ライフサイエンスコーパス: nasal cavity

1 s, where it was immediately sniffed into the nasal cavity.

2 le of neutrophils in host defense within the nasal cavity.

3 sites through the nasolacrimal duct into the nasal cavity.

4 receptor neurons on the occluded side of the nasal cavity.

5 also for proper morphogenesis of the entire nasal cavity.

6 ction is usually initiated via the ocular or nasal cavity.

7 h generally define their location within the nasal cavity.

8 ction is usually initiated via the ocular or nasal cavity.

9 ection is usually initiated in the ocular or nasal cavity.

10 asured before entering and after exiting the nasal cavity.

11 propria of the chemosensory epithelia of the nasal cavity.

12 er of endoturbinate IV on the midline of the nasal cavity.

13 asured before entering and after exiting the nasal cavity.

14 d in chondrogenic structures surrounding the nasal cavity.

15 h a bloody drainage was evident in his right nasal cavity.

16 rose within the ethmoid sinuses and superior nasal cavity.

17 d by rhythmic delivery of air puffs into the nasal cavity.

18 Swallowing increased VOC flow through the nasal cavity.

19 berg ganglion located at the entrance of the nasal cavity.

20 atiles toward the olfactory receptors in the nasal cavity.

21 MV infection in the URT, particularly in the nasal cavity.

22 termittently colonized with S. aureus in the nasal cavity.

23 as they migrated from the neural tube to the nasal cavity.

24 l, where it was immediately inhaled into the nasal cavity.

25 ry, and follicle-associated epithelia of the nasal cavity.

26 n spread systemically via lymph draining the nasal cavity.

27 actory sensory neurons (OSNs) located in the nasal cavity.

28 ulation of S. pneumoniae colonization in the nasal cavity.

29 e mice showed essentially no bacteria in the nasal cavity.

30 pre-existing Streptococcus pneumoniae in the nasal cavity.

31 midline to separate the oral cavity from the nasal cavity.

32 ce are unable to clear the bacteria from the nasal cavity.

33 the absence of PrP(Sc) in the tongue or the nasal cavity.

34 omas, melanoma, and cancers of the brain and nasal cavities.

35 treptococcus pneumoniae serotype 14 from the nasal cavities.

36 illar zones, larynx, soft palate, uvula, and nasal cavities.

37 neurons of the ipsilateral and contralateral nasal cavities.

38 se virus shedding did not occur in ocular or nasal cavities.

39 ) or normal saline solution sprayed into the nasal cavity 15 min before the measurement of nasal cond

40 bustly at the cool temperatures found in the nasal cavity (33-35 degrees C) than at core body tempera

41 ate better at cool temperatures found in the nasal cavity (33-35 degrees C) than at lung temperature

42 nts (orbita, 31; paranasal sinuses, 93; main nasal cavity, 38; tongue, 27; remaining oral cavity, 99;

43 Nasal cavity air-space volume was assessed by acoustic r

44 Nitric oxide (NO) is produced in the nasal cavities, airways, and lungs and is exhaled by nor

45 ing an expansive olfactory epithelium in the nasal cavity, allowing full expression of a huge odorant

46 njugates on M cells were accessible from the nasal cavity, an M-cell-selective lectin and a control l

47 . pertussis were required to colonize murine nasal cavities and did not displace host microorganisms.

48 cclusion, which blocks odorant access to the nasal cavities and OSN activity.

49 uitment of H(4)R-expressing basophils to the nasal cavity and activation through FcepsilonRI.

50 rve with peripheral processes that enter the nasal cavity and centrally directed processes that enter

51 The alpha 2C-AR mRNA is detected in the nasal cavity and cerebellar primordium only at > or = 14

52 Protollin was observed in the nasal cavity and cervical lymph node but not in the brai

53 n vivo, when the bacteria are growing in the nasal cavity and in the lungs.

54 The number of bacteria recovered from the nasal cavity and larynx was not significantly different

55 atarrhalis organisms were recovered from the nasal cavity and nasopharynx of the animals in numbers s

56 The nasal cavity and OB were examined for the presence of Ag

57 ain regions parallels the enlargement of the nasal cavity and olfactory brain in mammals.

58 We identified studies of nasal cavity and paranasal sinus tumours through searche

59 Malignant tumours arising within the nasal cavity and paranasal sinuses are rare and composed

60 itis (CRS) is an inflammatory process in the nasal cavity and paranasal sinuses, and bacteria have be

61 for patients with malignant diseases of the nasal cavity and paranasal sinuses.

62 However, the limited volume of the nasal cavity and poor water solubility of anti-epileptic

63 4-SIgA complexes are quickly taken up in the nasal cavity and selectively engulfed by mucosal dendrit

64 sites: the olfactory epithelium (OE) of the nasal cavity and the neuroepithelium of the vomeronasal

65 of P. multocida organisms isolated from the nasal cavity and the severity of clinical lesions, as de

66 e ammonia levels in mucus recovered from the nasal cavity and tonsil were found to be 7- and 3.5-fold

67 n a 10-fold decrease in vector growth in the nasal cavity and trachea and a 50-fold decrease in the l

68 is crucial for proper development of the OE, nasal cavity and VNO, as well as maintenance of OE neuro

69 nitored sniffing using a thermocouple in the nasal cavity and whisking with an electromyogram of the

70 ng the migratory path of GnRH neurons in the nasal cavity and, although not expressed by GnRH neurons

71 entical microsatellite profiles in the skin, nasal cavity, and bloodstream but revealed differences a

72 stricted to OSNs in the dorsal recess of the nasal cavity, and labels a unique subpopulation of glome

73 ors in target organs, including lung, liver, nasal cavity, and other major organs.

74 ere performed to monitor colonization of the nasal cavity, and the pigs were euthanized 4 weeks after

75 n sealed to replicate anatomically the rat's nasal cavity, and these same odorants were drawn at thre

76 al cavity, which retards invagination of the nasal cavity, and thus appears to contribute to the path

77 of the lateral nasal wall into the posterior nasal cavity; and (iii) the lack of an ossified roof ove

78 oid tissue (NALT) located at the base of the nasal cavity are believed to be sites of induction of mu

79 Solitary chemosensory cells (SCCs) of the nasal cavity are specialized epithelial chemosensors tha

80 n implicated in flavor sensation in oral and nasal cavities as well as being a molecular target of so

81 am-positive bacterium, live inside the human nasal cavity as commensals.

82 mucosa, and within lymphatic vessels of the nasal cavity at all time points examined.

83 rhinorrhea bilateral, presence of pus in the nasal cavity) at 58 family practices (74 family physicia

84 Bacteria isolated from murine nasal cavities but not those from the human lower respir

85 demonstrated that strain DBB25 colonized the nasal cavity but did so at levels that were significantl

86 ession was low in dorsomedial regions of the nasal cavity but higher ventrally.

87 ococci may enter the brain directly from the nasal cavity by axonal transport through olfactory nerve

88 e chemical signals are recognized within the nasal cavity by sensory neurons that express pheromone r

89 ntrast, blocking airflow through half of the nasal cavity by surgically closing an external naris on

90 ring the minimal cross-sectional area of the nasal cavity by using acoustic rhinometry.

91 icate that neuroinvasion from the tongue and nasal cavity can be independent of LRS infection but neu

92 vivo, driven by delivery of odorants to the nasal cavity carried by the inhaled air, making olfactio

93 rved in the FKO nasal bones and sutures, the nasal cavity cartilage and bony projections, and the olf

94 ctum, small intestine, and especially in the nasal cavity contribute such precursors to the female ge

95 main fully active in mouse lungs but not the nasal cavity, demonstrating that PlrS coordinates virule

96 Olfactory receptor neurons (ORNs) in the nasal cavity detect and transduce odorants into action p

97 ucks, increased the virus load in the ferret nasal cavity early during infection while simultaneously

98 ement of T. cruzi on the mucosa in the mouse nasal cavity establishes a systemic infection with a rob

99 birth, lacking OE, vomeronasal organ (VNO), nasal cavity, forebrain, lower jaw, eyelids and pinnae.

100 subsequent collapse of both neurogenesis and nasal cavity formation.

101 eposition and retention of inhaled Ag in the nasal cavity from nose-only exposure; b) the timing for

102 Bulk transepithelial transport in the nasal cavity has not been studied to date.

103 The tumor incidence in the nasal cavity, however, was not affected by either black

104 ased recall proliferative responses, and, in nasal cavities, impaired clearance of Streptococcus pneu

105 n the occluded and non-occluded sides of the nasal cavity in 18, 24 and 70-day-old mice.

106 antities of viral RNA were detected from the nasal cavity in all pigs after live virus challenge.

107 The width of the nasal cavity in patients with CNPAS was in the less than

108 in all cats, with consistent lesions in the nasal cavity, including acute necroulcerative rhinitis i

109 The hamster model of nasal cavity infection was used to determine the tempora

110 vels of apoptosis, resulting in cessation of nasal cavity invagination and loss of virtually all OE n

111 Since the nasal cavity is a primary site of influenza virus replic

112 26 (41.3%) nasal mucous samples, showing the nasal cavity is a reservoir for HHV-6.

113 least in mammals-inhalation of air into the nasal cavity is required for odor detection.

114 includes epithelial cancers of the oral and nasal cavity, larynx, and pharynx and accounts for appro

115 and then reach the receptors located in the nasal cavity, leading to their perception.

116 gh mitral cell counts and a greatly enlarged nasal cavity likely reflects a highly sensitive olfactor

117 itial uptake of aerosolized SCHU S4 from the nasal cavity, lungs, and possibly the gastrointestinal t

118 aging was used to record total fluxes in the nasal cavity, lungs, spleen, and liver and to enumerate

119 nasal cavity results in immediate entry into nasal cavity lymphatics following inhalation.

120 e results suggest that S. epidermidis in the nasal cavity may serve as a defence mechanism against in

121 Lastly, uncultured samples from the nasal cavity, mouth, and axilla of a human subject could

122 osure has been associated with cancer of the nasal cavities, nasopharynx, prostate, lung, and pancrea

123 esions, the pH1N1 viruses were shed from the nasal cavities of challenged pigs whereas the IA30 virus

124 medium to isolate B. parapertussis from the nasal cavities of conventionally reared sheep.

125 of the protein (PrP(Sc)) in the tongues and nasal cavities of hamsters following intracerebral inocu

126 re recorded in the liver, spleen, lungs, and nasal cavities of live mice after intranasal infection w

127 aerobic bacterial isolates cultured from the nasal cavities of pigs for proteolytic activity.

128 olonization of toxigenic P. multocida in the nasal cavities of pigs, which resulted in the almost tot

129 al masses could no longer be detected in the nasal cavities of these mice.

130 Here, we reconstruct the internal nasal cavity of a Neanderthal plus two representatives o

131 The nasal cavity of a rodent is lined by an epithelium organ

132 efficiency in bovine kidney cells and in the nasal cavity of acutely infected calves.

133 tion-incompetent retroviral vectors into the nasal cavity of adult rats 1 day after exposure to the o

134 The nasal cavity of Fisher-344 rats was instilled with rhoda

135 isolated from infected AD skin than from the nasal cavity of healthy children.

136 5; in the spleen on days 1 and 3; and in the nasal cavity on day 4 generated the most accurate predic

137 ohistochemical staining were observed in the nasal cavities or lungs of all mice.

138 (80%), the mass showed an extension into the nasal cavity or oropharynx.

139 ory tract, recruitment of neutrophils to the nasal cavity, or shedding of the pathogen.

140 anatomical sites including the oral cavity, nasal cavity, pharynx, and larynx.

141 The indigenous microbiota of the nasal cavity plays important roles in human health and d

142 activated DCs trafficked from the chinchilla nasal cavity primarily to the nasal-associated lymphoid

143 traumatic placement of T. cruzi in the mouse nasal cavity produced low parasitemia, high survival rat

144 y receptor neurons (ORNs) distributed in the nasal cavity project to localized regions in the glomeru

145 In the nasal cavity, PrP(Sc) accumulation was found in the olfa

146 tially carried by retronasal flow toward the nasal cavity rather than by orthonasal flow into the lun

147 reatment did not induce neutropenia, and the nasal cavity remained free of hyphal masses.

148 id bulk transport of brain homogenate in the nasal cavity results in immediate entry into nasal cavit

149 239 particles administered into the oral and nasal cavities, small intestine, and vagina was carried

150 lls, rhinovirus replicates preferentially at nasal cavity temperature due, in part, to a less efficie

151 ted significantly closer to the lumen of the nasal cavity than are their neuroepithelial counterparts

152 l brains (n=2), more cells were noted in the nasal cavity than in the brain.

153 king place through preexisting spaces in the nasal cavity that were orders of magnitude wider than wh

154 the location of their sensory neurons in the nasal cavity, the receptors they use to detect chemosens

155 washed out by the injection of PBS to mouse nasal cavity, the response of MOR161-2 to acetophenone w

156 f receptor neurons within a subsystem of the nasal cavity, the vomeronasal organ (VNO).

157 e in at least two separate organs within the nasal cavity: the vomeronasal organ (VNO) and the main o

158 serted in the olfactory mucosa lining of the nasal cavity, they are exposed to the environment and th

159 that result from the failure of the eyes and nasal cavities to develop.

160 rely detected in the surface epithelium from nasal cavity to conducting airways with a slightly incre

161 situated at characteristic locations in the nasal cavity to detect and report on different classes o

162 f the hypothalamus and extending through the nasal cavity to expand this region and prevent approxima

163 To assess the potential for the nasal cavity to serve as a point of entry for prion dise

164 putational fluid dynamics (CFD) model of rat nasal cavity to simulate the nasal aerodynamics and sorp

165 y are transported by exhaled air through the nasal cavity to stimulate the olfactory receptor neurons

166 ment of transport of drugs directly from the nasal cavity to the brain, based on its mucoadhesive cha

167 Olfactory sensory axons navigate from the nasal cavity to the olfactory bulb and sort from among 1

168 ed necrosis in respiratory epithelium of the nasal cavity, trachea, bronchi, and bronchioles with acc

169 eated animals, but a significant increase of nasal cavity tumor incidence was observed in the NNK-tre

170 mass-transfer boundary condition used at the nasal cavity wall included the effects of solubility and

171 contrast, shedding of the LR mutant from the nasal cavity was not significantly different from that o

172 the VNO per se, and not other aspects of the nasal cavity, was sexually dimorphic.

173 ctory-ensheathing glial cells located in the nasal cavity were demonstrated to support HHV-6 replicat

174 e of inspired odorant molecules in the human nasal cavity were determined using an anatomically corre

175 ue sections through the entire extent of the nasal cavity were processed immunohistochemically to ide

176 ment also induced marked colonization of the nasal cavity which, in contrast to that induced by ammon

177 s might have structural abnormalities of the nasal cavity, which could represent specific markers of

178 e dorsal septum and the dorsal recess of the nasal cavity, which projects primarily to medial regions

179 ll death in the epithelium of the developing nasal cavity, which retards invagination of the nasal ca

180 in histochemistry on sections of the hamster nasal cavity with a panel of lectins.

181 eurons (OSNs), which detect odors within the nasal cavity, would provide insight into the etiology of