ライフサイエンスコーパス: humeral

1 for gravitational assistance and to provide humeral abduction and adduction under cortical control.

2 Overall, Pondaungia humeral and calcaneal morphology is most consistent with

3 ved immunogenicity or dual induction of both humeral and cellular systems.

4 cus, echogenic bowel, renal pyelectasis, and humeral and femoral shortening.

5 Humeral and ulnar characters are primitive and like thos

6 antagonist Ro 41-5253 or AGN 193109 near the humeral anlagens in stage 21 (Day 3.5) or stage 27 chick

7 Fgf9(ScxCre) mice had smaller calcaneal and humeral apophyses, thinner cortical bone at the attachme

8 his functional diversity was achieved with a humeral architecture that was remarkably conserved durin

9 ghput bulk and single-cell RNA sequencing of humeral attachment cells revealed expression of hundreds

10 ire articular surface of unilateral proximal humeral condyles of skeletally mature rabbits was surgic

11 l activity introduced extreme loading to the humeral diaphysis and nearly doubled its strength.

12 e throwing-to-nonthrowing arm differences in humeral diaphysis bone properties in professional baseba

13 The humeral diaphysis indicates a gradual reduction in habit

14 ation of germline mutations in Facio-Scapulo-Humeral Dystrophy (FSHD) and in an unrelated development

15 aged 7-16 years) with nonincarcerated medial humeral epicondyle fractures and more than 2 mm of displ

16 Displaced pediatric medial humeral epicondyle fractures are traditionally treated n

17 e were taken from both the femoral heads and humeral epiphyses of a 51-y-old male subject.

18 riations are seen to be more dramatic in the humeral epiphysis (larger marrow volume fraction) than i

19 nal vein occlusion, urinary tract infection, humeral fracture, and cataract).

20 with urinary tract infection, cataract, and humeral fracture.

21 Among patients with displaced proximal humeral fractures involving the surgical neck, there was

22 majority of patients with displaced proximal humeral fractures is unclear, but its use is increasing.

23 of Pterodactylus exhibiting similar oblique humeral fractures.

24 the increase in translation of the center of humeral head and glenohumeral contact area were associat

25 ower than the concentrations measured in the humeral head and neck regions (0.07 +/- 0.03 %ID/g, p <

26 Application of force to the humeral head by an examiner was associated with as much

27 ical properties and protected the underlying humeral head by maintaining bone morphometry.

28 of glenohumeral contact area, and center of humeral head during simulated pitching motion in collegi

29 the same plane; and pseudoglenoid, with the humeral head in articulation with the more posterior of

30 f the posterior glenoid; biconcave, with the humeral head in articulation with the posterior of two c

31 The oblateness of the humeral head may cause this diametric translation.

32 We compared the osteochondral units of the humeral head of marine and terrestrial mammals across sp

33 with active subjects muscle contraction, the humeral head remained precisely centered on the glenoid

34 Fracture fixation or humeral head replacement were performed by surgeons expe

35 The center of humeral head translated from posterior to anterior durin

36 CT analyses demonstrated that the center of humeral head translated in the opposite direction to tha

37 one of four categories: concentric, with the humeral head well centered on the glenoid fossa; flat, w

38 a, center of humeral head, and oblateness of humeral head were calculated from 3D bone models using c

39 There was no difference between glenoid and humeral head width fully and semiautomated 3D model meas

40 ngents (cranial tangent border </= 2 cm from humeral head) were used in 50% of patients (33 of 66) ra

41 nter of glenohumeral contact area, center of humeral head, and oblateness of humeral head were calcul

42 ian examiner applied mechanical force to the humeral head, were also performed.

43 iated with the increase in oblateness of the humeral head.

44 t, lower thoracic spine, vertebral body, and humeral head.

45 red infraspinatus tendon, and the underlying humeral head.

46 thyroid, lung, pancreas, kidney, muscle, and humeral head.

47 se in posterior translation of the center of humeral head.

48 ee bioscaffolds, and three rabbits underwent humeral-head excision without bioscaffold replacement.

49 n absorbed dose to marrow in the femoral and humeral heads and the lumbar vertebrae (L3 and L4) which

50 We found no evidence of increased proximal humeral (HR, 1.06; 99% CI, 0.97-1.15) fracture risk.

51 These include bilateral humeral hypoplasia, humeroscapular synostosis, pelvic ab

52 We provide evidence for an ongoing humeral immune response to SARS-CoV-2 in the gastrointes

53 the surface morphology of a rabbit proximal humeral joint was captured with laser scanning and recon

54 aungia range from 4,000 to 9,000 g, based on humeral length, humeral midshaft diameter, and tooth are

55 verse recent humans, were compared with both humeral lengths and estimated body masses (based on femo

56 However, when scaled to body masses, their humeral lengths are relatively short, and their clavicul

57 ertal clavicular lengths to their associated humeral lengths reflects long clavicles, short humeri, o

58 Observations of the humeral microarchitecture of stem-tetrapods, batrachians

59 m 4,000 to 9,000 g, based on humeral length, humeral midshaft diameter, and tooth area by using extan

60 The humeral morphology of Catopithecus is consistent with ce

61 a number of diseases including facio-scapulo-humeral muscular dystrophy (FSHD), acute lymphoblastic l

62 on a woman with a left arm amputation at the humeral neck.

63 causes loss of the wing anterior cross vein, humeral outgrowths, absence of halteres and eye pigmenta

64 ses showed that conformational change of the humeral polyethylene bushing was associated with the gen

65 is rotation, increased muscular leverage for humeral retraction, but not depression/adduction, and in

66 uperfast' contractile kinetics in their main humeral retractor muscle.

67 They fall into eight general categories: humeral sensory-related (subfornical organ and median pr

68 Uptake was absent in the humeral shaft and proximal epiphysis and decreased in th

69 patients with closed, unilateral, displaced humeral shaft fracture met criteria for inclusion.

70 Patients contemplating treatment for closed humeral shaft fracture should be informed that two-third

71 or opioids in the period 61-90 days after a humeral shaft fracture was associated with nonunion.

72 of 321 adult patients with closed, displaced humeral shaft fracture were assessed for eligibility.

73 Among patients with closed humeral shaft fracture, internal fixation surgery, compa

74 nonoperative care in patients with a closed humeral shaft fracture.

75 Humeral shaft fractures traditionally have been treated

76 A cohort of 9,995 patients with humeral shaft fractures was identified using diagnosis a

77 Of the 9,995 humeral shaft fractures, 105 patients developed nonunion

78 ior oblique coronal plane in relation to the humeral shaft with the elbows extended and a coronal pla

79 xtended and a coronal plane aligned with the humeral shaft with the elbows slightly flexed (20 degree

80 tended or the coronal plane aligned with the humeral shaft with the elbows slightly flexed allows acc

81 poid taxon, and that Proteopithecus exhibits humeral similarities to parapithecids that may be symple

82 Humeral tertials are absent in non-avian dinosaurs close