1 oplasts it steals from the alga Acetabularia acetabulum.

2 sm underlying regional differentiation in A. acetabulum.

3 ssed throughout much of the life cycle of A. acetabulum.

4 usion of these bones in tetrapods creates an acetabulum.

5  of the unicellular green algae Acetabularia acetabulum.

6 dney hilum, iliac crest, and upper margin of acetabulum.

7  regulate reproductive onset in Acetabularia acetabulum and add to our understanding of how reproduct

8 eys, testicles (in men), and 2 marrow sites (acetabulum and sacrum), and correction for attenuation a

9 The distance between the anterior rim of the acetabulum and the metaphysis measured 20.4 mm on the af

10 s of the uninucleate green alga Acetabularia acetabulum can differentiate a reproductive structure of

11 olving the sacrum, and (3) a fracture of the acetabulum following RFA of an acetabular lesion.

12 he levels of the upper liver (diaphragm) and acetabulum had a higher noise and lower diagnostic quali

13 1-like) homeobox gene, Aaknox1 (Acetabularia acetabulum kn1-like homeobox 1).

14 The unicellular green macroalga Acetabularia acetabulum L.

15  at arthroscopy indicate that the SAF of the acetabulum likely represents a variant.

16                 Signs of retroversion of the acetabulum occurred in 24 patients without of necessity

17 f an accessory bony fossa in the roof of the acetabulum, or SAF.

18 ocalization may be one mechanism by which A. acetabulum regulates gene expression posttranscriptional

19 mage noise at the level of porta hepatis and acetabulum was evaluated with a five-point scale (1, no

20 the unicellular green macroalga Acetabularia acetabulum, we used degenerate PCR to clone a knotted1-l