ライフサイエンスコーパス: humerus

1 ed with a site in the appendicular skeleton (humerus).

2 differences were not detected in the distal humerus.

3 nts with displaced fractures of the proximal humerus.

4 magnetic resonance (MR) imaging of the right humerus.

5 ns frequently affected the femur, tibia, and humerus.

6 l and endosteal surfaces of the mandible and humerus.

7 resented by only a proximal femur and distal humerus.

8 With a powerfully-constructed humerus 1.76 m in length, Notocolossus is one of the lar

9 empts were made into either the tibia or the humerus; 192 were unsuccessful, with an overall success

10 ania from Myanmar, including a complete left humerus, a fragmentary right humerus, parts of left and

11 ris tendon from the lesser tuberosity of the humerus, accompanied by medial dislocation of the biceps

12 to the base of the medial epicondyle of the humerus and distally to the medial aspect of the coronoi

13 t were drawn around the head and neck of the humerus and femur (both sides) and around lumbar vertebr

14 the compound structures observed around the humerus and femur of Kulindadromeus are support fibers a

15 In the stylopod (humerus and femur) and sternum, bone marrow MSCs express

16 ressed most indices of bone formation in the humerus and mandible, while NE decreased some indices of

17 and second moments of area of the mid-distal humerus and midshaft femur.

18 periosteal and endocortical surfaces of the humerus and the periosteal and cancellous bone surfaces

19 lable for three different bone sites (femur, humerus and tibia), very little variation with bone site

20 The humerus and ulna indicate that Pondaungia was capable of

21 croarchitecture in weight bearing (femur and humerus) and non-weight bearing (2(nd) lumbar vertebra a

22 cipally located in the tibia, femur, pelvis, humerus, and spine and, in most cases, presented the ima

23 of the lower limb bones and strength of the humerus are much smaller and less consistent.

24 At 4 wk of implantation in the rabbit humerus, control-released TGF-beta1 from porous implants

25 ern blot of human osteoclastoma or fetal rat humerus demonstrated bands of 38 and 27 kDa, consistent

26 or stage 27 chick embryos severely affected humerus development.

27 sis of non-pathological fracture of the hip, humerus, distal tibia, wrist, or vertebrae between Octob

28 Smaller body size was not a risk factor for humerus, elbow, wrist ankle, or foot fractures.

29 clinical trial, the Proximal Fracture of the Humerus Evaluation by Randomization (PROFHER) trial, rec

30 s present in stage 27 (Day 5.5) chick embryo humerus exhibited low and diffuse expression of RARalpha

31 tant embryo has four limbs with recognizable humerus/femur bones that have anterior-posterior polarit

32 incidence of nonvertebral fracture (proximal humerus, forearm, hip) in adult kidney transplant recipi

33 t problems, increased the odds of a proximal humerus fracture (adjusted odds ratio = 1.65, 95% confid

34 This case-control study of proximal humerus fracture included 448 incident female and male c

35 ould likely reduce the frequency of proximal humerus fracture.

36 h a higher risk of frailty (hip and proximal humerus) fractures but not fractures at other sites.

37 A tetrapod humerus from the Late Devonian of Pennsylvania has a nov

38 utomatically classify nine anatomical terms: humerus, handplate, fibula, tibia, femur, ribs, petrous

39 ultrasonography to determine femur (FLZ) and humerus (HLZ) length z scores.

40 ve the radial head in adults, and the distal humerus in children.

41 taining a displaced fracture of the proximal humerus involving the surgical neck.

42 Its 1.69-meter-long humerus is longer than that of any known Cretaceous saur

43 ghtly larger size, the Arctic presbyornithid humerus is not distinguishable from fossils of Presbyorn

44 scapularis from the lesser tuberosity of the humerus is rare in the pediatric population and only a c

45 Moreover, humerus length and bone mineral content were decreased,

46 tal head circumference, biparietal diameter, humerus length, abdominal circumference, femur length an

47 7 wk was associated with increased femur and humerus lengths at 28 wk.Maternal weight gain was associ

48 al tibia (n = 7), distal radius and proximal humerus (n = 3), and calcaneus and public ramus (n = 2).

49 orearm (n = 1,000), foot (n = 827), proximal humerus (n = 448), shaft of the tibia/fibula (n = 168),

50 orearm (n = 1,016), foot (n = 574), proximal humerus (n = 467), pelvis (n = 150), and shaft of the ti

51 femur (n = 17; 50%), tibia (n = 9; 26%), and humerus (n = 5; 15%).

52 The lesions were located in the proximal humerus (n = 7), proximal tibia (n = 4), proximal femur

53 ur but had no effect on cortical bone in the humerus or calvarium.

54 oward specific skeletal elements such as the humerus or digits.

55 orphometric indices of bone formation in the humerus or mandible.

56 A primary tumor site in the proximal humerus or proximal femur and an elevated serum alkaline

57 mary outcome was nonvertebral fracture (hip, humerus, or radius or ulna) within 12 months of treatmen

58 with a first diagnosed fracture of the hip, humerus, or wrist; up to 4 controls, matched by age, sex

59 a complete left humerus, a fragmentary right humerus, parts of left and right ulnae, and the distal h

60 muscle activity at the primary movers of the humerus (pectoralis major (PM), anterior (AD) and poster

61 al: 0.99, 2.04) and fracture of the proximal humerus (rate ratio = 1.79, 95% confidence interval: 1.0

62 The morphology of a large well-preserved humerus supports identification of a new volant, possibl

63 T-PCR revealed a higher turnover rate in the humerus than in lumbar vertebrae, suggesting enhanced bo

64 ced a nonadaptive correlated response in the humerus that overwhelmed its own trait-specific response

65 re complex featherlike structures around the humerus, the femur, and the tibia.

66 tern was femur (OR, 20.6; 95% CI, 8.4-48.1), humerus, then vertebra/ribs.

67 st fracture was a comminuted fracture of her humerus three years ago, when she stumbled and fell forw

68 iceps brachii muscle tendon and connects the humerus to the ulna.

69 d gradient-echo in vivo images of the femur, humerus, upper spine, and lower spine were acquired for

70 cation of tumour (proximal femur or proximal humerus vs other limb vs axial skeleton); and presence o

71 ntradiction to ecogeographic hypotheses, the humerus was under directional selection for longer value

72 y positively associated with fetal femur and humerus z scores (P < 0.01).

73 Fetal femur and humerus z scores and neonatal birth length were signific

74 25(OH)D was associated with fetal femur and humerus z scores only when maternal calcium intake was <

75 times across gestation, and fetal femur and humerus z scores were generated.