ライフサイエンスコーパス: upper jaw

1 omeotic transformation of the lower jaw into upper jaw.

2 erimposed a mammalian-like morphology on the upper jaw.

3 iple signaling centers within the developing upper jaw.

4 facial ectoderm regulate development of the upper jaw.

5 in which the lower jaw is transformed to an upper jaw.

6 an EDNRA gain of function in the developing upper jaw.

7 d radiation with bilateral pit organs in the upper jaw.

8 t a homeotic transformation of lower jaws to upper jaws.

9 When a whale kept its upper jaw above the sea surface, many anchovies in the t

10 n total, 67 teeth were included (28 from the upper jaw and 39 from the lower jaw; 25 central incisors

11 at these C11 domains integrate action at the upper jaw and center of pol III during termination.

12 the tenaculum is closely associated with the upper jaw and that tenacular dentition resembles separat

13 te of pus from 5 periapical abscesses of the upper jaw and their corresponding maxillary sinusitis we

14 l crest cells regulate size and shape of the upper jaw, and that signaling by Bone morphogenetic prot

15 The upper jaw bones of placoderms have traditionally been co

16 onstraints present in the quadrate-jugal bar-upper jaw-braincase-quadrate kinematic chain as well as

17 ally expressed in the maxillary (prospective upper jaw) but not mandibular arch, is upregulated in th

18 ontinuous variation in the morphology of the upper jaw, but despite its potential explanatory power,

19 l cord, hypothalamus, pituitary, somites and upper jaw, but that Boc might negatively regulate Hh sig

20 that will form the anterior neurocranial and upper jaw cartilage.

21 erygoid process of the palatoquadrate in the upper jaw, condenses upon the upper or roof layer of the

22 uced in size and often fused to their dorsal upper jaw counterparts.

23 res, but the molecular mechanisms regulating upper jaw development remain unclear.

24 the jaw primordium such that Dlx1/2 regulate upper jaw development, while Dlx5/6 confer the lower jaw

25 transcription factor Twist1 is required for upper jaw development.

26 tween WNT9B and FGF signaling during lip and upper jaw development.

27 extension and dorso-ventral polarity of the upper jaw in birds.

28 Class patients II (A condition in which the upper jaw is larger than the lower jaw) were randomly se

29 transformation of lower jaw structures into upper jaw-like structures, suggesting that some cephalic

30 rovide evidence that Hand2 is sufficient for upper jaw (maxilla)-to-mandible transformation by regula

31 Consequently, the upper jaw, nasal, ocular and telencephalic structures ar

32 The upper jaws of birds, unlike those in many tetrapods, mov

33 from the maxillary arch (primordium for the upper jaw) of mouse embryos.

34 sis and proximal rhynchokinesis in which the upper jaw pivots around the nasal-frontal (N-F) hinge.

35 We report here that the frontonasal and upper jaw primordia cannot be formed after conditional a

36 We show that the majority of upper jaw shape variation can be explained by progressiv

37 Periodontal stem cells from the upper jaw showed a higher proliferation capacity, secret

38 n signatures but also caused homeosis of the upper jaw structure into a lower jaw-like structure.

39 throughout the CNCCs partly transformed the upper jaw to lower jaw structures, but the molecular mec

40 elivery, the first molar on each side of the upper jaw was extracted, and either a zirconia or a tita

41 a failing tooth in the frontal region of the upper jaw were treated with immediate implant placement

42 a failing tooth in the frontal region of the upper jaw were treated with removal of the tooth and res

43 1 and Dlx2 (Dlx1/2-/-) causes defects in the upper jaw, whereas Dlx5/6(-/-) results in homeotic trans