ライフサイエンスコーパス: digestive tract

1 thway that stimulates the development of the digestive tract.

2 mainly in the head and in the lining of the digestive tract.

3 ntestinal and extraintestinal tissues of the digestive tract.

4 congenital pathophysiologies up and down the digestive tract.

5 aride for establishing infection through the digestive tract.

6 homeostasis in the body require a functional digestive tract.

7 he peritrophic/mucous membrane in the larval digestive tract.

8 atients with symptoms referable to the upper digestive tract.

9 g the spine, genitourinary system and distal digestive tract.

10 red for anterior-posterior patterning of the digestive tract.

11 wild-type strain for infectivity through the digestive tract.

12 cluding the airway, the oral cavity, and the digestive tract.

13 ies to treat diseases of the oral mucosa and digestive tract.

14 d under simulated in-vitro conditions of the digestive tract.

15 the protease-rich environment of the animal digestive tract.

16 xylanase activity throughout the R. flavipes digestive tract.

17 blocked by a Yersinia pestis biofilm in the digestive tract.

18 complex community of microbes resides in the digestive tract.

19 d enriched for TFs that are expressed in the digestive tract.

20 ost-microbial interactions in the vertebrate digestive tract.

21 blocked by a mass of Yersinia pestis in the digestive tract.

22 AIVb is expressed only in the digestive tract.

23 accumulation of bacteria within the nematode digestive tract.

24 ins within the different compartments of the digestive tract.

25 lly or genetically ablating cells within the digestive tract.

26 and Lewis(b) was not found elsewhere in the digestive tract.

27 t levels of IKLF expression are found in the digestive tract.

28 d with GlcNAc-specific binding to the insect digestive tract.

29 cal glucuronidation at the distal end of the digestive tract.

30 in-like enzymes following secretion into the digestive tract.

31 link the external epidermis to the internal digestive tract.

32 ggesting a role during the maturation of the digestive tract.

33 to rapidly visualise mucosal surfaces in the digestive tract.

34 tors with context-dependent functions in the digestive tract.

35 compounds in conditions simulating the human digestive tract.

36 to food and bacterial constituents from the digestive tract.

37 coloplasty for caustic injuries of the upper digestive tract.

38 f probiotics to promote wound healing in the digestive tract.

39 estibility and fermentation model of the pig digestive tract.

40 the risk of cancers occurring throughout the digestive tract.

41 majority of the CIT-Ag NP uptake was in the digestive tract.

42 nlike enteroendocrine cells elsewhere in the digestive tract.

43 el disease (IBD) that can involve the entire digestive tract.

44 tions due to facilitated elimination via the digestive tract.

45 ss a transcriptome that is optimized for the digestive tract.

46 (axial) resolution as it travels through the digestive tract.

47 peptides had a normal phenotype in the flea digestive tract.

48 eatic, and esophageal adenocarcinomas in the digestive tract.

49 ies for patient-specific regeneration of the digestive tract.

50 bacterial and Leishmania populations in the digestive tract.

51 antimicrobial defense in the respiratory and digestive tracts.

52 lia of human respiratory, genitourinary, and digestive tracts.

53 by methanogenic archaea residing in ruminant digestive tracts.

54 nsis is able to spread systemically from the digestive tract after infection, most likely through M c

55 investment in muscularity, adiposity and the digestive tract allow for a larger brain.

56 The close proximity of the pancreas to the digestive tract allows EUS to obtain detailed images of

57 ecimens of which preserve traces of muscles, digestive tract and brain.

58 er ingestion, salmonellae traverse the upper digestive tract and initiate tissue invasion of the dist

59 he mechanisms by which the epithelium of the digestive tract and its associated glands are specified

60 es body cavities and organ ducts such as the digestive tract and kidney tubules.

61 ormally transcribed in primary tumors of the digestive tract and lung.

62 However, PAs are unstable in the digestive tract and must be stabilized to allow oral adm

63 ud and posterior domains in the spinal cord, digestive tract and urogenital system.

64 ages in skin, lung, liver, pancreas, and the digestive tract and were anemic.

65 Anaerobic environments such as mammalian digestive tracts and industrial reactors harbor an abund

66 and diversity of microbes that colonize the digestive tract, and how the system integrates with more

67 ts is associated with morbidity in the upper digestive tract, and since nicotine may alter cellular f

68 Because digestive tract anomalies in mouse embryos with excess N

69 uction from selective decontamination of the digestive tract appears related to the mortality risk of

70 The organs of the digestive tract are specified by coordinated signaling b

71 e functions of each anatomical region of the digestive tract are summarized.

72 ncluding humans, by the bites of fleas whose digestive tracts are blocked by a mass of the bacterium

73 rgies in the eyes, skin, nose, and the UR or digestive tracts are common.

74 ntroduced through the surface tissues of the digestive tracts are efficiently removed through excreti

75 ), the most common mesenchymal tumors of the digestive tract, are believed to arise from the intersti

76 virions by extracellular proteolysis in the digestive tract, are mostly derived from in vitro studie

77 e that will give rise to the respiratory and digestive tracts, are complex and not well understood.

78 r gives rise to the epithelial lining of the digestive tract as well as its associated organs such as

79 gnancies of the lung, breast, head and neck, digestive tract, brain, and other organs, quantitative a

80 t control viscera along the subdiaphragmatic digestive tract, but may also contain neurons that do no

81 that catabolism of amino acids in the insect digestive tract by host enzymes plays a role in plant pr

82 ced into the stomach or other sectors of the digestive tract by means of flexible endoscopy.

83 green tea intake in the development of oral-digestive tract cancer or an inhibitory role of oral sup

84 he inverse association was more evident with digestive tract cancers (HR, 0.66 for >/=63.0 vs </=8.9

85 insufficient data available regarding other digestive tract cancers to make any conclusions about GI

86 ccasionally drank tea, the relative risk for digestive tract cancers was 0.68 (95% confidence interva

87 sk of digestive system cancers, particularly digestive tract cancers, in men.

88 evated observed-to-expected ratio of 6.5 for digestive tract cancers, these studies also show a signi

89 the association between GI, GL, and risk of digestive tract cancers.

90 was associated with the risk of nonlung, non-digestive tract cancers; a standard deviation increase (

91 Potential benefits of vitamin D on other digestive-tract cancers and on survival in patients with

92 st a potential benefit of vitamin D on other digestive-tract cancers, and that vitamin D status at th

93 /E7-Tg mice were highly susceptible to upper digestive tract carcinogenesis upon initiation with 4-ni

94 Invasive infections of the CNS or digestive tract caused by Candida species in previously

95 tions of the central nervous system (CNS) or digestive tract caused by commensal fungi of the genus C

96 Ready translocation in mice after digestive tract challenge demonstrates the potential of

97 The acquisition rate of digestive tract colonization during ICU stay was 7% (95%

98 STM) was used to identify genes required for digestive tract colonization.

99 Most digestive tracts contain a complex consortium of benefic

100 Selective digestive tract decontamination is not recommended becau

101 for stress ulcer prophylaxis, and selective digestive tract decontamination.

102 as implications not only for the etiology of digestive tract defects, but sheds new light on the mean

103 f the nervous system, differentiation of the digestive tract, deposition of the larval cuticle and th

104 eneral developmental delay up to 72 hpf, but digestive tract development became arrested at the primi

105 observed, together with variable defects in digestive tract development.

106 shment of the gut microbiota and its role in digestive tract differentiation in the zebrafish model v

107 fect of milk processing on the in vivo upper digestive tract digestion of milk fat globules.

108 bacterium is ingested, it passes through the digestive tract, encountering various environmental stre

109 we interpret as a lophophore, and a U-shaped digestive tract ending in a dorsolateral anus.

110 thelium is generated after the epidermis and digestive tract epithelia have matured, ensuring that bo

111 The digestive tract epithelium and its adjoining mesenchyme

112 nsiderable carbonylation was observed in the digestive tract, especially under the acidic conditions

113 ts anthocyanins during transit through upper digestive tract for subsequent colonic delivery/metaboli

114 The digestive tract, for example, is lined by a firmly adher

115 afferents are extensively distributed in the digestive tract from the oesophagus to the colon.

116 process, as well as protecting invertebrate digestive tracts from microbial infections.

117 Understanding the basis for digestive tract functions is essential to understand dys

118 ntify 283 interactions between 72 C. elegans digestive tract gene promoters and 117 proteins.

119 ic pathways was present across these diverse digestive tract habitats.

120 In most animals, digestive tracts harbor the greatest number of bacteria

121 efficacy of selective decontamination of the digestive tract in reducing mortality is significantly b

122 The metameric organization of the digestive tract in trilobites provides further support t

123 The digestive tract includes diverse habitats and hosts the

124 and ileum, but not in other epithelia of the digestive tract (including stomach and colon), skin, lun

125 homolog selectively expressed in the nascent digestive tract, including all pharynx precursors at the

126 ripts, a few are virtually restricted to the digestive tract, including Nr2e3, previously regarded as

127 was not detectable in other sections of the digestive tract, including stomach, cecum, colon, and re

128 When limited to digestive tract, infection may resolve without IS reduct

129 underlying mesenchyme pattern the developing digestive tract into regions with specific morphology an

130 ingestion complicated by perforation of the digestive tract is a well-known occurrence.

131 lated and contact birds, suggesting that the digestive tract is not the main site of H5N1 influenza v

132 fect the anogenital tract and the upper aero-digestive tract is the cause of a number of benign and m

133 The mucous barrier of our digestive tract is the first line of defense against pat

134 Endoderm that forms the respiratory and digestive tracts is a sheet of approximately 500-1000 ce

135 y to predict their bioavailability along the digestive tract, is still not clear.

136 n epidermis and the mucosal epithelia of the digestive tract (K14 HPV49 E6/E7-Tg mice).

137 ed epithelia of the retina, neural tube, and digestive tract, leading to novel phenotypes, such as th

138 stones during organogenesis of the zebrafish digestive tract, liver, and pancreas and identify import

139 the viability of these bacteria through the digestive tract may be relevant to evaluate their potent

140 ol absorption, although other enzymes in the digestive tract may compensate for the lack of PTL in PT

141 suggested that the commensal bacteria of the digestive tract may play a role in the pathogenesis of U

142 e mechanical and physiochemical state of the digestive tract, mediated in part by serotonin, which, i

143 esses were distributed widely throughout the digestive tract microbiota, with variations in metagenom

144 obiota, commensal microbes that colonize the digestive tract, might increase the risk of LOS via disr

145 to the lack of phytases in the non-ruminant digestive tract, monogastric animals cannot utilize diet

146 cer of the digestive system encompassing the digestive tract (mouth, throat, esophagus, stomach, smal

147 ealth, but little is known about its role in digestive tract neoplasia.

148 immunohistochemistry in other tissues of the digestive tract, nor was it found in a wide range of oth

149 est number of second cancers occurred in the digestive tract (O/E = 19.3) and breast (O/E = 22.9).

150 the lung (observed [Obs] = 377; O/E = 2.9), digestive tract (Obs = 376; O/E = 1.7), and female breas

151 licate at the high temperatures found in the digestive tract of birds, have a glutamic acid at residu

152 The digestive tract of Hirudo verbana, the medicinal leech,

153 en-containing substances lost from the upper digestive tract of humans.

154 ut forms dense aggregates in the non-sterile digestive tract of its flea vector to produce a transmis

155 nia pestis adopts a unique life stage in the digestive tract of its flea vector, characterized by rap

156 results are compared with peristalsis in the digestive tract of mammals.

157 tially and collaboratively across the entire digestive tract of R. flavipes.

158 icrobial community that resides in the upper digestive tract of ruminant animals and is responsible f

159 transcriptional activation of CmCatB in the digestive tract of scN-adapted bruchids.

160 uld be exposed to proteolytic enzymes in the digestive tract of the host.

161 tle is known about protein expression in the digestive tract of ticks.

162 oarray comparisons of gene expression in the digestive tracts of 6 days post fertilization germ-free,

163 cterization of new Arthromitus isolates from digestive tracts of common sow bugs (Porcellio scaber),

164 The microbial ecology of the digestive tracts of conventionally raised and convention

165 Anthropogenic debris was extracted from the digestive tracts of fish and whole shellfish using a 10%

166 Frequently found as a commensal within the digestive tracts of healthy individuals, C. albicans is

167 y is associated with microbes inhabiting the digestive tracts of ruminants and other animals, feeding

168 e, polarize, and form tight junctions in the digestive tracts of the mouse, the sea urchin, and the n

169 sizes and colors were found in 27.6% of the digestive tracts of the nine dominant species regardless

170 g, copepods passed P. bursaria through their digestive tract only partially digested, releasing endos

171 ith unexplained invasive disease of the CNS, digestive tract, or both caused by Candida species.

172 that transmit plague without blockage of the digestive tract, or some combination of these three are

173 indicate that miRNAs are required for proper digestive tract organogenesis and that miR-7a and miR-20

174 of tea drinking were seen for cancers of the digestive tract (p for trend, 0.04) and the urinary trac

175 (NT), a peptide expressed in both brain and digestive tract, participates in these responses.

176 The digestive tract plays a central role in the digestion an

177 Patients who underwent upper digestive tract reconstruction for caustic injuries by c

178 old increase in L. plantarum survival in the digestive tract relative to healthy animals.

179 anatomical asymmetry in other regions of the digestive tract remain unknown.

180 echanisms of HTLV-1 transmission through the digestive tract remain unknown.

181 Infection of the aero-digestive tract represents a major disease burden of the

182 ooth muscles in the head and along the upper digestive tract required to consume and digest food, as

183 Homeostasis of the vertebrate digestive tract requires interactions between an endoder

184 rmal function of the central nervous system, digestive tract, respiratory tract, and urinary system.

185 specific defects in specialized cells of the digestive tract, resulting in loss of proper digestive s

186 Selective decontamination of the digestive tract (SDD) and selective oropharyngeal decont

187 variety of larval traits (e.g., fins, skin, digestive tract, sensory systems) are remodeled in a coo

188 t are highly prevalent across cancers of the digestive tract showed significantly higher abundances i

189 e the bacterial community composition of ten digestive tract sites from more than 200 normal adults e

190 The microbiomes of ten digestive tract sites separated into four types based on

191 ences in head morphology, bite strength, and digestive tract structure after experimental introductio

192 tructural barrier separating the urinary and digestive tracts, suggesting a potential role of PCM pro

193 The absence of microbes in the digestive tract suggests that limnoriid wood borers prod

194 We analyzed DNA methylation profiles of the digestive tract surface and the central bulk and invasiv

195 uitoes host communities of microbes in their digestive tract that consist primarily of bacteria.

196 a, and pathological changes in the lungs and digestive tract that included eosinophilic infiltrates,

197 y, unique structural aspects of invertebrate digestive tracts that contribute to symbiont specificity

198 a community of bacterial symbionts in their digestive tracts that contribute to their well being.

199 in enteroendocrine cells in the lumen of the digestive tract, these results suggest that GABA in came

200 indicate BTNL2 is predominantly expressed in digestive tract tissues, in particular small intestine a

201 h from persisting peacefully in a nematode's digestive tract to a lifestyle in which pathways to prod

202 aquatic environments and colonizes the human digestive tract to cause the disease cholera.

203 ely on symbiotic microorganisms within their digestive tract to gain energy from plant biomass that i

204 s receiving selective decontamination of the digestive tract treatment was analyzed as a function of

205 s, pathway activity and cell growth in these digestive tract tumours are driven by endogenous express

206 Here we show that a wide range of digestive tract tumours, including most of those origina

207 y provide protection from degradation in the digestive tract until plant cell degradation occurs near

208 hat PLFA reduced total organismal (including digestive tract) uptake of ionic silver, but not of citr

209 stigated in an in vitro mimetic model of the digestive tract using specific chemical traps.

210 aquatic habitat and as it passes through the digestive tract, V. cholerae must cope with fluctuations

211 The digestive tract was divided into 4 organs and subsequent

212 After killing, all parts of the digestive tract were analysed by a pathologist unaware o

213 taken along the longitudinal axis of the rat digestive tract were subjected to 16S rRNA gene sequenci

214 cell papillomas and carcinomas of the upper digestive tract were the most frequent finding among Atp

215 hat form the excretory system; and (iii) the digestive tract, where two bacterial species dominate th

216 bacteria can starve fleas by blocking their digestive tracts, which stimulates the insects to bite r

217 PS-COOH accumulated inside embryo's digestive tract while PS-NH2 were more dispersed.

218 in receptors in the developing and adult rat digestive tract with a pan-trk antibody that recognizes

219 ion, associated with the colonization of the digestive tract with extended-spectrum beta-lactamase-pr

220 n is in the epithelium joining the posterior digestive tract with the external epidermis.

221 we summarize our knowledge of the Drosophila digestive tract, with an emphasis on the adult midgut an