ライフサイエンスコーパス: sacrum

1 whole presacral series caused by the wedged sacrum.

2 l spinal fixation devices that extend to the sacrum.

3 participant's waistband, approximating their sacrum.

4 ine venous plexus from chondrosarcoma of the sacrum.

5 rib-bearing vertebra and positioning of the sacrum.

6 vertebrae that are incompletely fused to the sacrum.

7 for T12, 6.11+/-1.73 for L5, 4.59+/-1.74 for sacrum, 5.39+/-1.72 for right iliac bone, and 3.90+/-1.5

8 initial bone metastases were in the spine or sacrum (75%) followed in descending order by the pelvis

9 patients with hardware that extended to the sacrum, 88% of MR arteriograms were of diagnostic qualit

10 Models trained by raw marker data at the sacrum achieve an accuracy of 92% in distinguishing PAD

11 (in men), and 2 marrow sites (acetabulum and sacrum), and correction for attenuation and background w

12 wing treatment of a metastasis involving the sacrum, and (3) a fracture of the acetabulum following R

13 h four well-developed legs, a multivertebral sacrum, and a strong sacroiliac articulation that could

14 nterior and/or superior to sacroiliac joint, sacrum, and remainder of pelvis), mean lesion attenuatio

15 esections of the bony pelvis, especially the sacrum, are becoming more common as part of extended rad

16 n exceptionally well-preserved Edmontosaurus sacrum excavated from the Upper Cretaceous strata of the

17 ies: the antero-dorsal sloping caused by the sacrum had to be counteracted with further skeletal modi

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

19 ion of the C7 vertebral body relative to the sacrum in a 'birds eye view', as the coronal and sagitta

20 Partial absence of the sacrum is a rare congenital defect which also occurs as

21 atment for chordomas of the mobile spine and sacrum is en-bloc excision with wide margins and postope

22 Baseline results highlight that the sacrum is the best-performing location, yet optimal (lon

23 lities, partially due to the modified wedged sacrum, likely a potential synapomorphy of the clade and

24 Vertical displacement of the CoM (sacrum marker displacement), oxygen uptake, walking econ

25 ce leg were accurately estimated from single sacrum-mounted IMU data incorporating a single-leg stanc

26 s of the body segment, derived from a single sacrum-mounted inertial measurement unit (IMU).

27 Stress fractures of the lower extremity and sacrum occur in a variety of patients, ranging from youn

28 chordal origin, most commonly arising in the sacrum or skull base.

29 y, the position of the C7 vertebral body and sacrum remain within the 95% confidence ellipse of that

30 pophyseal facets vary among Eusauropoda, the sacrum retained more than 10 degrees of wedging in all E

31 (VOI) was placed over 5 bone sites: T12, L5, sacrum, right iliac bone, and right femur.

32 e was best for the visualization of the bony sacrum, sacral foramina, and proximal S-1 to S-4 nerve r

33 eleton, with the most common sites being the sacrum, skull base, and spine.

34 Accelerations and orientations from sacrum, thigh and shank were collected using these senso

35 +/- 11.3 kg) who wore accelerometers on the sacrum, thighs and shanks.

36 Lesions located between T10 and the sacrum were 4.6 times more likely to fracture than were

37 he top of the thoracic spine relative to the sacrum) were analysed using linear mixed effect models (