ライフサイエンスコーパス: pinna

1 nd extravasation of eosinophils into the ear pinna.

2 ds and somatosensory neurons innervating the pinna.

3 bilateral preauricular skin tags and normal pinna.

4 dar-deficient mice have an abnormally shaped pinna.

5 oach of transplanting LNs into the mouse ear pinna.

6 nes to coordinately generate the determinate pinna.

7 ctrical stimulation of the basal part of the pinna.

8 y reduced neutrophil accumulation in the ear pinna.

9 imulation of its branches that innervate the pinna.

10 te from muscle receptors associated with the pinna.

11 ants from B10 (H2b) donors in the dorsal ear pinna.

12 ured by a reduction in virus load in the ear pinna.

13 oblasts and chondrocytes of the mature human pinna.

14 sia to complete loss of the external ear, or pinna.

15 s with aberrant Hmx1 expression in the basal pinna, along with ectopic distal pinna expression, disru

16 3A+ somatosensory neurons that innervate the pinna and PHOX2B+ sensory neurons that innervate the ora

17 , with little scarring, of wounds to the ear pinna and repair of cardiac muscle, without fibrosis, fo

18 typical mammalian features as pelage, mane, pinna, and a variety of skin structures: keratinous derm

19 cornea, the fine structures inside the mouse pinna, and sweat ducts and Meissner's corpuscle in the h

20 nd sheath cells, and adipocytes in the adult pinna are derived from cranial neural crest.

21 ion dependent filtering in the idiosyncratic pinna cavities.

22 In ear pinna, contact sensitization, CpG, LPS, and papain all m

23 X-ray fluorescence imaging of pinna cross-sections revealed preferential localization

24 zation of late gestational and postnatal ear pinna development in two rodents and investigate the rol

25 We find that ear pinna development is largely conserved between Mus muscu

26 n sensitivity at 32 kHz appears to be due to pinna directionality.

27 n the basal pinna, along with ectopic distal pinna expression, disrupt outer ear development, affecti

28 spectral structure of the specific head and pinna filter for sound coming from the front.

29 binaural properties and frequency-dependent pinna filtering, providing a useful model to study how n

30 The role of spectral features imposed by the pinna for vertical sound localization was shown by the b

31 l 18H (a18H) mice are dark agouti with black pinna hairs.

32 nflammation localized to the skin of the ear pinna in 64% of the cases examined.

33 Comparison of multiple parts of the ear pinna indicated that a central punch spanning the auricu

34 Electrical stimulation of the pinna induced significant increases in the number of Fos

35 t all nondeomyine rodents heal identical ear pinna injuries via fibrotic repair with scar tissue.

36 as highly asymmetrical, being largest in the pinna ipsilateral to the stimuli.

37 -wide association study for non-pathological pinna morphology in over 5,000 Latin Americans.

38 Prominent pinna movements accompany eye movements when the animal

39 In visual trials the pinna movements are coordinated with eye movements, sugg

40 No behavioral contingencies were placed on pinna movements.

41 Only stimuli that activate pinna muscle receptors, such as stretch or vibration of

42 The fan shell Pinna nobilis is the largest bivalve endemic to the Medi

43 human fetal heart tissues s.c. into the ear pinna of a SCID mouse.

44 cell-free device in guinea pigs or into the pinna of mice.

45 3+ cells, but not CD133- cells, into the ear pinna of NOD/SCID mice resulted in the formation of card

46 esenting cells (APCs) were injected into the pinna of the mouse ear, and swelling was measured 24 hou

47 remains impaired in the adult mid-distal ear pinna of these mutants.

48 were taken from muscles that either move the pinna or alter its shape.

49 After individual mosquitoes fed on an ear pinna or the ventral abdomen of a mouse, fluorescence mi

50 or to support correction for the effects of pinna orientation on sound-localization cues.

51 role of the DCN in hearing is to coordinate pinna orientation to sounds or to support correction for

52 The existence of a pinna-orienting system in humans, one that is experiment

53 s may nevertheless have retained a vestigial pinna-orienting system that has persisted as a 'neural f

54 CFU in the ear pinna peaked at day 7 before dropping by day 14.

55 umor were implanted in the outer edge of one pinna per C3H/HeN mouse, and the growing tumors were rem

56 n of CHS on the external surface of the ear (pinna) potentiated the CHS response, and the magnitude o

57 n of Phox2b + neurons, as compared to Phox2b-pinna-projecting neurons, was not altered, indicating th

58 generative responses in a mouse model of ear pinna punch wound involving the restoration of tissue ar

59 rovide evidence that RT-QuIC analysis of ear pinna punches may be a useful approach to detecting CWD

60 tested a more easily accessed specimen, ear pinna punches, using an improved RT-QuIC assay involving

61 blink, pupil constriction, vibrissae reflex, pinna reflex, Digiscan open field locomotion, rotarod mo

62 the same treatments, the adjacent LCs in ear pinna remained immotile over a 48-hr period of observati

63 constructive surgery, development of the ear pinna remains poorly studied.

64 In auditory trials the pinna response was composed of two movements: short- and

65 ofluorescence microscopy of the external ear pinna revealed increased CGRP-immunoreactive sensory inn

66 e 6-9 kHz band, which falls within the human pinna's most prominent elevation-related spectral notch,

67 voluntary orienting; rearward folding of the pinna's upper-lateral edge exhibited such differences on

68 s), interaural level differences (ILDs), and pinna spectral cues, are all represented in the same loc

69 ealed preferential localization of As on the pinna surface in the proximity of veins, with the majori

70 d that As was localized largely on the lower pinna surface, with smaller amounts on the upper surface

71 B(c) antibody CSL311 strongly suppressed ear pinna thickening and histopathological changes typical o

72 a(c) antibody CSL311 strongly suppressed ear pinna thickening and histopathological changes typical o

73 ntly, by performing transplants into the ear pinna, this system enabled intravital observation of xen

74 velopmental basis for differentiation of ear pinna tissues.

75 neous challenge of the skin on the outer ear pinna using Morrow-Brown allergy test needles coated in

76 asured the movements of the external ear, or pinna, using the magnetic search coil technique in cats

77 or vibration of the muscles connected to the pinna, were effective in driving DCN units, whereas cuta

78 head to position their sensors (e.g., eyes, pinna, whiskers).

79 , we immunized mice intradermally in the ear pinna with LdCen(-/-) Compared with LdWT infection, LdCe