ライフサイエンスコーパス: biliary tree

1 mmune-mediated damage of hepatocytes and the biliary tree.

2 gressive and heterogeneous malignancy of the biliary tree.

3 ced proliferation of all compartments of the biliary tree.

4 f the corresponding defect in the developing biliary tree.

5 vely decreased with increasing length of the biliary tree.

6 ients may not originate exclusively from the biliary tree.

7 ted complications yet maintain access to the biliary tree.

8 y, 17 patients required decompression of the biliary tree.

9 n the management of benign strictures of the biliary tree.

10 heterogeneous along the normal intrahepatic biliary tree.

11 able of producing high-quality images of the biliary tree.

12 ave activity in metastatic carcinomas of the biliary tree.

13 ete nature of the development of NASs in the biliary tree.

14 ma (CCA) is a highly malignant cancer of the biliary tree.

15 ivo signatures when transplanted back in the biliary tree.

16 by chronic inflammation and fibrosis of the biliary tree.

17 transformation of cholangiocytes lining the biliary tree.

18 l product from the gut via the sinusoids and biliary tree.

19 rtially thrombosed mycotic aneurysm into the biliary tree.

20 dality for the pancreas and the extrahepatic biliary tree.

21 hat triggers a proliferative response of the biliary tree.

22 ecipient duct or jejunum) to reconstruct the biliary tree.

23 nflammatory obliteration of the extrahepatic biliary tree.

24 ated to be retargeted, deleteriously, to the biliary tree.

25 e duct strictures that can affect the entire biliary tree.

26 involving the extrahepatic and intrahepatic biliary tree.

27 he embryonic liver caused hyperplasia of the biliary tree.

28 is a candidate tumor suppressor gene in the biliary tree.

29 nd benign conditions affecting the liver and biliary tree.

30 cinoma is a highly malignant neoplasm of the biliary tree.

31 ) are present in the guinea pig extrahepatic biliary tree.

32 n AQPs have been identified in the liver and biliary tree.

33 stine, even in mice with inflammation of the biliary tree.

34 langiocytes, the epithelial cells lining the biliary tree.

35 role in the development of the intrahepatic biliary tree.

36 of the secreted hormone on the growth of the biliary tree.

37 r disease characterized by strictures of the biliary tree.

38 his approach was applied successfully to the biliary tree, a series of ductular tissues responsible f

39 Its association with cytomegalovirus and biliary tree abnormalities suggest specific areas for pr

40 ough 12 Wnt and 7 Fz genes were expressed in biliary tree, additional Fz9 and Fzb were only expressed

41 mRNA and protein were detected only near the biliary tree after BDL, and not in the peripheral liver,

42 ited data exist regarding the renewal of the biliary tree after partial hepatectomy.

43 progressively from proximal to distal in the biliary tree and correlated with location-related differ

44 iocarcinoma (ICC) likely originates from the biliary tree and develops within the hepatic parenchyma.

45 racting potential inflammatory damage in the biliary tree and gastrointestinal tract, whereas plasma

46 HGF mRNA expression is increased in both the biliary tree and in the peripheral liver, and production

47 irubin, metabolites that are abundant in the biliary tree and intestinal tract and are sometimes elev

48 cinoma (CCA) comprises diverse tumors of the biliary tree and is characterized by late diagnosis, sho

49 a disease of unknown cause that effects the biliary tree and is closely associated with inflammatory

50 titis, fatty liver disease, disorders of the biliary tree and other topics that have a substantial im

51 n G4 (IgG4)-related disease (IgG4-RD) of the biliary tree and pancreas is difficult to distinguish fr

52 diagnosis, and monitoring of IgG4-RD of the biliary tree and pancreas.

53 with regard to the overall visibility of the biliary tree and pancreatic duct and the number of ducta

54 y of eight individual ductal segments of the biliary tree and pancreatic duct, and number of ductal s

55 ecific anatomical locations within the human biliary tree and pancreatic ducts.

56 substances, including ET-1, are found in the biliary tree and selectively enter the circulation after

57 cidal agents in cysts communicating with the biliary tree and short-course medical therapy for dissem

58 documented fistulous connection between the biliary tree and shunt.

59 heterogeneous along the normal intrahepatic biliary tree and suggest that secretion-regulated transp

60 lack of continuity between the extrahepatic biliary tree and the small intestine as demonstrated by

61 to better evaluate branching patterns of the biliary tree and, eventually, the quantitative aspects o

62 o the promise of direct visualization of the biliary trees and the complementary tools for diagnosis

63 nd carcinomas affecting the liver, pancreas, biliary tree, and associated neuroectodermal endocrine c

64 es are present in the gut, gall bladder, and biliary tree, and biliary epithelial cells express CD40

65 IL-6R mRNA is weakly expressed in the biliary tree, and IL-6R protein is detectable on hepatoc

66 table; met mRNA is expressed strongly in the biliary tree, and met protein is expressed weakly on hep

67 Stem/progenitors for liver, biliary tree, and pancreas exist at early stages of deve

68 ications in benign disease of the esophagus, biliary tree, and pancreas, in addition to its increasin

69 The anatomical details of the biliary tree architecture of normal rats and rats in who

70 Those found in the biliary tree are still being defined.

71 Cells lining the biliary tree are targets of injury, but also orchestrate

72 orms are heterogeneously expressed along the biliary tree, are associated with specific secretory sti

73 cholangiocytes, the epithelia lining of the biliary tree, are the target cells.

74 Morphometric analysis showed regrowth of the biliary tree beginning at day 1 with restoration by day

75 arker of mesenchymal cells that surround the biliary tree but not epithelial cells of the canals of H

76 th of both the extrahepatic and intrahepatic biliary tree, but have distinctly different phenotypes a

77 he cells were immune-sorted from human fetal biliary tree by protocols in accordance with current goo

78 Depending on their localization along the biliary tree, CCAs are classified as intrahepatic, perih

79 proved visibility of the pancreatic duct and biliary tree, compared with the conventional 2D SSFSE th

80 r disease characterized by strictures of the biliary tree complicated by cirrhosis and cholangiocarci

81 Biliary tree complications were present in 34% of entero

82 maging modalities enable precise location of biliary tree components for radiation treatment planning

83 Disorders of the biliary tree develop and progress differently according

84 negative to Sox9-positive progenitors as the biliary tree develops.

85 Biliary tree dimensions and novel insights into anatomic

86 tion, tumors developed in other parts of the biliary tree (e.g., cholangiocarcinoma).

87 anisms underlying the repair of extrahepatic biliary tree (EHBT) after injury have been scarcely expl

88 ens and that malignant transformation in the biliary tree follows chronic infection or inflammation.

89 ore, ASO-mediated Poglut1 knockdown improves biliary tree formation in a different mouse model with n

90 Ink injection experiments reveal impaired biliary tree formation in the periphery of P30 Jag1(+/-)

91 can significantly improve BD development and biliary tree formation.

92 Extrinsic compression of biliary tree from mass effect of sarcoid granulomas with

93 ine into the bile canaliculus to protect the biliary tree from the detergent activity of bile salts.

94 resent in peribiliary glands of extrahepatic biliary trees from humans of all ages and in high number

95 onal differences of cholangiocytes along the biliary tree has been gained.

96 The extrahepatic branches of the biliary tree have glands that connect to the surface epi

97 Cholangiocytes, epithelial cells lining the biliary tree, have primary cilia extending from their ap

98 Three-dimensional reconstruction of the biliary tree, hepatic artery, and portal vein in normal

99 umber of segments, whereas the length of the biliary tree, hepatic artery, and portal vein remain unc

100 The total volume of the biliary tree, hepatic artery, and portal vein was increa

101 computer reconstructions of the intrahepatic biliary tree, identification of oval cells (presumed pro

102 , middle, and lower part of the extrahepatic biliary tree in 11, 4, and 4 patients (58%, 21%, and 21%

103 bile and fluid obtained from the obstructed biliary tree in CBDL animals contains ET-1 and alters eN

104 eration of the extrahepatic and intrahepatic biliary tree in most patients and defective morphogenesi

105 inflammatory obstruction of the extrahepatic biliary tree in neonates.

106 secondary to opportunistic infections of the biliary tree in patients with acquired immunodeficiency

107 a myofibroblast phenotype, and surround the biliary tree in response to cholestatic injury.

108 ts the growth and choleretic activity of the biliary tree in the bile duct-ligated rat, a model of ch

109 d on serotonin that limits the growth of the biliary tree in the course of chronic cholestasis.

110 f human cholangiocytes from the extrahepatic biliary tree in the form of extrahepatic cholangiocyte o

111 langiocytes, the epithelial cells lining the biliary tree in the liver, express primary cilia that ca

112 The biliary tree in the PCK rat was distorted markedly, show

113 struction, providing access to the pancreato-biliary tree in those who have undergone Roux-en-Y gastr

114 h normal rats, the total surface area of the biliary tree increased 26 times after ANIT-induced bile

115 tion of hedgehog signaling, and consequently biliary tree inflammation and liver fibrosis.

116 Liver histology, biliary tree ink injection, serum chemistry, RNAscope (o

117 In conclusion, IL-6 appears to contribute to biliary tree integrity and maintenance of hepatocyte mas

118 this approach: the canal of Hering (proximal biliary tree), intralobular bile ducts, periductal "null

119 duct are unaltered, this enlargement of the biliary tree is caused by branching and not by convoluti

120 asing impact of endoscopic ultrasound in the biliary tree is explored, as well as the latest developm

121 The biliary tree is the target of cholangiopathies that are

122 Cholangiocarcinoma (CCA), or tumor of the biliary tree, is a rare and heterogeneous group of malig

123 racterized by fibropolycystic changes in the biliary tree, is caused by mutations in the PKHD1 gene,

124 principal bicarbonate secretor in the human biliary tree, is down-regulated in primary biliary chola

125 ombination of Northern blotting and a unique biliary tree isolation technique, in which the bile duct

126 imal and salivary glands, thyroid, pancreas, biliary tree, lungs, kidneys, and meninges.

127 per abdominal surgery, serum creatinine, and biliary tree malignancy (all P <.03).

128 Biliary tree malignancy could be omitted from the Cox mo

129 high serum creatinine, high serum bilirubin, biliary tree malignancy, previous upper abdominal surger

130 langiocytes, the epithelial cells lining the biliary tree, normally express primary cilia and their i

131 , assessed by liver histology or imaging the biliary tree, occurred in 56 of 152 patients (37%) at a

132 Moreover, the total volume of the biliary tree of ANIT-fed rats was significantly greater

133 tudy aimed to characterize the extra hepatic biliary tree of Mdr2(-/-) mice at various ages and to de

134 ocedures can be complicated by injury to the biliary tree or retained stones, requiring repeat surgic

135 Congenital and acquired diseases of the biliary tree, or cholangiopathies, represent a significa

136 Sox9 heterozygosity worsens the P30 biliary tree phenotype and impairs the partial recovery

137 The extrahepatic biliary tree phenotype is less studied compared to the i

138 that pancreatic stem cells reside within the biliary tree, primarily the hepatopancreatic common duct

139 During NMP, biliary tree progenitor cells start to differentiate tow

140 usion, ECOs can successfully reconstruct the biliary tree, providing proof of principle for organ reg

141 othesis that, after partial hepatectomy, the biliary tree regenerates by proliferation of the remaini

142 nts decreased twofold, and the length of the biliary tree remained unchanged after ANIT feeding.

143 rives ongoing pathological remodeling of the biliary tree, resulting in progressive cyst formation an

144 In addition, isolated human biliary tree stem cells (hBTSCs) were used to examine ex

145 ts proof of the concept that the human fetal biliary tree stem cells are a suitable and large source

146 Biliary tree stem cells are comprised of multiple subpop

147 epatic artery transplantation of human fetal biliary tree stem cells in patients with advanced cirrho

148 most primitive of the stem/progenitor cells, biliary tree stem cells, are found in peribiliary glands

149 ture for hFL-HCCs closely resembling that of biliary tree stem cells--newly discovered precursors for

150 Human biliary tree stem/progenitor cells (BTSC) within PBGs we

151 Massive proliferation of biliary tree stem/progenitor cells (BTSCs), expansion of

152 Human biliary tree stem/progenitor cells (hBTSCs) are being us

153 wide variability of location of extrahepatic biliary tree structures suggests the need for individual

154 h biliary atresia (i.e., obliteration of the biliary tree) suffer liver fibrosis and cirrhosis.

155 ation and considerable reorganization of the biliary tree takes place.

156 gressive and heterogeneous malignancy of the biliary tree that carries a poor prognosis.

157 depict the whole pancreatic duct system, the biliary tree, the major and minor papillae, and the duod

158 improved imaging and tissue sampling of the biliary tree through endoscopic ultrasound techniques, b

159 angiography as narrowing of the extrahepatic biliary tree to < 75% of the diameter of the unaffected

160 pts and the pathophysiologic response of the biliary tree to injury should provide new therapies for

161 Our results show that the biliary tree undergoes extensive remodeling resulting in

162 The intrahepatic biliary tree was filled with a silicone polymer through

163 lammation with corrected T1 (cT1), while the biliary tree was modelled using quantitative MRCP (MRCP

164 Associated resection of the extrahepatic biliary tree was required in 11 cases (58%) and could be

165 mal, cholangiographically identifiable human biliary tree was studied with an innovative computer-aid

166 Changes around the biliary tree were compared with those seen in the periph

167 ibrosis involving the hepatic parenchyma and biliary tree, which can lead to cirrhosis and malignancy

168 ion of met and gp-80 mRNA and protein in the biliary tree, which is stronger than that seen in the pe

169 y combining endoscopy-guided sampling of the biliary tree with a high-dimensional analysis approach,

170 minal CT demonstrated a dilated intrahepatic biliary tree with left proximal intrahepatic hyperdensit

171 ccessfully be performed to all levels of the biliary tree with low rates of leak, stricture, cholangi

172 t compression or rupture of the HAA into the biliary tree with occlusion of the lumen from blood clot

173 s a highly malignant epithelial tumor of the biliary tree with poor prognosis.

174 ils an inflammatory sclerosing lesion of the biliary tree, with prominent fibrosis in infancy.

175 al ways that have revealed the extent of the biliary tree within the hepatic parenchyma, including id