ライフサイエンスコーパス: lumbar vertebrae

1 r of thoracic vertebrae as well as number of lumbar vertebrae.

2 s in attenuation between vessel segments and lumbar vertebrae.

3 limb autopod and a decrease in the number of lumbar vertebrae.

4 the cross-sectional area and density of the lumbar vertebrae.

5 developing thoracic and a variable number of lumbar vertebrae.

6 rd expressing the ratio between thoracic and lumbar vertebrae.

7 s (HT) were implanted into the discs between lumbar vertebrae 4 and 5 (L4/5) and L5/6 of male Lewis r

8 ort hind legs, aberrant limb features, split lumbar vertebrae, abnormal rib patterning, and pathologi

9 re calculated from manual delineation of the lumbar vertebrae and blood samples, assuming a fixed RM-

10 Cervical, thoracic, and lumbar vertebrae and disks can be readily identified and

11 ivo BMD assessment of the trabecular bone of lumbar vertebrae and enables freely rotatable color-code

12 sediba likely possessed five non-rib-bearing lumbar vertebrae and five sacral elements, the same conf

13 and marrow fat fraction were measured in the lumbar vertebrae and proximal femur.

14 region with the largest effect for number of lumbar vertebrae and thoracolumbar vertebrae were locate

15 ional areas of IAAT (at the fourth and fifth lumbar vertebrae) and subcutaneous abdominal adipose tis

16 Regions of interest were drawn over several lumbar vertebrae, and red marrow activity concentration

17 vity concentration in all visible vertebrae, lumbar vertebrae, and thoracic vertebrae, respectively.

18 In the absence of Hox10 function, no lumbar vertebrae are formed.

19 ntial to set the transition from thoracic to lumbar vertebrae because of their rib-repressing activit

20 r 10-mm slices between the second and fourth lumbar vertebrae by an inverse recovery method, and IAF

21 We aimed to evaluate whether lumbar vertebrae can be correctly numbered using auxilia

22 Newly discovered lumbar vertebrae contribute to a near-complete lower bac

23 se, Spearman correlations r were poor in two lumbar vertebrae, fair in five specimens, and moderately

24 s to the vertebra using fresh-frozen thoraco-lumbar vertebrae from two female body donors (A, B).

25 e (magnetization transfer ratio, MTR) across lumbar vertebrae, ilium, and femoral heads.

26 related much better with dose estimated from lumbar vertebrae imaging and patient-specific marrow mas

27 ere obtained at the first, second, and third lumbar vertebrae in 1222 healthy white male and female s

28 his vessel segment typically overlapped with lumbar vertebrae in anterior and posterior whole-body im

29 -subunit gene Gnai3 have fusions of ribs and lumbar vertebrae, indicating a requirement for Galpha(i)

30 the uncertainties in image quantification of lumbar vertebrae is correction for radioactivity in larg

31 ll as a marked posterior concavity of wedged lumbar vertebrae, known as a lordosis.

32 l-energy CT software, the trabecular bone of lumbar vertebrae L1-L4 were analyzed and segmented.

33 Single slices were taken at lumbar vertebrae L1-L5 plus intervertebral discs and the

34 row in the femoral and humeral heads and the lumbar vertebrae (L3 and L4) which were 0.66 +/- 0.3, 1.

35 andardized uptake value) was assessed in the lumbar vertebrae (L3-L4).

36 axial image measured between the 4th and 5th lumbar vertebrae (L4-L5) is most frequently chosen to ap

37 BC analyses were performed at the third lumbar vertebrae level using preoperative computed tomog

38 tment reduced intervertebral disc defects of lumbar vertebrae, loss of synchondroses, and foramen-mag

39 s mean is 76% of the mean marrow volume of 3 lumbar vertebrae measured in some of these patients.

40 r the posterior cortex were performed in the lumbar vertebrae of 10 pigs by a single operator.

41 f 588 thoracic vertebrae and 45 (18%) of 245 lumbar vertebrae (P < 0.001).

42 ae; the mean number of affected thoracic and lumbar vertebrae per patient were 5.4 and 1.8, respectiv

43 In lumbar vertebrae reduced vertebral body area and wall th

44 uential, quantitative images of the body and lumbar vertebrae, respectively, and that in blood using

45 ography (microCT) analyses of the femurs and lumbar vertebrae revealed delayed or incomplete endochon

46 mb features specialized for digging, and its lumbar vertebrae show xenarthrous articulations.

47 A total of 210 thoracic and lumbar vertebrae showed compression fractures and were e

48 IGF 11778 anterior inferior iliac spine and lumbar vertebrae structure and identifications.

49 higher turnover rate in the humerus than in lumbar vertebrae, suggesting enhanced bone formation and

50 63 (45%) of 588 thoracic and 86 (35%) of 245 lumbar vertebrae; the mean number of affected thoracic a

51 a derived curvature and reinforcement of the lumbar vertebrae to compensate for this bipedal obstetri

52 Marrow dose in the lumbar vertebrae was estimated from images for (111)In-C

53 ts at the levels of the first through fourth lumbar vertebrae was graded by a previously validated ra

54 Although the total biomechanical strength of lumbar vertebrae was reduced by 35%, the strength of the

55 Nonetheless, bone density indices of lumbar vertebrae were affected in lead-poisoned individu

56 One hundred sixty lumbar vertebrae were analyzed in 40 patients (mean age,

57 rta at the level of the first through fourth lumbar vertebrae were graded according to increasing sev

58 libration phantom and a porcine phantom with lumbar vertebrae were imaged with a dual-energy x-ray ab

59 nsity and bone mineral content in femurs and lumbar vertebrae when compared with the wild-type (WT) l

60 mary outcome was bone-mineral density of the lumbar vertebrae, with bone-mineral density at other sit

61 here was a predilection towards thoracic and lumbar vertebrae, with L4 being the commonest.