ライフサイエンスコーパス: vertebra

1 s in trabecular bone (-12% to -15% of lumbar vertebra).

2 e small caliber bullet lodged next to the C2 vertebra.

3 ion with fluid density and destruction of D4 vertebra.

4 culated for a region of interest within each vertebra.

5 ative to the phantom was estimated in the L2 vertebra.

6 20% MSTN-mutant pigs had one extra thoracic vertebra.

7 marrow and by p66(shc) phosphorylation in L6 vertebra.

8 (Tb.Sp) in trabecular bone of the femur and vertebra.

9 homeotic transformation of the last thoracic vertebra.

10 d discontinuity of the neural arch of the C1 vertebra.

11 eck but not in trabecular bone of the lumbar vertebra.

12 s an increase in grade in an affected year-1 vertebra.

13 low-back pain and a lumbosacral transitional vertebra.

14 low-back pain and a lumbosacral transitional vertebra.

15 pends on the location of ablation within the vertebra.

16 opt the morphology of the next most anterior vertebra.

17 anterior limits of these are commonly skull/vertebra 1 (v1) for OE1, v1/v2 for OE2 and v7 for OE4.

18 rus and femur (both sides) and around lumbar vertebra 3 (L3) and 4 (L4) on a series of planar images

19 derwent a dorsal hemisection at T9 (thoracic vertebra 9).

20 segment cranial to the ultimate rib-bearing vertebra, also occurs in all other early hominins and is

21 e rats are transected at the second thoracic vertebra and are tested 24 to 48 hours later.

22 umerus) and non-weight bearing (2(nd) lumbar vertebra and calvarium) bones in the context of ovarian

23 compared to ground control animals in lumbar vertebra and distal femur metaphysis and epiphysis; sign

24 on, along with a strongly wedged last lumbar vertebra and other indicators of lordotic posture, would

25 ole in controlling the number of rib-bearing vertebra and positioning of the sacrum.

26 Ex vivo CT scans were acquired of the lumbar vertebra and right proximal femur excised from a 66-y ma

27 sverse process of a lumbosacral transitional vertebra and the sacrum in 39 (81%) of the patients.

28 etected in other calvarial bones, in several vertebras and in the proximal left femur.

29 to active bone marrow in the ribs, cervical vertebra, and parietal bone are 0.81, 0.80, and 0.55 for

30 n who have experienced fractures of the hip, vertebra, and wrist and patients using glucocorticoids a

31 were confined to vertebral body, with "ivory vertebra" appearance.

32 omputed tomography scans of the third lumbar vertebra before and during palliative chemotherapy.

33 r-old male with a complex fracture of the C2 vertebra body and a mandibular fracture after a penetrat

34 l was performed in all patients below the C4 vertebra by an experienced radiologist with over eight y

35 mineral density (BMD) was determined in each vertebra by using a clinical multidetector computed tomo

36 underwent 3-T (1)H MR spectroscopy of the L2 vertebra by using a point-resolved spatially localized s

37 contusion at the level of the fifth cervical vertebra (C5) followed by administration of 17beta-estra

38 gle MR image located approximately at the L3 vertebra can accurately estimate total VAT volume in bla

39 osa of the femur and at metaphysis of the L4 vertebra confirmed that male transgenic mice had decreas

40 test, as were differences between lesion-to-vertebra contrast-to-noise ratios obtained for each sequ

41 r fracture-free probability of an individual vertebra could be as high as 99.8% or as low as 19.9% ba

42 d no region was associated with kyphosis and vertebra counts.

43 Automated disk-vertebra detection and numbering were concordant with ne

44 uscle index (muscle area at the third lumbar vertebra divided by squared height).

45 were compared with calvaria, maxilla, lumbar vertebra, femoral neck, and iliac crest.

46 out the skeletal system including the skull, vertebra, femur, tibia, pelvis, and bone marrow of the f

47 sed the L2-L3 intervertebral space or the L2 vertebra for 15% of subjects.

48 ly accepted 'resegmentation' model, a single vertebra forms from the recombination of the anterior an

49 was performed to isolate the geometry of the vertebra from its surrounding fossilized matrix.

50 l articulation, the lumbosacral transitional vertebra had not been noted in a radiographic report bef

51 s discovered, but until now only an isolated vertebra has been described and it has therefore been ov

52 as millimeters (SB width) and as ratio to L5 vertebra height (SB diameter ratio).

53 nt of maximal SB diameter standardized to L5 vertebra height may be a valuable objective tool for pat

54 levels from the 12th thoracic to 1st sacral vertebra (identified on a sagittal section) for the resp

55 The L4-L5 + 6 image crossed the L3 vertebra in 85% of subjects and crossed the L2-L3 interv

56 distinct from and above the last rib-bearing vertebra in Au. sediba, resulting in a functionally long

57 s associated with a lumbosacral transitional vertebra in young patients with low-back pain.

58 Importantly, the transitional vertebra is distinct from and above the last rib-bearing

59 ity of the total body, femur neck and lumbar vertebra (L2 to L3) were significantly decreased below b

60 Bone mineral density (BMD) of the lumbar vertebra (L2-3) was assessed using a dual-energy X-ray a

61 D) of the total body, femur neck, and lumbar vertebra (L2-3) were assessed before, and at 2 and 8 mon

62 pathologic fracture of the adjacent thoracic vertebra may give rise to symptomatic spinal cord compre

63 istribution of infected sites for adults was vertebra (odds ratio [OR], 0.09; 95% confidence interval

64 otype (LBM) in both the distal femur and the vertebra of Krox20(+/-) mice.

65 pid's bow contour was compared with the fish vertebra of osteoporosis and Schmorl node.

66 block at the anterolateral aspect of the C6 vertebra on the right side under fluoroscopy.

67 ification and an attenuation of longitudinal vertebra or limb-bone growth were seen in null animals.

68 density (BMD) loss at the L2-L4 lumbar spine vertebra (P < 0.05), femoral neck (P < 0.01), and trocha

69 wed that mean FA (P = .030) and FA at the C2 vertebra (P = .035) enabled prediction of good surgical

70 that proximal CTs are directly derived from vertebra periosteal cells in response to BMP and Ihh sig

71 In fate-mapping studies, FITC-labeled vertebra periosteal cells were detected in proximal, but

72 rvature, vertebral formula, and transitional vertebra position.

73 , liver, spleen, kidney, small bowel, lumbar vertebra, psoas muscle, urinary bladder) as well as the

74 spinal canal with anterior subluxation of C1 vertebra relative to C2.

75 ur of Timimus hermani, and a single cervical vertebra represents a juvenile spinosaurid.

76 Aspiration biopsy of the vertebra revealed granulomatous inflammation and yeast f

77 (OR, 20.6; 95% CI, 8.4-48.1), humerus, then vertebra/ribs.

78 We investigated whether the history of a vertebra's position can affect signalling from paraspina

79 nders, with measurement at the second lumbar vertebra (slightly above the umbilicus) capturing the la

80 Relevant patient- and vertebra-specific covariates were included.

81 Strong vertebra-specific risk factors were thoracolumbar locali

82 the presence or absence of both patient- and vertebra-specific risk factors.

83 Tumor, brain, myocardium, vertebra, spleen, liver, lung, and kidneys showed apprec

84 bone marrow at the level of the fifth lumbar vertebra (SUVb) on PET images.

85 /- 33; T2, 29 msec +/- 4), bone marrow in L4 vertebra (T1, 586 msec +/- 73; T2, 49 msec +/- 4), subcu

86 defects that extend from the second thoracic vertebra (t2) to t11.

87 mpactor by a 12.5-mm weight drop at thoracic vertebra T8.

88 al cord, dorsal root ganglia, first cervical vertebra, thyroid gland, kidney tubules, esophagus, stom

89 sed upon the displacement that loaded the L6 vertebra to 50-60% of the cat's body weight.

90 nance (MR) spectroscopy of the second lumbar vertebra to evaluate single-voxel and multivoxel techniq

91 BMD of the whole body, femur neck and lumbar vertebra to within 1%, 1.9% and 3.6% of pretransplantati

92 ngle breath hold from the upper abdomen (T12 vertebra) to the pubic symphysis with 5-mm collimation a

93 on and localization of fractures within each vertebra was 0.81 (87 of 107 findings; 95% CI: 0.75, 0.8

94 on and localization of fractures within each vertebra was 0.82 (28 of 34 findings; 95% confidence int

95 ity for fracture localization to the correct vertebra was 0.88 (23 of 26 findings; 95% CI: 0.72, 0.96

96 ity for fracture localization to the correct vertebra was 0.92 (55 of 60 findings; 95% CI: 0.79, 0.94

97 C1-C3 fusion complete bone healing of the C2 vertebra was achieved and there were no secondary neurov

98 ctrode placement in the targeted part of the vertebra was achieved in all procedures.

99 The L6 vertebra was controlled using a displacement-controlled

100 and shortened (hold-short) the spindle, the vertebra was repositioned identically and muscle spindle

101 The L2 vertebra was scanned with dual-energy CT (80 and 140 kV)

102 e resulting polygon mesh describing only the vertebra was used for a physical 3D reconstruction by us

103 diotracer concentrations (Cmax) in brain and vertebra were low (0.67 and 0.54 m(2) x mL(-1), respecti

104 Transverse process fractures of the L3 vertebra were most common (n = 25).

105 njected, preprocedural pain, PMMA volume per vertebra) were related to postprocedural pain response a

106 The ILL denotes the lowest lumbar vertebra, which does not always represent L5.