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Diagnostic pitfalls mimicking meniscal tears: MR imaging evaluation with arthroscopic correlation Poster No.: C-611 Congress: ECR 2009 Type: Educational Exhibit Topic: Musculoskeletal Authors: I. Tsifountoudis, I. Kalaitzoglou, A. Haritanti, I. Economou, A. S. Dimitriadis; Thessaloniki/GR Keywords: MRI, Meniscus, Diagnostic pitfalls, Postoperative meniscus DOI: 10.1594/ecr2009/C-611 Any information contained in this pdf file is automatically generated from digital material submitted to EPOS by third parties in the form of scientific presentations. References to any names, marks, products, or services of third parties or hypertext links to thirdparty sites or information are provided solely as a convenience to you and do not in any way constitute or imply ECR's endorsement, sponsorship or recommendation of the third party, information, product or service. ECR is not responsible for the content of these pages and does not make any representations regarding the content or accuracy of material in this file. As per copyright regulations, any unauthorised use of the material or parts thereof as well as commercial reproduction or multiple distribution by any traditional or electronically based reproduction/publication method ist strictly prohibited. You agree to defend, indemnify, and hold ECR harmless from and against any and all claims, damages, costs, and expenses, including attorneys' fees, arising from or related to your use of these pages. Please note: Links to movies, ppt slideshows and any other multimedia files are not available in the pdf version of presentations. www.myESR.org Page 1 of 40 Learning objectives MRI has been established as a very sensitive method for the diagnosis of meniscal tears. To maintain high accuracy, radiologists should be aware of potential pitfalls in interpretation. Our purpose is to review these potential causes of confusion, to describe the mechanisms by which they may create foci of pathologic signal intensity similar to meniscal tears and to recommend methods to avoid false-positive and false-negative interpretations. Background The findings from MRI examinations of 310 knees were retrospectively interpreted and correlated with prospectively recorded results from arthroscopic examinations performed between 2006 and 2008. The imaging protocol consisted of: a) T1-weighted fast spin-echo (FSE), b) proton density (PD)-weighted and T2-weighted FSE, c) T2 gradient (GRE)weighted and d) short-tau inversion recovery (STIR) sequences. Of the knees examined, 255 meniscal tears were identified. Furthermore, 27 false-positive and 14 false-negative findings were detected. Imaging findings OR Procedure details False-positive and false-negative findings were attributed to pitfalls in interpretation which may be caused by: (a) normal structures of the knee which project in close relationship to the menisci, such as anterior transverse ligament, meniscofemoral ligaments, oblique menisco-meniscal ligament and popliteal tendon and bursa, (b) normal variants of the menisci such as meniscal flounce, speckled anterior horn of the lateral meniscus and Wrisberg's variant of a discoid lateral meniscus, (c) MRI artifacts created by the pulse sequences used, such as magic angle phenomenon, volume averaging, motion and truncation artifacts, (d) various pathologic conditions of different etiology, such as chondrocalcinosis, meniscal ossicles and gas within the joint and (e) postoperative changes of the menisci. Page 2 of 40 NORMAL ANATOMIC STRUCTURES Normal anatomic structures that lie in close proximity to the meniscus and show similar MR signal intensity to the meniscus are common mimickers of meniscal pathology. The anterior transverse ligament attaches the anterior margin of lateral meniscus to the anterior horn of medial meniscus (Fig.). Fig.: The anterior transverse ligament is clearly demonstrated on coronal PD-W fat sat (a) and T1-W images (b) and on axial PD-W fat sat (c) and T1-W images (d) as it courses from the anterior margin of lateral meniscus to the anterior horn of medial meniscus. On sagittal images, a linear band of increased signal is present between the anterior horn of lateral meniscus and the anterior transverse ligament, occasionally simulating an oblique meniscal tear (Fig.) [1]. Page 3 of 40 Fig.: A linear band of increased signal intensity (arrowhead) is noticed on a sagittal PD-W fat sat image (j), between the anterior horn of lateral meniscus and the anterior transverse ligament (arrow), simulating an oblique meniscal tear. The course of the ligament is clearly demonstrated on adjacent sagittal PD-W fat sat images (ej). Osgood-Schlatter disease is also present with patellar tendon thickening, deep infrapatellar bursitis and tibial tubercle fragmentation. By the same mechanism, increased linear MR signal in the medial aspect of the posterior horn of lateral meniscus at the attachment site of the meniscofemoral ligament can mimic the appearance of a vertical meniscal tear. The meniscofemoral ligament originates from the lateral meniscus posteriorly and inserts on the medial aspect of medial femoral condyle. The ligament is composed of 2 separate branches, the ligament of Humphry and the ligament of Wrisberg (Fig.). Page 4 of 40 Fig.: Diagram showing the origin of meniscofemoral ligaments from the medial aspect of the posterior horn of lateral meniscus. On sagittal MR images, these are seen as low signal intensity ovoid structures anterior and posterior to the posterior cruciate ligament (PCL) and may be mistaken for meniscal fragments (Fig.) [2]. Page 5 of 40 Fig.: A linear band of increased signal intensity (arrowheads) is noticed on sagittal PDW fat sat images (e, f), between the posterior horn of lateral meniscus and the ligament of Humphry, simulating a vertical meniscal tear. The anterior meniscofemoral ligament (arrows) is clearly demonstrated on adjacent sagittal PD-W fat sat images (a-f). Page 6 of 40 Fig.: The anterior meniscofemoral ligament (arrows) is depicted on adjacent coronal PD-W fat sat images (g, h) as it courses from the medial aspect of medial femoral condyle to the medial aspect of the posterior horn of lateral meniscus. A horizontal tear of the posterior horn of medial meniscus (arrowheads) is also noticed. Page 7 of 40 Fig.: The ligament of Humphry (arrows) is demonstrated on adjacent axial PD-W fat sat images (i-l) as it courses from the medial aspect of medial femoral condyle to the medial aspect of the posterior horn of lateral meniscus. Page 8 of 40 Fig.: A linear band of increased signal intensity (arrowhead) is noticed on a sagittal PD-W fat sat image (e), between the posterior horn of lateral meniscus and the ligament of Wrisberg, simulating a vertical meniscal tear. The posterior meniscofemoral ligament (arrows) is clearly demonstrated on adjacent sagittal PD-W fat sat images (ae). Page 9 of 40 Fig.: The ligament of Wrisberg (arrows) is depicted on adjacent coronal PD-W fat sat images (f, g) as it courses from the medial aspect of medial femoral condyle to the medial aspect of the posterior horn of lateral meniscus. A horizontal tear of the posterior horn of medial meniscus (arrowheads) is also noticed. The medial and lateral oblique menisco-meniscal ligaments have a reported incidence of 1% to 4% and are an uncommon source of diagnostic difficulty. These ligaments extend obliquely from the anterior horn of one meniscus to the posterior horn of the opposite meniscus (Fig.). Page 10 of 40 Fig.: Diagram showing the medial oblique menisco-meniscal ligament as it courses from the anterior horn of medial meniscus to the posterior horn of lateral meniscus. As the ligament traverses the intercondylar notch, it passes between anterior cruciate ligament (ACL) and PCL, mimicking the appearance of a "double PCL sign" (Fig.). Page 11 of 40 Fig.: Sagittal T1-W (a) and PD-W fat sat images (b) through the intercondylar notch at the level of PCL demonstrate the medial oblique menisco-meniscal ligament as a thin linear structure of low signal intensity (arrows) mimicking a displaced meniscal fragment. A Baker's cyst is also noticed (arrowheads). Coronal PD-W fat sat image (c) shows the ligament as it passes through the intercondylar notch. Knowledge of the normal course of these ligaments, as well as the ability to trace them on consecutive MR images, allows distinction of these ligaments from a meniscal bucket-handle tear (Fig.) [3]. Page 12 of 40 Fig.: Bucket-handle meniscal tear of medial meniscus. The thin linear structure of low signal intensity (arrow) which courses under the PCL (arrowheads) on a sagittal T2-W image (a) represents a displaced meniscal fragment ("double PCL sign"). The meniscal fragment (arrow) is also demonstrated as it passes through the intercondylar notch under the PCL (arrowheads) on a coronal PD-W fat sat image (b). The bursa of the popliteus tendon, which lies close to the posterolateral meniscus, may also be mistaken for a meniscal tear. Fluid within the bursa appears as high-signal intensity on T2-weighted MR images and gives the appearance of a vertical or slightly diagonal tear in the posterior horn of lateral meniscus (Fig.) [4, 5]. Page 13 of 40 Fig.: Fluid within the bursa (arrowhead) appears as high-signal intensity on a sagittal PD-W fat sat image (e) and gives the appearance of a vertical or slightly diagonal tear in the posterior horn of lateral meniscus. The popliteus tendon and bursa (arrows) are clearly demonstrated on adjacent sagittal PD-W fat sat images (a-e). Page 14 of 40 Fig.: Fluid within the bursa (arrowhead) appears as high-signal intensity on a coronal PD-W fat sat image (f) and resembles a vertical or slightly diagonal tear in the posterior horn of lateral meniscus. The popliteus tendon and bursa (arrows) are demonstrated on adjacent coronal PD-W fat sat images (f, g). The lateral inferior genicular artery arises from the popliteal artery at the level of the tibiofemoral joint and courses laterally to the anterior aspect of the knee where it and other arteries compose the genicular anastomosis. Unlike the superior genicular arteries and the inferior medial genicular artery, the lateral inferior genicular artery is closely applied to the meniscus as it wraps around the knee, lying in a periarticular fat pad between the meniscus and lateral collateral ligament (LCL) (Fig.). Page 15 of 40 Fig.: Diagram showing the arteries of the knee. When the lateral inferior genicular artery lies immediately adjacent to the anterior horn of lateral meniscus, the space between the artery and the meniscus can produce the appearance of a tear in the meniscus on sagittal images. Comparison with a coronal image through the area of suspected tear may be helpful since the artery does not mimic a tear when viewed in the coronal plane (Fig.) [6]. Page 16 of 40 Fig.: Adjacent sagittal T1-W images through the lateral meniscus (a-d) demonstrate the course of the lateral inferior genicular artery (arrows). A narrow separation (arrowhead) between the anterior horn of lateral meniscus and the lateral inferior genicular artery (c) can sometimes be mistaken for a meniscal tear. NORMAL VARIANTS In addition to normal meniscal structures previously demonstrated radiologists should be familiar with several normal variants of the menisci that have been described in recent years. Meniscal flounce is an uncommon variant that can simulate meniscal pathology. It occurs in the absence of a tear and is a single symmetric fold along the free edge of the meniscus. It is a normal finding that is said to be present with ligamentous laxity, although it is not necessarily indicative of a tear in the ligament. The appearance is like that of a carpet that has a wrinkled edge and, in fact, presumably has a similar cause-that is, sliding of the tibia on the femur because of ligamentous laxity with resultant folding or buckling of the inner edge of the meniscus. It has no known significance. Page 17 of 40 A flounce results in a wavy S-shaped appearance along the free edge of the meniscus on sagittal images and a truncated meniscal appearance on coronal images that may be mistaken for a meniscal tear or degeneration (Fig.) [7]. Fig.: Meniscal flounce of medial meniscus (arrows) which results in a slight wavy Sshaped appearance along the free edge of the meniscus on adjacent sagittal PD-W fat sat images (a, b). A speckled appearance of the anterior horn of lateral meniscus is a frequent finding that has been explained by fibers of the anterior cruciate ligament inserting into the meniscus. It can be seen on one or two of the most medial sagittal images. The appearance can be mistaken for a torn lateral meniscus (Fig.) [8]. Page 18 of 40 Fig.: A speckled appearance (white arrows) of the anterior horn of lateral meniscus on adjacent sagittal PD-W fat sat images (a, b), which is caused by the insertion of the fibers of anterior cruciate ligament (black arrow) into the meniscus (c). The finding can easily be mistaken for a torn lateral meniscus. A discoid lateral meniscus is a normal variant seen in about 3% of knees. An uncommon variant of a discoid lateral meniscus is a Wrisberg's variant, in which the posterior horn is not attached to the capsule and is, therefore, mobile enough to move freely and sublux into the joint, causing pain and, occasionally, locking. The MR imaging appearance is a discoid lateral meniscus with no posterior horn attachment or a free-floating posterior horn. Unlike the incidental discoid meniscus, which should be asymptomatic unless torn, a Wrisberg's variant can be a source of pain and require surgery. It is most commonly found in children, although it can be seen in patients at any age [9]. The moderate to high signal intensity seen at the normal capsular attachment of the posterior horn of medial meniscus may be due to tissue inhomogeneity or peripheral vessels that can mimic a meniscocapsular detachment (Fig.). Page 19 of 40 Fig.: The high signal intensity seen at the periphery of the posterior horn of medial meniscus (arrows) on adjacent sagittal (a, b) and coronal PD-W fat sat images (c) was diagnosed as meniscocapsular detachment. The following arthroscory for anterior cruciate ligament reconstruction (ACLR), because of torn ACL, revealed absence of meniscal tear. Usually, the signal intensity of this normal connective tissue at the meniscocapsular junction is less conspicuous, whereas in cases of meniscocapsular detachment, there is markedly increased signal intensity (Fig.) [10]. Page 20 of 40 Fig.: Peripheral tear-meniscocapsular detachment (arrows) of the posterior horn of medial meniscus on sagittal (a) and coronal PD-W fat sat images (b). Bone contusions of the posterior tibial epiphysis are also noticed. The most significant characteristic in the appearance of pediatric meniscus is the presence of intrasubstance signal that represents perforating vessels within the meniscus. This signal has been described in 82% of menisci in children and is considered to be a normal finding that should not be misinterpreted as mucinous or myxoid degeneration like in adults. The MR criteria for establishing the diagnosis of a meniscal tear are the same in children and adults. The 2 most important criteria are intrameniscal signal that extends to the surface and abnormal meniscal morphology (Fig.) [11]. Page 21 of 40 Fig.: The presence of intrasubstance signal in the posterior horns of medial (arrows) and lateral (arrowheads) meniscus represents perforating vessels within the menisci. This signal is considered a normal finding and should not be misinterpreted as mucinous or myxoid degeneration like in adults. MRI ARTIFACTS MRI artifacts created by the pulse sequences used can result in image degradation and errors in diagnosis. The magic angle phenomenon occurs on short TE images in fibers that are orientated 55° relative to the static magnetic field. This MRI artifact is a cause of increased signal in the medial segment of the posterior horn of lateral meniscus. Imaging the knee joint in slight abduction can alter the orientation of the fibers in the posterolateral meniscus and eliminate this artifact [12]. Partial volume averaging is a type of artifact that occurs when 3-dimensional volumetric data is used to create a 2-dimensional image. The attachment of the capsule produces a concavity at the outer margin of the meniscus Page 22 of 40 that is filled with periarticular fat and neurovascular structures. When the signal from a normal dark meniscus is averaged with the bright, fatty tissue adjacent to the outer concave margin of the meniscus, high-signal intensity linear artifacts that may simulate a tear are created through the periphery of the meniscus on sagittal images (Fig.). Fig.: Diagram of the meniscus showing the concave meniscal edge. A sagittal section through the edge of the meniscus (B) produces a partial volume averaging linear artifact in the body of the meniscus. A section located more medially (A) may produce a similar linear artifact in the anterior and posterior horns when the curvature of the meniscus is placed at the edge of the section. This linear defect is seen only on sagittal images obtained through the periphery of the meniscus. A coronal image obtained through the meniscus will show no abnormality and can be used to exclude the presence of a tear (Fig.) [6]. Page 23 of 40 Fig.: Partial volume averaging produces linear artifacts mimicking horizontal tears (arrows) in the anterior and posterior horns and in the body of lateral meniscus on adjacent sagittal PD-W fat sat (a-c) and T1-W images (d-f). Motion artifact can be particularly problematic in MRI because of the long image acquisition times. If a structure moves to different positions during image acquisition, the image appears blurred or double exposed. Intrameniscal signal resembling a tear may result. If motion artifact is present on an MRI scan and a meniscal tear is suspected by imaging criteria, the sequence should be repeated without motion (Fig.) [5]. Page 24 of 40 Fig.: Motion artifact mimicking a tear (arrow) in medial meniscus on a coronal PD-W fat sat image (a). The meniscus appears normal on a coronal T1-W image at the same level (b), which is obtained without motion. Truncation error is a type of MRI artifact that occurs at high-contrast boundaries, such as between the articular cartilage and the menisci. Truncation artifact is a result of inherent errors in the Fourier transformation method of image reconstruction. It appears as a series of alternating parallel bands of bright and dark signal. When a line of high-signal intensity projects over a low-signal meniscus, a pseudotear is created [13]. VARIOUS PATHOLOGIC CONDITIONS Certain pathologic conditions of different etiology may mimic a meniscal tear. Most of them are rare entities and their recognition may help to explain areas of abnormal signal that do not fit well into previously recognized patterns and may improve interpretation accuracy. Page 25 of 40 A meniscal contusion occurs when the meniscus gets trapped between the tibia and the femur during a traumatic event-usually involving ACL tears. Increased signal in the periphery of the meniscus can resemble a tear; however, the signal intensity of a contusion is indistinct and amorphous rather than sharp and discrete. An adjacent bone contusion should alert one to the possible presence of a contusion rather than a meniscal tear (Fig.) [14]. Fig.: Meniscal contusion with amorphous and indistinct signal in the periphery of the posterior horn of medial meniscus (arrows) on adjacent sagittal (a-c) and coronal PD-W fat sat images (d-f) after an acute traumatic event with bone contusions, complete ACL and partial medial collateral ligament (MCL) tear. Follow-up MRI 5 months after initial imaging revealed resolution of abnormal meniscal signal. Grade 2C meniscal signal is an extensive triangular or wedge-shaped signal that does not reach the surface of the meniscus on more than one images on MRI. It has a low incidence (1,5%) and has been proved to represent a tear in 50% of cases. Most patients with grade 2C meniscal signal are not treated Page 26 of 40 with arthroscopy because they do not have symptoms at the site of grade 2C signal. Thus, when grade 2C signal is seen on MR imaging, arthroscopic follow-up is indicated if symptoms referable to the site of abnormal signal are also present (Fig) [15]. Fig.: Grade 2C signal in the posterior horn of medial meniscus (arrows) on adjacent sagittal PD-W (a, b) and coronal PD-W fat sat images (c, d), confirmed as intact meniscus on arthroscopy. Chondrocalcinosis is defined as a radiographically visible calcification in the cartilage of a joint. It can occur in the hyaline articular cartilage lining the articular surface or in the fibrocartilage of a meniscus. Although it can occur from many types of calcium crystals, the most commonly seen is from calcium pyrophosphate dihydrate crystal deposition in pseudogout, which is also known as calcium pyrophosphate dihydrate deposition disease. When MR imaging is performed on a meniscus with chondrocalcinosis, the T1-weighted or PD-weighted sequence shows high signal, which can be mistaken for a meniscal tear. Differentiating a meniscal tear from the high Page 27 of 40 signal of chondrocalcinosis can be difficult, if not impossible. Most meniscal tears have a more linear appearance than the globular high signal seen in chondrocalcinosis. Comparison with a conventional radiograph of the knee will help avoid this pitfall. However, chondrocalcinosis can also obscure a tear and result in a false-negative report (Fig) [16, 17]. Fig.: Chondrocalcinosis in medial meniscus. Radiograph of the knee (a) reveals meniscal calcifications in the posterior horn of the meniscus (arrow). Coronal PD-W (b) and sagittal PD-W images (c, d) show marked high signal throughout the posterior horn of medial meniscus (arrows) that resembles a tear. No meniscal tear was identified on arthroscopy. Page 28 of 40 Fig.: Chondrocalcinosis in lateral meniscus. Anteroposterior knee radiograph (a) shows meniscal calcifications in lateral meniscus (arrow). Sagittal PD-W image (b) shows high signal intensity both in the anterior and posterior horn of lateral meniscus with extension to inferior articular surface (arrowheads), interpreted as meniscal tears. No meniscal tear was found on arthroscopy. Meniscal ossification is a rare finding of unknown origin with a prevalence of 0,15% in MR examinations. Meniscal ossicles are frequently asymptomatic and discovered incidentally. They mimic intra-articular loose bodies and lead to inappropriate surgical treatment. Imaging is required to confirm the diagnosis and assess meniscal integrity. The typical appearance is that of an intrameniscal lesion which shows central high signal on T1-weighted images, due to normal fat bone marrow, surrounded by low signal on both T1-weighted and T2-weighted images related to the cortical rim. The high signal of the inner portion, which is the same as viable medullary bone, allows differentiation from loose bodies, which may present internal low signal. However, loose bodies, if ossified, may present with an internal high signal [18, 19]. Page 29 of 40 Gas within the knee joint may represent a vacuum phenomenon or iatrogenic placement during arthrography or joint aspiration. The low magnetic susceptibility of gas produces a discrete signal void. If the gas collects adjacent to the meniscus, it can simulate a meniscal tear, abnormal meniscal volume, or a displaced meniscal fragment (Fig.) [20]. Fig.: Gas within the knee joint (arrows) produces a discrete signal void on adjacent coronal T2 GRE (a, b) and T1-W images (c, d), as well as on sagittal T2-W images (eg), that simulates a radial meniscal tear in medial meniscus (arrowheads). Articular cartilage damage is another potentially confounding pathological condition that can resemble a tear. Articular cartilage defects and chondral fractures of the tibial, femoral, and patellar cartilage in children may mimic a bucket-handle meniscal tear on MRI [21]. POSTOPERATIVE CHANGES Page 30 of 40 In recent years, there has been increasing demand for postoperative evaluation of the meniscus because of the increased number of patients who undergo meniscal surgery. The most common surgical procedures include partial meniscectomy and meniscal repair. Recognition of the normal postoperative MRI appearance of the meniscus and of abnormalities is essential for the accurate assessment of symptomatic patients [22]. After partial meniscectomy, meniscal morphology may differ from that of a nonoperative meniscus with its postoperative appearance depending on the amount and anatomical location of meniscal tissue resected and the morphology of the previous meniscal tear. On MR imaging, such postsurgical variations in meniscal shape typically include diminution in the overall size of the meniscus or meniscal horns, blunting of the meniscal apical margin, or variable degrees of meniscal truncation (Fig.) [23]. Fig.: Diagram of medial meniscus (a) illustrating the two types of partial meniscectomy: circumferential (b)-where the posterior horn and anchor, and therefore Page 31 of 40 the meniscal "hoop" has been preserved and segmental (c)-where the posterior attachment has been resected and the load transmitting function has been sacrificed. Fig.: Normal appearance of a partially resected meniscus. Adjacent coronal PD-W fat sat images from anterior to posterior (a-c) demonstrate a small blunted body of medial meniscus (arrow) following circumferential partial meniscectomy. Page 32 of 40 Fig.: Normal appearance of a partially resected meniscus. Adjacent coronal PD-W fat sat images from anterior to posterior (a-c) demonstrate a resected posterior horn of medial meniscus (arrows) following segmental partial meniscectomy. Increased short TE intrameniscal signal extending to the meniscal articular surface after the operation may also be seen as a normal finding on MR imaging and may not be indicative of a recurrent tear (Fig.) [24]. Page 33 of 40 Fig.: Diagram illustrating the potential of creating an intrasubstance grade 3 signal intensity abnormality after meniscectomy. The dotted lines (a) show the planned incision in a torn meniscus. The surgeon resects the torn portion of the virgin meniscus after probing it. The resected fragment usually does not contain the entire linear area of abnormal signal intensity (straight line) seen on MRI. A grade 3 signal intensity abnormality extends to the articular surface after the operation (b) and mimics a tear in the untorn postoperative meniscus. Page 34 of 40 Fig.: Diminutive morphology of the posterior horn of medial meniscus on adjacent coronal PD-W fat sat (a, b) and sagittal PD-W images (c, d) following prior meniscectomy with intrameniscal increased signal intensity extending to the inferior meniscal surface (arrows), which was interpreted as new tear. Second-look arthroscopic evaluation revealed an intact meniscus. Page 35 of 40 Fig.: Intrameniscal increased signal intensity (arrows) on adjacent coronal PD-W fat sat (a-c) and sagittal PD-W images (d, e) in the resected posterior horn of medial meniscus after partial meniscectomy was interpreted as new tear. Second-look arthroscopy revealed normal signal postoperative changes. What is more, studies on meniscal repair have shown that linear increased signal intensity extending to the surface, which is indicative of healing process, can persist at the site of surgery for at least 1 year after repair (Fig.) [22]. Page 36 of 40 Fig.: Coronal PD-W fat sat image demonstrates linear increased signal (but not synovial fluid) (arrow) corresponding to a scar mimicking a new tear, 2 years after repair of a peripheral vertical tear in lateral meniscus. Thus, diagnosis of meniscal tears by using the usual criterion of linear increased signal intensity extending to the surface on conventional short echo time MR images may lead to a false-positive diagnosis in patients after meniscal repair. Use of the stricter criterion of fluid signal intensity within a linear defect in the meniscus on T2-weighted images has been shown to provide high specificity (88%-92%) but low sensitivity (41%-69%) for tears. Thus, the use of this stricter criterion with conventional MR imaging will result in fewer false-positive diagnoses; however, many tears will be missed [25]. For patients who have undergone partial meniscectomy, the accuracy of conventional MR imaging for detection of a tear is 66%-82%. Studies have shown accuracy similar to that found for evaluation of preoperative menisci in cases when only a small resection (less than 25%) is performed. Unfortunately, most resections are not small [25]. In an attempt to improve the accuracy of MR imaging for diagnosing retorn menisci, the use of direct MR arthrography, which involves the injection of intraarticular contrast material, has been proposed. MR arthrography is approximately 90% sensitive and specific for detecting retear of the postoperative meniscus. Advantages of MR arthrography over conventional MR imaging include the ability to obtain adequate joint distension, greater Page 37 of 40 penetration of contrast material and the ability to use T1-weighted images. On MR arthrograms, meniscal tears are diagnosed as areas of increased signal intensity (equal to that of intraarticular gadolinium contrast material) within the meniscus (Fig.) [26, 27]. Fig.: Sagittal T1-W fat-sat MR arthrography image following intra-articular injection of gadolinium demonstrates contrast extending into a subtle cleft (arrow) in the posterior horn of medial meniscus corresponding to a peripheral vertical tear, which was previously missed on conventional MRI. Conclusion MRI is a valuable tool for the evaluation of meniscal pathology. A thorough knowledge of potential pitfalls mimicking meniscal tears is essential if one is to maximize diagnostic accuracy. 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