ライフサイエンスコーパス: lower leg

1 ncluded patients treated with casting of the lower leg.

2 nes fractures of the arm, forearm, thigh and lower leg.

3 action, CNS control and other muscles in the lower leg.

4 an adapted muscle activation pattern in the lower leg.

5 between the beta3 headpiece and the alphaIIb lower leg.

6 he anterior and peroneal compartments of the lower leg.

7 ional imaging during scratching of the right lower leg.

8 oot and during the later growth phase in the lower leg.

9 he digits, and only two were on the ankle or lower leg.

10 ired to pattern the skeletal elements of the lower leg.

11 ble at the upper arm and the finger, not the lower leg.

12 posterior, and superficial posterior) of the lower leg.

13 alogue scale, VAS), and circumference of the lower leg.

14 ch marked the shortening of the forearms and lower legs.

15 que to measure rotational deformities in the lower legs.

16 le CSA [thigh: 1.8% (0.6%, 2.9%), P = 0.003; lower leg: 0.9% (0.3%, 1.6%), P = 0.005], balance eyes c

17 defect preferentially affecting the lateral lower leg, a theory that accounts for similar findings i

18 ms largely from parasagittal rotation of the lower leg about the knee joint.

19 The ovine sural nerve descended to the lower leg along the short saphenous vein.

20 Some patients with lower leg amputations may be candidates for motorized pr

21 e posterior and anterior compartments of the lower leg and considerable affection of proximal leg mus

22 nd their valves, the gastrocnemius and other lower leg and foot muscles as well as the nerves supplyi

23 st 20 foci of in-transit disease in the left lower leg and foot, as well as a solitary lung metastasi

24 Images of the lower leg and wrist were acquired in five volunteers eac

25 most common clinical sign is weakness in the lower legs and feet, associated with muscle atrophy and

26 particularly the anterior compartment of the lower leg, and is the subject of this review.

27 Across taxa, afferents from the tail, foot, lower leg, and upper leg terminated in a mediolateral se

28 ers, two thermoluminescent dosimeters at the lower legs, and a thermoluminescent dosimeter on the for

29 he anterior and peroneal compartments of the lower leg appears to be safe with regard to the results

30 structure of the recombinant ectodomain, the lower legs are not parallel, straight, and adjacent.

31 nd superficial posterior compartments of the lower legs, as well as the total MNSI, showed significan

32 rectus calvaria (skull caps) and two tibiae (lower leg bones) were discovered from a bone bed located

33 llofemoral pain syndrome; chronic exertional lower-leg compartment syndrome, ankle sprains, and refle

34 The conditions were no compression (NONE), lower leg compression (LEG), abdominal/thigh compression

35 of muscle and intra-muscular fat within the lower leg could provide a valuable addition to current c

36 Closed-bone fracture (right lower leg; external fixation) and/or soft-tissue trauma

37 n (thigh fat fraction R(2) = 0.35, p = 0.01; lower leg fat fraction R(2) = 0.49, p < 0.01).

38 r recordings within spinal cord MN pools for lower leg flexor and extensor muscles and the electromyo

39 Multimorbidity and proximal or lower leg fractures were associated with increased morta

40 Pelvis/hip, vertebral, and lower leg fractures were the most prevalent fracture typ

41 r facial bones, pelvis, ribs or sternum, and lower leg fractures) compared with matched comparators.

42 lthy-weight subjects and was associated with lower leg glucose disposal (LGD) (63%) in obese men.

43 Knemometry assessing short-term lower-leg growth rate (LLGR) is a more rarely used alter

44 Two vaccinees presented with purpura of the lower legs; histological findings indicated cutaneous va

45 In other word the right lower legs in our study were more likely to be in varus

46 o were English-speaking and did not report a lower leg injury within the past 2 months or a concussio

47 Rather, the alphaIIb lower leg is bent between the calf-1 and calf-2 domains

48 ism after knee arthroscopy or casting of the lower leg is disputed.

49 s not, however, appear to be associated with lower leg lean mass or strength.

50 Head circumference and lower leg longitudinal growth were also similar, as was

51 As compared with lower leg measurements of AP, finger measurements were,

52 We retrospectively analyzed lower leg MRI data of 107 CMT1A patients.

53 MNSIs of the muscle compartments in lower leg MRI, obtained using an automated segmentation

54 izing muscle signal intensity on T1-weighted lower leg MRIs in Charcot-Marie-Tooth disease type 1 A (

55 Moreover, anterior lower leg MTR correlated strongly with strength of ankle

56 (31)P-MRS/(31)P-MRI may be used to quantify lower leg muscle oxidative metabolism in HF patients, wi

57 small-for-age and that 80% had at least one lower leg muscle that was small-for-age.

58 similar shape to reference curves for total lower leg muscle volume.

59 nstruct muscle-specific reference curves for lower leg muscle volumes in children aged 5 to 15 y.

60 with cerebral palsy in our cohort had total lower leg muscle volumes that were small-for-age and tha

61 t of a reduction in the resistive force from lower leg muscles 130 ms after the visual motion onset.

62 The analysis of the mechanical dynamics of lower leg muscles highlights a resonant response to WBVs

63 We imaged the lower leg muscles of ten healthy volunteers (total exper

64 Volumes of 10 lower leg muscles were measured from magnetic resonance

65 rs, glutei and posterior thigh groups, while lower leg muscles were relatively spared even in advance

66 This calls for more targeted exercises for lower leg muscles with vital roles as ankle joint stabil

67 nalyzed with respect to the integrity of the lower-leg musculotendinous units, presence of fluid coll

68 chemical shift imaging were performed on the lower legs of 10 healthy volunteers at rest.

69 During xenodiagnosis, the forearms or lower legs of participants were exposed to 30-35 female

70 The lower legs of six CTEV (2 bilateral, 4 unilateral) and f

71 neous fat, tibia, fibula and arteries in the lower legs of teenagers and young adults with CTEV using

72 oposed fully digital technique we found that lower legs of the human adults were symmetrical in axial

73 ate (ATP) metabolic fluxes in muscles of the lower leg on a clinical 3.0 T MR scanner.

74 Nineteen patients with activity-related lower leg pain and tenderness on palpation along the pos

75 egative and HC participants in the upper and lower leg (plantar flexors [PF], 62% vs 78% vs 89%; P <

76 ng vascular studies of the hands, brain, and lower leg regions.

77 cal findings, and muscle weight ratio of the lower leg showed recovery of the nerve function by inter

78 and fasting serum glucose were measured, and lower-leg skeletal muscle composition was assessed with

79 Lower leg skin sodium content was measured using magneti

80 2) (means +/- s.d.) who underwent unilateral lower leg suspension for 23 days; five were studied betw

81 asive and invasive readings was worse at the lower leg than that observed at the upper arm or the fin

82 and noninvasive readings of AP taken at the lower leg, the finger, and the upper arm.

83 In the lower leg, the numbers of capillaries increased.

84 vine, CA), and an oscillometric cuff (at the lower leg then the upper arm).

85 Here we refined and evaluated the lower leg trajectory error (LLTE) framework, a novel qua

86 wrist were acquired in five volunteers each (lower leg: two men and three women aged 24, 24, 49, 30,

87 further 2 min thereafter, circulation to the lower leg was occluded by inflation of a thigh cuff to a

88 0.35) and (35)Cl (40/0.6) MR imaging of both lower legs was performed with a 7-T whole-body system in

89 Fat-selective MR images of the lower leg were taken in 8 normal-weight [body mass index

90 Three dimensional CT images of the lower legs were bilaterally reconstructed.

91 rial College, CT images of 10 pairs of human lower legs were retrieved.

92 KE, 32 msec vs 31 msec; P = .002) and in the lower leg when compared with participants without DPN (P