ライフサイエンスコーパス: bone marrow edema

1 eted virtual noncalcium images for traumatic bone marrow edema.

2 epth and cross-sectional area of subchondral bone marrow edema.

3 n in 3 of the control subjects (18%), but no bone marrow edema.

4 l noncalcium images were evaluated to detect bone marrow edema.

5 s to be osteoarthritis, stress fracture, and bone marrow edema.

6 ts, foci of wall susceptibility, osteolysis, bone marrow edema, abductor muscle or tendon abnormality

7 The lessening of bone marrow edema after anti-TNF therapy provides furthe

8 The presence of bone marrow edema and abductor tendon tears but not the

9 The presence of soft-tissue edema, bone marrow edema, and bone spur formation at the attach

10 RI showed that 96% had synovitis and 46% had bone marrow edema, and US showed that 73% had gray-scale

11 Bone marrow edema appears after a few weeks from occurre

12 synovium, and, less commonly, pisotriquetral bone marrow edema are MR imaging findings that may help

13 Calcaneus bone marrow edema at the insertion site was observed in

14 While bone marrow edema (BME) detected by magnetic resonance i

15 body, posterior element, and spinous process bone marrow edema (BME) lesions, were scored in a blinde

16 cation and severity of defects of cartilage, bone marrow edema (BME), osteophytes, subchondral cysts,

17 Bone marrow edema correlates with inflammation severity,

18 ions of these in clinical practice-urate and bone marrow edema detection, metal artifact reduction, a

19 of 14 bones): cartilage defects, bone cysts, bone marrow edema, fractures, joint debris, joint effusi

20 After ESWT, the extant of bone marrow edema had increased in one heel and had newl

21 capsule distention, and (e) the location of bone marrow edema, if any.

22 (VNCa) technique for detection of traumatic bone marrow edema in patients with vertebral compression

23 moral condyle and lateral tibial plateau and bone marrow edema in the lateral femoral condyle.

24 l outcome and severity of cartilage loss and bone marrow edema in the medial femoral condyle and medi

25 with greater severity of cartilage loss and bone marrow edema in the same compartment as the menisca

26 noncalcium technique may enable depiction of bone marrow edema in thoracolumbar vertebral compression

27 agnostic performance for assessing traumatic bone marrow edema in vertebral compression fractures.

28 epth and cross-sectional area of subchondral bone marrow edema increased with increasing grade of the

29 Bone marrow edema is a potent risk factor for structural

30 miquantitative Leeds Scoring System in which bone marrow edema is graded from 0 to 3 according to sev

31 VIPR-SSFP helped detect 69.3% of bone marrow edema lesions identified at routine MR.

32 eral collateral ligament tears, and 85.3% of bone marrow edema lesions identified on images obtained

33 Bone marrow edema lesions on magnetic resonance imaging

34 were used to evaluate the relation of medial bone marrow edema lesions to medial progression and late

35 llateral ligament tears, meniscal tears, and bone marrow edema lesions within the knee joint at 3.0 T

36 cruciate ligament tears, meniscal tears, and bone marrow edema lesions, first by using routine MR and

37 at helping detect lateral meniscal tears and bone marrow edema lesions.

38 lesions, ligament tears, meniscal tears, and bone marrow edema lesions.

39 ficantly less subchondral bone attrition and bone marrow edema-like abnormalities in the knee as asse

40 The newest studies reveal that bone marrow edema may be a more sensitive indicator of t

41 as a significantly greater degree of diffuse bone marrow edema (median of 6.5 tarsal bones versus 2 a

42 We recorded bone marrow edema on STIR images from each vertebral bod

43 CT numbers for the diagnosis of bone marrow edema on the basis of MR imaging revealed ar

44 alyzed by two readers for cartilage lesions, bone marrow edema pattern, and ligamentous and meniscal

45 Cartilage lesions, bone marrow edema pattern, and meniscal and ligamentous

46 showed full-thickness cartilage lesions and bone marrow edema pattern.

47 Bone marrow edema (present in six asymptomatic patients

48 Bone marrow edema presents with increased signal in T2-w

49 and lumbar spine that were scored for active bone marrow edema representative of acute inflammation,

50 ylosing spondylitis, present in MRI include: bone marrow edema, sclerosis, fat metaplasia, formation

51 eviewed for findings including hernia, pubic bone marrow edema, secondary cleft sign, and rectus abdo

52 magnetic resonance (MR) imaging of transient bone marrow edema syndrome (TBMES) and avascular osteone

53 is indicated by the presence of subchondral bone marrow edema, synovitis, bursitis, or enthesitis.

54 s a group of patients with more severe axial bone marrow edema that is likely related to the classic

55 Six of the SpA patients had bone marrow edema that was maximal at entheseal insertio

56 ess the post-ESWT changes in soft-tissue and bone marrow edema, the thickness of the proximal plantar

57 n to adjacent cartilage and underlying bone, bone marrow edema underneath graft, and contour of bone

58 re used to determine the association between bone marrow edema volume and IKDC score.

59 was no significant association between total bone marrow edema volume and preoperative or postoperati

60 Bone marrow edema volume was quantified by using segment

61 Subchondral bone marrow edema was also seen beneath four (1.4%) of 2

62 Calcaneal bone marrow edema was present in four volunteers (5.2%).

63 Subchondral bone marrow edema was seen beneath 105 (19%) of 554 arti

64 Although bone marrow edema was seen globally in similar frequenci

65 patients without synovitis), pisotriquetral bone marrow edema was seen only in patients with synovit

66 correlate MR imaging findings of subchondral bone marrow edema with the arthroscopic grade of articul

67 the size, depth, and location of subchondral bone marrow edema without knowledge of the arthroscopic