ライフサイエンスコーパス: rotator cuff

1 plete- and 12 partial-thickness tears of the rotator cuff.

2 r was present in the anterior portion of the rotator cuff.

3 h tendon tears in the anterior aspect of the rotator cuff.

4 nventional SE sequence for evaluation of the rotator cuff.

5 sion criteria included a full-thickness torn rotator cuff.

6 ective care for patients suspected of having rotator cuff abnormality.

7 ative rotator cuff, patients with a repaired rotator cuff, and patients who have undergone shoulder r

8 the expected location and orientation of the rotator cuff cable.

9 le option for symptom relief associated with rotator cuff calcific deposits.

10 Two radiologists graded rotator cuff contact on a three-point scale.

11 To prospectively evaluate rotator cuff contact with the glenoid in healthy volunte

12 In 238 patients with rotator cuff diagnoses at surgery, preoperative magnetic

13 Rotator cuff disease (RCD) is the most common cause of s

14 to guide the imaging evaluation of suspected rotator cuff disease in patients with a native rotator c

15 painful shoulders with clinically suspected rotator cuff disease.

16 ermine their relationship to patient age and rotator cuff disorders.

17 nologists to astronaut operators to complete rotator cuff evaluation.

18 Common injury sites include the rotator cuff, glenohumeral joint, acromioclavicular join

19 n; extraarticular contrast material leakage; rotator cuff, glenoid labrum, and anterior capsule consp

20 Rotator cuff grading was similar for fast SE and convent

21 endations will lead to greater uniformity in rotator cuff imaging and more cost-effective care for pa

22 lgorithm was tested on coronal images of the rotator cuff in a series of 144 patients, and the improv

23 reliable detection of calcifications in the rotator cuff in patients with calcific tendonitis by usi

24 Rotator cuff injury is a very common pathology in patien

25 y and specificity to MRI in the diagnosis of rotator cuff injury.

26 sterior and anterior cystic abnormalities at rotator cuff insertion site on the greater tuberosity an

27 Distances between the rotator cuff insertion sites and the glenoid decreased i

28 r and intertechnique agreement for detecting rotator cuff lesions were measured and compared with kap

29 rography and MR arthrography in depiction of rotator cuff lesions.

30 Standard rotator cuff MR sequences yielded a sensitivity of 59% (

31 er sensitivity and specificity than standard rotator cuff MR sequences.

32 For grading fatty infiltration of rotator cuff muscles, kappa and Z statistics were used.

33 e to microgravity than the joint-stabilizing rotator cuff muscles.

34 elping identify abnormalities that may mimic rotator cuff or labral abnormalities at clinical examina

35 fect on image quality or on the depiction of rotator cuff or labral tears.

36 re was no difference in the detectability of rotator cuff or labral tears.

37 tator cuff disease in patients with a native rotator cuff, patients with a repaired rotator cuff, and

38 o surgical procedures (open and arthroscopic rotator cuff repair).

39 was associated with impingement syndrome and rotator cuff rupture (n = 2).

40 ity; and partial-thickness or full-thickness rotator cuff tear and labral tear detectability.

41 ck of similarity between the impingement and rotator cuff tear groups.

42 If rotator cuff tear was present, tendon retraction and loc

43 arthrography had 100% accuracy in depicting rotator cuff tear, whereas both indirect MR arthrography

44 t accurate for diagnosis of a full-thickness rotator cuff tear.

45 confirm the presence or absence of labral or rotator cuff tear.

46 t labral tear and 88% in depicting recurrent rotator cuff tear.

47 e presence or absence of recurrent labral or rotator cuff tear.

48 romiale ( OR odds ratio = 138, P < .001) and rotator cuff tears ( OR odds ratio = 5.4, P = .015) afte

49 roups: those without shoulder impingement or rotator cuff tears (31 patients), those with shoulder im

50 er impingement (22 patients), and those with rotator cuff tears (31 patients).

51 erformed well with respect to full thickness rotator cuff tears (FTT).

52 ultrasound (USG) and MRI in the diagnosis of rotator cuff tears (RCT) and to determine if high resolu

53 Rotator cuff tears (RCTs) represent a significant propor

54 (SGHL), presence of biceps tendinopathy, and rotator cuff tears adjacent to the rotator interval.

55 nt to the development of an os acromiale and rotator cuff tears after age 25 years.

56 r and intertechnique agreement for measuring rotator cuff tears and grading muscle fatty infiltration

57 shows promising results in the diagnosis of rotator cuff tears and in differentiating partial from c

58 skeletal pain caused, among other things, by rotator cuff tears due to narrowing of subacromial space

59 luate the prevalence of partial and complete rotator cuff tears in magnetic resonance images of patie

60 However, the diagnosis of rotator cuff tears is controversial.

61 with the development of an os acromiale and rotator cuff tears later in life was assessed with follo

62 ifference between US and MRI in detection of rotator cuff tears of any type (RCT) or FTT.

63 otal of 40 patients were diagnosed as having rotator cuff tears on ultrasound (USG) and MRI.

64 s, 31 patients who had positive findings for rotator cuff tears on ultrasound and/or MRI were finally

65 study, 40 patients with clinically suspected rotator cuff tears underwent both ultrasound and MRI of

66 s performed to assess for joint subluxation, rotator cuff tears, tendinosis, subacromial-subdeltoid b

67 In the diagnosis of rotator cuff tears, the strength of agreement between ul

68 s the investigation of choice for diagnosing rotator cuff tears.

69 it a modality of first choice for evaluating rotator cuff tears.

70 terature on the causes and classification of rotator cuff tears.

71 ess the accuracy of US and MRI in diagnosing rotator cuff tears.

72 ry cause of shoulder impingement syndrome or rotator cuff tears.

73 st consistent positive treatment effects for rotator cuff tendinitis were achieved by ultrasound-guid

74 ded fibrillar structure perpendicular to the rotator cuff tendon (average thickness and width, 1.2 mm

75 diagnostic performance for the evaluation of rotator cuff tendon tears.

76 se but no alteration in the depiction of the rotator cuff tendons or glenoid labrum.

77 hematoxylin-eosin stain) from three resected rotator cuff tendons were inspected for fibers in the ex

78 omial pain for at least 3 months with intact rotator cuff tendons, were eligible for arthroscopic sur

79 r than in conjunction with injuries to other rotator cuff tendons.

80 spected of having calcific tendonitis of the rotator cuff were included.

81 n in cases of partial-thickness tears of the rotator cuff with a horizontal component.

82 Two radiologists independently graded the rotator cuff with separate and side-by-side assessment o