injury assessment and repair. This article reviews the current state-of-the-art clinical MR imaging methods designed for noninvasive evaluation of cartilage. Basic technical considerations are discussed, including selection of an imaging site for patient referral, interpretation of MR images, and the limitations of each acquisition technique. Clinical examples are used to illustrate the appearance of chondral lesions. Finally, the unique issues arising from cartilage assessment after surgical repair are examined.     

A practical guide to imaging of cartilage repair with emphasis on bone marrow changes

Orthopedic surgeons have multiple options available to treat articular cartilage lesions, including microfracture, osteochondral autografting, and autologous chondrocyte implantation. By having basic knowledge of these surgical procedures, radiologists can more accurately interpret imaging studies obtained after surgery. In this article, we briefly review the different types of cartilage repair procedures, their appearance on magnetic resonance imaging (MRI), and pathologic MRI findings associated with postoperative complications. We also briefly discuss advanced MRI techniques (T2 mapping, delayed gadolinium-enhanced MRI of cartilage, sodium MRI) that have been recently used to assess the biochemical composition of repair tissue matrix. MRI can accurately assess the status and health of cartilage repair tissue. By providing this information to orthopedic surgeons, radiologists can play a valuable role in the management of patients who undergo cartilage repair surgery.     

Magnetic resonance imaging of cartilage and cartilage repair

Magnetic resonance (MR) imaging of articular cartilage has assumed increased importance because of the prevalence of cartilage injury and degeneration, as well as the development of new surgical and pharmacological techniques to treat damaged cartilage. This article will review relevant aspects of the structure and biochemistry of cartilage that are important for understanding MR imaging of cartilage, describe optimal MR pulse sequences for its evaluation, and review the role of experimental quantitative MR techniques. These MR aspects are applied to clinical scenarios, including traumatic chondral injury, osteoarthritis, inflammatory arthritis, and cartilage repair procedures.     

Matrix-based autologous chondrocyte implantation for cartilage repair with HyalograftC: two-year follow-up by magnetic resonance imaging

OBJECTIVE: Monitoring of articular cartilage repair after matrix-associated autologous chondrocyte implantation with HyalograftC by a new grading system based on non-invasive high-resolution magnetic resonance imaging. PATIENTS AND METHODS: In 23 patients, postoperative magnetic resonance imaging (MRI) was performed between 76 and 120 weeks. In nine of these patients, five MRI examinations were performed at 4, 12, 24, 52 and 104 weeks after HyalograftC implant. The repair tissue was described with separate variables: degree of defect repair in width and length, signal intensity of the repair tissue and status of the subchondral bone. For these variables a grading system with point scale evaluation was applied. RESULTS: CONCLUSION: High-resolution MRI provides a non-invasive tool for monitoring the development of cartilage repair tissue following HyalograftC technology, shows a good correlation with clinical outcome and may help to differentiate abnormal repair tissue from a normal maturation process.     

MR imaging of autologous chondrocyte implantation of the knee

Autologous chondrocyte implantation (ACI) is a surgical technique that is increasingly being used in the treatment of full-thickness defects of articular cartilage in the knee. It involves the arthroscopic harvesting and in vitro culture of chondrocytes that are subsequently implanted into a previously identified chondral defect. The aim is to produce a repair tissue that closely resembles hyaline articular cartilage that gradually becomes incorporated, restoring joint congruity. Over the long term, it is hoped that this will prevent the progression of full-thickness articular cartilage defects to osteoarthritis. This article reviews the indications and operative procedure performed in ACI. Magnetic resonance imaging (MRI) sequences that provide optimal visualization of articular cartilage in the post-operative period are discussed. Normal appearances of ACI on MRI are presented along with common complications that are encountered with this technique.     

Articular cartilage repair in the adolescent athlete: is autologous chondrocyte implantation the answer?

OBJECTIVE: To determine the evidence base for recommendations regarding autologous chondryocyte implantation in adolescent athletes. MATERIALS AND METHODS: All literature on articular cartilage repair from MEDLINE search dated 1990 to 2006 was reviewed. The majority of articles describe surgical technique and indications. Three techniques for secondary articular cartilage repair have been identified: autologous chondrocyte implantation, autologous osteochondral implants, and marrow stimulation techniques. The initial literature search identified 4 studies that reported the effectiveness and durability of autologous chondrocyte implantation in adults and 2 studies that reported the outcomes of autologous chondrocyte implantation in adolescent athletes. No results of osteochondral implantation or marrow stimulation techniques in adolescent athletes have been published. RESULTS: Acceptable repair rates with all 3 techniques have been reported in adult athletes. Two studies reported high success using autolgous chondrocyte implantation (ACI) in children. CONCLUSIONS: Articular cartilage injury in young athletes remains a difficult problem. The ideal situation is early diagnosis and primary repair, particularly with lesions of the knee, elbow, and ankle. In cases where primary repair is not possible or has been unsuccessful and the lesion is large or symptomatic, secondary repair with either marrow stimulation, microfracture, autologous chondrocyte implantation, or autologous osteochondral grafting may be used. However, at present only the results of ACI repair have been reported for adolescent athletes.     

Treatment of osteochondral injuries. Genetic engineering

Articular cartilage injuries are commonly encountered problems in sports medicine and orthopaedics. The treatment of chondral and osteochondral lesions, which possess only a very limited potential for healing, still represents a great challenge to clinicians and to scientists. Experimental investigations reported over the last 20 years have shown that a variety of methods, including implantation of periosteum, perichondrium, artificial matrices, growth factors, and transplanted cells, can stimulate formation of new cartilage. Genetic engineering--a combination of gene transfer techniques and tissue engineering--will facilitate new approaches to the treatment of articular cartilage injuries.     

Early postoperative adherence of matrix-induced autologous chondrocyte implantation for the treatment of full-thickness cartilage defects of the femoral condyle

Matrix-induced autologous chondrocyte implantation (MACI) is a tissue-engineering technique for the treatment of full-thickness articular cartilage defects and requires the use of a three-dimensional collagen type I–III membrane seeded with cultured autologous chondrocytes. The cell-scaffold construct is implanted in the debrided cartilage defect and fixed only with fibrin glue, with no periosteal cover or further surgical fixation. In a clinical pilot study, the MACI technique was used for the treatment of full-thickness, weight-bearing chondral defects of the femoral condyle in 16 patients. All patients were followed prospectively and the early postoperative attachment rate, 34.7 days (range: 22–47) after the scaffold implantation, was determined. With the use of high-resolution magnetic resonance imaging (MRI), the transplant was graded as completely attached, partially attached, or detached. In 14 of 16 patients (87.5%), a completely-attached graft was found, and the cartilage defect site was totally covered by the implanted scaffold and repair tissue. In one patient (6.25%), a partial attachment occurred with partial filling of the chondral defect. A complete detachment of the graft was found in one patient (6.25%), which resulted in an empty defect site with exposure of the subchondral bone. Interobserver variability for the MRI grading of the transplants showed substantial agreement (=0.775) and perfect agreement (_w=0.99). In conclusion, the implantation and fixation of a cell-scaffold construct in a deep cartilage defect of the femoral condyle with fibrin glue and with no further surgical fixation leads to a high attachment rate 34.7 days after the implantation, as determined with high resolution MRI.     

MRI of articular cartilage: revisiting current status and future directions

OBJECTIVE: The purpose of this article is to review the current understanding of the MRI appearance of articular cartilage and its relationship to the microscopic and macroscopic structure of articular cartilage, the optimal pulse sequences to be used in imaging, the appearance of both degenerative and traumatic chondral lesions, the appearance of the most common cartilage repair procedures, and future directions and developments in cartilage imaging. CONCLUSION: Articular cartilage plays an essential role in the function of the diarthrodial joints of the body but is frequently the target of degeneration or traumatic injury. The recent development of several surgical procedures that hold the promise of forming repair tissue that is hyaline or hyalinelike cartilage has increased the need for accurate, noninvasive assessment of both native articular cartilage and postoperative repair tissue. MRI is the optimal noninvasive method for assessment of articular cartilage.     

Clinical and MRI considerations in sports-related knee joint cartilage injury and cartilage repair

Cartilage injuries of the knee occur frequently in professional and amateur athletes and can be associated with severe debilitation and morbidity. They are commonly associated with ligament injuries but also may be frequently isolated. Increasing awareness and advances in magnetic resonance imaging (MRI) have led to increasing diagnosis and recognition of these injuries. Articular cartilage is just 2 to 4 mm thick and is avascular, alymphatic, and aneural. It has a limited capacity for healing, and there has been increasing use of cartilage repair techniques to treat these lesions in the active population. Strategies for cartilage repair include marrow stimulation techniques such as microfracture/drilling, osteochondral grafting, and autologous chondrocyte transplants. MRI is an important tool in the diagnosis and grading of cartilage injury and is useful in the follow-up and monitoring of these repair procedures. It is important for radiologists and clinicians to be aware of the capabilities and limitations of MRI in assessing cartilage injury and to be familiar with common postsurgical appearances to facilitate assessment and follow-up in this population. This article reviews the clinical findings and MRI imaging appearances of cartilage injury. The management options are discussed as well as common postsurgical appearances following the various interventions.     

Aspects of Magnetic Resonance in the surgical treatment of osteochondral lesions of the knee

AIM: To assess the magnetic resonance (MR) appearance of knee cartilage chondroplasty procedures and their evolution in order to evaluate the usefulness of the method in monitoring postoperative rehabilitation. MATERIALS AND METHODS: Sixty-two patients treated with knee chondroplasty for high-grade cartilage injuries (Noyes' stages II and III) were examined with MR. Forty patients were treated with abrasion chondroplasty, fifteen with osteochondral graft in the injury site and seven with the matrix-induced autologous chondrocyte transplant technique. All patients were operated on by the same orthopaedic team and examined with the same MR protocol. The MR follow-up was performed six months and one year after surgery in the patients treated with abrasion chondroplasty and osteochondral graft, and one week, three months and one year after surgery in the patients treated with cartilage transplant. In the patients treated with abrasion chondroplasty we assessed the fibrocartilage repair and the subchondral bone features, in the patients treated with osteochondral graft we examined the cartilage, the subchondral bone and the graft borders, while in the patients treated with cartilage transplant we evaluated the features and the evolution of the transplant and the subchondral bone. Arthrosynovitis was assessed in all patients. In seven patients a cartilage repair biopsy was performed in arthroscopy. RESULTS: In all the patients MR imaging proved useful in monitoring the chondroplasty. In the patients treated with abrasion chondroplasty the cartilage repair appeared as a hypointense non-homogeneous irregular strip of tissue that replaced the articular surface. The subchondral bone was sclerotic with some geodes. In the later examination the repair was unchanged. In the patients treated with osteochondral graft the articular cartilage was similar to the adjacent hyaline cartilage, although more non-homogeneous. The subchondral bone was sclerotic and in three cases oedematous. In four cases the graft extended beyond the articular border. In the cartilage transplant the matrix appeared as a hypointense stripe after a week due to hydration and it had thinned with signal reduction in the later follow-ups. In the cases with unfavourable clinical evolution the subchondral bone was oedematous and sclerotic in the later examinations. In the cases with unfavourable clinical evolution there was moderate arthrosynovitis, regardless of the chondroplasty technique performed. CONCLUSIONS: MR imaging is useful for monitoring the maturation and the integration of knee chondroplasty and can be proposed as a replacement of arthroscopy for the assessment of postoperative rehabilitation.     

MR示踪技术在干细胞移植治疗软骨缺损中的研究进展

关节软骨缺损临床十分常见, 但目前的治疗方法均存在修复不完全的缺陷。间充质干细胞移植治疗的发展为再生修复关节软骨缺损提供了新的治疗策略, 但是作为组织修复执行者的干细胞移植后的在体迁徙分布、增殖及转归过程, 目前尚无安全无创、实时动态的监测手段, 因此难以明确外源性干细胞在关节软骨缺损再生修复中所扮演的角色。而MR在体示踪细胞技术为解决上述问题提供了新思路。MRI具有无创、无电离辐射、时间空间分辨率高、对比度好等优点, 协同MRI对比剂, 既可无创提供关节软骨的详细解剖结构信息, 还可动态评估移植干细胞的归宿。笔者就MR示踪技术在干细胞移植治疗软骨缺损中的最新研究进展进行综述, 探讨其优势、局限性及未来前景。     

Evaluation of chondral repair using quantitative MRI

Various quantitative magnetic resonance imaging (qMRI) biomarkers, including but not limited to parametric MRI mapping, semiquantitative evaluation, and morphological assessment, have been successfully applied to assess cartilage repair in both animal and human studies. Through the interaction between interstitial water and constituent macromolecules the compositional and structural properties of cartilage can be evaluated. In this review a comprehensive view of a variety of quantitative techniques, particularly those involving parametric mapping, and their relationship to the properties of cartilage repair is presented. Some techniques, such as T2 relaxation time mapping and delayed gadolinium‐enhanced MRI of cartilage (dGEMRIC), are well established, while the full potential of more recently introduced techniques remain to be demonstrated. A combination of several MRI techniques is necessary for a comprehensive characterization of chondral repair. J. Magn. Reson. Imaging 2012; 36:1287–1299. © 2012 Wiley Periodicals, Inc.     

The use of carbon fiber pads inchondral injury and early osteoarthritis

Articular cartilage damage in young active individuals is a cause of pain and disability and may lead to earlyosteoarthritis. Methods proposed for treatment include intact cartilage grafting, osteochondral grafting, and isolated chondrocyte autografts. However, in some joints it is possible to repair the surface by stimulating the patient's repair mechanisms with techniques such as drilling and abrasion arthroplasty The repair tissue produced by such procedures, however, is usually of inferior quality with regard to the collagen (type I and III) and the proteoglycans. The use of carbon fiber pads as a support for such repair material has proved successful, particularly for the medial femoral condyle of the knee over a period of 5.8 years. The concept of supporting the matrix of the repair material which is formed from the subchondral bone by the use of a carbon fiber matrix is valuable and may be developed by the use of other biodegradable matrices in the future.     

MR Imaging of Postoperative Talar Dome Lesions

The number of surgical interventions of osteochondral lesions in the talar dome is steadily increasing. The surgical treatment with microfracturing or autologous chondrocyte transplantation has shown good clinical outcome at the midterm follow-up. With the development of advanced MR methods that are relatively specific for ultrastructural components of articular cartilage, compositional or biochemical MR has become possible in addition to the standard morphological evaluation of repair tissue. These quantitative MR techniques allow a monitoring of repair tissue on a molecular level. Using these techniques, the maturation of repair tissue, in particular the glycosaminoglycan content responsible for the biomechanical properties and the organization and content of collagen fibers, can be quantified and compared with normal hyaline cartilage. In addition, the diffusion properties of the repair tissue can also be analyzed by specific MR sequences.