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4 n and function were assessed preoperatively; meniscal and cartilage abnormalities were documented at
5 n and function were assessed preoperatively; meniscal and cartilage abnormalities were documented at
8 ide whether to refer patients with potential meniscal and ligament injuries, and we prefer clinical c
10 lage lesions, bone marrow edema pattern, and meniscal and ligamentous lesions were frequently demonst
12 Baker cyst, effusion, internal derangement (meniscal and/or anterior cruciate ligament tears), media
13 , osteophytes, subchondral cysts, sclerosis, meniscal and/or ligamentous tears, joint effusion, synov
15 orn (P <.05), and enhancement of the lateral meniscal body was greater than that of the medial menisc
16 19.7%, P < .0001) but not in the group with meniscal but no root tear (76.7% vs 65.2%, P = .055).
17 vances in the understanding of the nature of meniscal calcification and its relationships with menisc
18 ve identified a guinea pig OA model in which meniscal calcification appears to correlate with aging a
25 cond group of six monkeys (group 2), porcine meniscal cartilage and porcine articular cartilage plugs
29 or possible human transplantation, xenograft meniscal cartilage was transplanted from pigs and cows i
30 nees, HB-IGF-1 was retained in articular and meniscal cartilage, but not in tendon, consistent with e
36 Only PC-1 was abundant at the perimeter of meniscal cells and in association with meniscal cell-der
37 transfected the isozymes in nonadherent knee meniscal cells cultured with ascorbic acid, beta-glycero
41 ene expression suggest that in older adults, meniscal cells might dedifferentiate and initiate a prol
42 direct transfection of chondrocytic TC28 and meniscal cells, both induced matrix apatite deposition.
43 ene-expression profile different from normal meniscal cells, have elevated expression of ankylosis pr
50 h included meniscal displacement, peripheral meniscal corner tears, increased perimeniscal signal int
54 everal MR features (eg, bone marrow lesions, meniscal damage and extrusion, and synovitis or effusion
55 ed and older adults, any association between meniscal damage and the development of frequent knee pai
56 we found no independent association between meniscal damage and the development of frequent knee sym
57 cted tibial and femoral loss included medial meniscal damage and varus malalignment (medially) and la
58 in seems to be present because both pain and meniscal damage are related to OA and not because of a d
59 each predictor (meniscal position factor and meniscal damage as dichotomous predictors in each model)
60 ned lateral cartilage damage and progressive meniscal damage as increases in cartilage or meniscus sc
62 paucity of data regarding the prevalence of meniscal damage in the general population and the associ
66 h there was a modest association between the meniscal damage score (range 0-3) and the development of
67 nded to the case-control status assessed the meniscal damage using the following scale: 0 = intact, 1
70 adjusted for age, sex, and body mass index), meniscal damage was mostly present in knees with OA.
72 The aim of this study was to test whether meniscal damage, meniscal extrusion, malalignment, and l
73 d for cartilage damage, bone marrow lesions, meniscal damage, meniscal extrusion, synovitis, and effu
74 cartilage damage, the presence of high BMI, meniscal damage, synovitis or effusion, or any severe ba
77 body mass index (BMI), bone marrow lesions, meniscal damage/extrusion, synovitis, effusion, and prev
79 cal calcification and its relationships with meniscal degeneration and cartilage lesions in osteoarth
81 dels demonstrated that meniscal position and meniscal degeneration each contributed to prediction of
83 redictor variables were MRI cartilage score, meniscal degeneration, and meniscal position measures.
85 calcification is positively associated with meniscal degeneration, which is an early event in the de
91 f meniscocapsular separation, which included meniscal displacement, peripheral meniscal corner tears,
92 Meniscal displacement (measured from the meniscal edge to the tibia) was as great as 10 mm medial
93 e changes in the Lysholm and Western Ontario Meniscal Evaluation Tool (WOMET) scores (each ranging fr
95 or tibiofemoral cartilage loss were baseline meniscal extrusion (adjusted OR 3.6 [95% CI 1.3-10.1]),
96 ars (adjusted OR, 3.19; 95% CI: 1.13, 9.03), meniscal extrusion (adjusted OR, 3.62; 95% CI: 1.34, 9.8
97 ication of tibio-femoral osteophytes, medial meniscal extrusion and medial femoral cartilage morpholo
100 age, knee effusion, and body mass index with meniscal extrusion were assessed by using logistic regre
102 femoral articular cartilage, osteophytes and meniscal extrusion, and of radiographic assessment of jo
103 nt as the meniscal tear, greater severity of meniscal extrusion, greater overall severity of joint de
104 s study was to test whether meniscal damage, meniscal extrusion, malalignment, and laxity each predic
105 amage, bone marrow lesions, meniscal damage, meniscal extrusion, synovitis, and effusion prior to rep
106 ion between clinical outcome and severity of meniscal extrusion, total BLOK score, and meniscal tear
108 t, and cartilage damage were associated with meniscal extrusion, with odds ratios (ORs) of 6.3 (95% c
109 t, and cartilage damage were associated with meniscal extrusion, with ORs of 10.3 (95% CI: 7.1, 14.9)
113 ars are not the only factors associated with meniscal extrusion; other factors include knee malalignm
114 on to determine the relative contribution of meniscal factors and cartilage morphologic features to J
122 effusions were seen in 26 (87%) of 30 knees, meniscal hypoplasia in 11 (37%) of 30 knees, and abnorma
124 diagnostic certainty was greatest for medial meniscal injuries (30%), followed by lateral meniscal in
126 ynovial pathology in patients with traumatic meniscal injuries and determine the relationships betwee
127 ynovial pathology in patients with traumatic meniscal injuries and determine the relationships betwee
131 d (SF) from patients with early knee OA with meniscal injury could lead to inflammatory activation of
132 onstrate that sCD14 in the setting of OA and meniscal injury sensitizes FLS to respond to inflammator
134 ngs indicate that in patients with traumatic meniscal injury undergoing arthroscopic meniscectomy wit
135 n, a feature of both osteoarthritis (OA) and meniscal injury, is hypothesized to be triggered in part
136 s were found in 95 (79.0%) of 120 knees, and meniscal lesions were found in 54 (45%) of 120 knees.
140 sions (OR, 4.00; 95% CI: 1.75, 9.16), medial meniscal maceration (OR, 1.84; 95% CI: 1.13, 2.99), effu
141 e medial tibiofemoral joint, each measure of meniscal malposition was associated with an increased ri
143 n intermediate-weighted images, (b) abnormal meniscal morphology, (c) likelihood of a typical postope
144 morphology, subchondral bone marrow lesions, meniscal morphology/extrusion, synovitis, and effusion.
149 efects of cartilage, osteophytes, sclerosis, meniscal or ligamentous tears, joint effusion, and synov
152 Loading also led to osteophyte formation, meniscal ossification, synovial hyperplasia and fibrosis
153 nt of synovial inflammation in patients with meniscal pathology; they also represent potential therap
154 nt of synovial inflammation in patients with meniscal pathology; they also represent potential therap
155 variance explained in JSN, and the change in meniscal position accounts for a substantial proportion
156 change in medial joint space, both change in meniscal position and change in articular cartilage scor
157 he results from the models demonstrated that meniscal position and meniscal degeneration each contrib
158 used to assess the effect of each predictor (meniscal position factor and meniscal damage as dichotom
161 5 plates of each tibiofemoral joint, and the meniscal position was measured using eFilm Workstation s
162 ent of meniscal morphologic characteristics, meniscal position, and cartilage morphologic characteris
165 pair in vitro and therefore may also inhibit meniscal repair during arthritis or following joint inju
166 that IL-1Ra and TNF mAb promoted integrative meniscal repair in an inflammatory microenvironment sugg
167 concentrations of IL-1 and TNFalpha inhibit meniscal repair in vitro and therefore may also inhibit
172 Sixteen of 61 patients with more than 25% meniscal resection needed MR arthrography to demonstrate
174 meniscal resection, those with less than 25% meniscal resection, and those with meniscal repair.
175 into three groups: those with more than 25% meniscal resection, those with less than 25% meniscal re
176 nty-nine patients had clear MR evidence of a meniscal retear without any contrast material injected i
179 er overall severity of joint degeneration, a meniscal root tear, and a longer meniscal tear at preope
180 d spin-echo coronal and sagittal imaging for meniscal scoring and axial and coronal spoiled gradient
182 ne and knee replacement (KR) associated with meniscal surgery in subjects with and those without a re
183 ubjects without a reported preceding trauma, meniscal surgery is not independently associated with in
190 root tear than in the group without root or meniscal tear (76.7% vs 19.7%, P < .0001) but not in the
192 tic patients 45 years of age or older with a meniscal tear and evidence of mild-to-moderate osteoarth
193 She has undergone arthroscopic surgery for a meniscal tear and has taken nonsteroidal anti-inflammato
194 meniscectomy for symptomatic patients with a meniscal tear and knee osteoarthritis results in better
197 tilage damage in the root tear group and the meniscal tear group, with the no tear group serving as a
203 most always associated with a far peripheral meniscal tear or with a meniscocapsular junction injury
204 odel, the hazard ratio for developing medial meniscal tear was 18.2 (95% confidence interval: 8.3, 39
205 igns of osteoarthritis), the prevalence of a meniscal tear was 63% among those with knee pain, aching
207 solated medial posterior root tear, 294 with meniscal tear without root tear, and 264 without menisca
208 separated into three groups: root tear only, meniscal tear without root tear, and neither meniscal no
209 fect was used to evaluate the risk of medial meniscal tear, adjusting for age, sex, body mass index,
211 ificant associations (P < .01) for effusion, meniscal tear, and degenerative arthropathy, independent
213 marrow edema in the same compartment as the meniscal tear, greater severity of meniscal extrusion, g
220 ccuracy (P = .05) for helping detect lateral meniscal tears (73.2% sensitivity and 88.4% accuracy for
221 interval [CI]: 1.01, 1.23), the presence of meniscal tears (adjusted OR, 3.19; 95% CI: 1.13, 9.03),
222 ely to have defects of cartilage (P = .001); meniscal tears (P = .001); and osteophytes, subchondral
223 medial meniscal tears (P = .04) and lateral meniscal tears (P = .01) and significantly higher accura
225 ntly higher sensitivity for detecting medial meniscal tears (P = .04) and lateral meniscal tears (P =
228 These will be discussed in reference to meniscal tears and injuries of the cruciate ligaments as
235 Sixty-one percent of the subjects who had meniscal tears in their knees had not had any pain, achi
237 The parameters for detecting 31 lateral meniscal tears were 58.0%, 90.6%, and 80.0% for IDEAL GR
238 espective parameters for detecting 50 medial meniscal tears were 85.0%, 91.1%, and 87.9% for IDEAL GR
241 ents undergoing arthroscopy for degenerative meniscal tears were recruited under Institutional Review
242 he general population and the association of meniscal tears with knee symptoms and with radiographic
243 four with flouncelike folds associated with meniscal tears) with an S-shaped fold in the free edge o
244 e ligament tears, collateral ligament tears, meniscal tears, and bone marrow edema lesions within the
245 erior and posterior cruciate ligament tears, meniscal tears, and bone marrow edema lesions, first by
247 s were analyzed, including ACL tears, medial meniscal tears, and other lateral femorotibial compartme
248 d to functional knee instability, subsequent meniscal tears, and the development of early degenerativ
249 vitis in posttraumatic joint injury, such as meniscal tears, and the protective role of the pericellu
251 Cross-sectional associations of severity of meniscal tears, knee malalignment, tibiofemoral cartilag
261 to injured joints stimulates regeneration of meniscal tissue and retards the progressive destruction
262 ential means of examining the time course of meniscal tissue change in the development and progressio
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