ライフサイエンスコーパス: caudal fin

1 and the loss of touch response in the distal caudal fin.

2 ae-bearing tail continues to grow beyond the caudal fin.

3 oups of genetically labeled cells within the caudal fin.

4 iated cells that cooperate to regenerate the caudal fin.

5 ineage classes that make the adult zebrafish caudal fin.

6 e also possess the ability to regenerate the caudal fin.

7 bending, spiraling tail and twisting of the caudal fin.

8 f shha does not alter the shape of the adult caudal fin.

9 e hoxb13a and hoxc13a mutants fail to form a caudal fin.

10 c prepattern of transcription factors in the caudal fin.

11 formities, including pooling of blood in the caudal fin.

12 bes and the body axis not extending into the caudal fin.

13 enhanced three-dimensional kinematics of the caudal fin.

14 ed fibroblasts of uninjured and regenerating caudal fins.

15 estral scale-covered tails curved over their caudal fins.

16 e into slender midwater species with furcate caudal fins.

17 test increase in transcript abundance in the caudal fin (10-18-fold) and liver (6-10-fold).

18 -independent bioindicator of oil exposure in caudal fin, a tissue that is amenable to nonlethal sampl

19 sset Lagerstatte, which exhibits lateral and caudal fins, a distinct head region with long antennae a

20 remely small and strongly arched; dorsal and caudal fins absent; tail stings and cartilaginous tail r

21 of mass and center of buoyancy and increased caudal fin activity exhibit higher energetic costs.

22 gene expression among the regenerating adult caudal fin, adult heart, and larval fin.

23 In wild-type zebrafish caudal fins, amputated blood vessels heal their ends by

24 Here, we use the zebrafish caudal fin, an optically accessible organ formed of repe

25 th a unique pooling of blood observed in the caudal fin and eye.

26 1, shha, and tsc22d3) was measured in paired caudal fin and whole-body tissues.

27 modern sharks and sturgeons, with asymmetric caudal fins and a vertebral column extending into an elo

28 owth trajectories; a lower median fin turned caudal fin, and an upper vertebrae-bearing tail, equival

29 The adult zebrafish caudal fin, and bone cells specifically, have been cruci

30 profiles from regenerating zebrafish retina, caudal fin, and heart muscle revealed additional candida

31 agrass, kelp or coral reefs, lack pelvic and caudal fins, and give birth to directly developed offspr

32 abilization, peduncle joint flexibility, and caudal fin angle fixation.

33 nd tissue regeneration, we studied zebrafish caudal fin arteries.

34 Relative to standard length (SL; jaw tip to caudal fin base distance), the surface area of jaw-closi

35 Fishes that use their body and caudal fin (BCF) during undulatory swimming have been tr

36 positive cells occurring on the lobes of the caudal fin by stage 48 and on the remaining fins by stag

37 form body plan, with a fusiform body, lunate caudal fin, compressed peduncle, and peduncle joint.

38 at of the Xenopus limb bud and the zebrafish caudal fin, despite the difference of anatomy.

39 ransition in growth control during zebrafish caudal fin development, wherein a switch from allometric

40 , we investigated the role of hox13 genes in caudal fin formation as these genes control posterior id

41 qPCR was performed on liver and caudal fin from the same genotypically sexed individuals

42 The musculature of the caudal fin is composed of 12 muscles that are arranged i

43 neurovascular-bone relationship in the adult caudal fin is established during fin organogenesis and s

44 The caudal fin is the primary appendage used for propulsion

45 phological abnormalities, including peculiar caudal fin malformations and hyperpigmentation in the ta

46 Most cell bodies of caudal fin motoneurons are small and are located in a ve

47 Dorsal and caudal fin motoneurons have small cell bodies and ipsila

48 The organization of dorsal and caudal fin motoneurons is compared with the innervation

49 The nerves that supply the caudal fin musculature arise from the last five caudal s

50 The external caudal fin of the zebrafish develops with a forked shape

51 f the neuromuscular system of the dorsal and caudal fin of zebrafish, Danio rerio, was studied, inclu

52 metabolites along the proximodistal axis of caudal fins of uninjured and regenerating adult zebrafis

53 The dorsal, anal and caudal fins of vertebrates are proposed to have originat

54 h reduced or absent expression in pelvic and caudal fin precursors.

55 During development we show that the caudal fin progresses through sequential stages of endot

56 The zebrafish caudal fin provides a valuable model to study the mechan

57 s aspects of proximodistal patterning of the caudal fin rays, regardless of fin size.

58 nic fish, and its genomic deletion perturbed caudal fin regeneration and abrogated cardiac regenerati

59 In contrast, caudal fin regeneration and skin wound healing remained

60 hat an intact miRNA pathway is essential for caudal fin regeneration in zebrafish.

61 Caudal fin regeneration is characterized by a proliferat

62 Using the zebrafish caudal fin regeneration model, we have examined the hypo

63 of AHR activation, we employed the zebrafish caudal fin regeneration model, where AHR activation bloc

64 ke other glucocorticoids, suppress zebrafish caudal fin regeneration, indicating that hair cell regen

65 ters of numerous genes involved in zebrafish caudal fin regeneration.

66 ences in the rate of growth during zebrafish caudal fin regeneration.

67 to identify temperature-sensitive mutants in caudal fin regeneration.

68 ted tail is eclipsed by the upward-expanding caudal fin, rendering a once ventral body margin as the

69 here deep-bodied benthic forms with truncate caudal fins repeatedly evolve into slender midwater spec

70 Amputation of the zebrafish caudal fin stimulates regeneration of the dermal skeleto

71 the total thrust produced over the body and caudal fin, substantially decreasing the net drag on the

72 late multiple spontaneous fractures in their caudal fin, suggesting their bones may be more brittle.

73 strategies demonstrated self-sustained body-caudal fin swimming, highlighting the role of feedback m

74 appropriate level of flexibility to flapping caudal fins (tails) of robots emulating the thunniform s

75 Alopiids possess specialist pectoral and caudal fins that are likely to have evolved, at least in

76 igmented extension of the ventral tip of the caudal fin-the "sword"-in males of several species of Xi

77 putation, zebrafish regenerate their injured caudal fin through lineage-restricted reprogramming.

78 nerate the complex structure of an amputated caudal fin to a degree that the original and replacement

79 rowth of the central rays, causing the adult caudal fin to grow into a triangular, truncate shape.

80 ults indicated that during the first h after caudal fin transection, neutrophils migrate from the hem

81 ution of inflammation and regeneration after caudal fin transection.

82 rformed a longitudinal analysis of zebrafish caudal fin vascular assembly, revealing the existence of

83 analyses further suggest that its dorsal and caudal fins were adapted for swift predatory locomotion

84 bar, and the elongate segmented body bears a caudal fin with dorsal and ventral lobes.

85 day-old zebrafish regenerate their amputated caudal fins within 3 days.

86 adult fibroblast cell lines derived from the caudal fin (ZFL) and the liver epithelium (SJD).