ライフサイエンスコーパス: endotoxemia

1 n serum lipopolysaccharide levels (metabolic endotoxemia).

2 de in a clinically controlled setting (human endotoxemia).

3 uced colonic mucosal barrier dysfunction and endotoxemia.

4 shing IL-18 increased lethality to sepsis or endotoxemia.

5 thetic vasoconstrictor responsiveness during endotoxemia.

6 ding RNA, was largely recapitulated in human endotoxemia.

7 fects of lipopolysaccharide and for treating endotoxemia.

8 ng hyperinflammation during the first 3 h of endotoxemia.

9 ants of the febrile response to experimental endotoxemia.

10 ologic features in response to mild systemic endotoxemia.

11 d to a dextran sodium sulfate-induced portal endotoxemia.

12 the suppression of hyperinflammation during endotoxemia.

13 on with macrophages in the spleen during LPS endotoxemia.

14 ll migration and increased susceptibility to endotoxemia.

15 inal barrier integrity and reduces metabolic endotoxemia.

16 l endothelial cells and liver in vivo during endotoxemia.

17 appaB only within muscle fibers during acute endotoxemia.

18 ain-inflammation relationship is affected by endotoxemia.

19 chanisms to avoid collateral organ damage in endotoxemia.

20 c function was significantly improved during endotoxemia.

21 uclear factor-kappaB activation in mice with endotoxemia.

22 ease in serum iron during experimental human endotoxemia.

23 tibility to lipopolysaccharide (LPS)-induced endotoxemia.

24 on, cardiac function, and animal survival in endotoxemia.

25 e inhibitor Neu5Gc2en protected mice against endotoxemia.

26 se-mediated hyperinsulinemia associated with endotoxemia.

27 nosuppressive role of macrophage CD40 in LPS endotoxemia.

28 mproves cardiac function and survival during endotoxemia.

29 inflammation often associated with low-grade endotoxemia.

30 tic inflammation in mouse models of NASH and endotoxemia.

31 reduced survival to polymicrobial sepsis and endotoxemia.

32 actor-kappaB pathway were subjected to acute endotoxemia.

33 s well as other conditions such as metabolic endotoxemia.

34 responses of the vascular endothelium during endotoxemia.

35 recently been reported to increase metabolic endotoxemia.

36 t have potential for liver protection during endotoxemia.

37 respiratory dysfunction during experimental endotoxemia.

38 in on skeletal muscle injury in experimental endotoxemia.

39 tissue injury in traumatized animals during endotoxemia.

40 s sympathetic activation during experimental endotoxemia.

41 and the effects of statins in a rat model of endotoxemia.

42 is and in healthy subjects with experimental endotoxemia.

43 5116 pg/mL), were much higher 12 hours after endotoxemia.

44 asma lipopolysaccharides (LPSs) in metabolic endotoxemia.

45 asma Lp-PLA(2) mass declined modestly during endotoxemia.

46 usion encountered in healthy subjects during endotoxemia.

47 ciated with bacterial translocation (BT) and endotoxemia.

48 utoregulation in healthy subjects exposed to endotoxemia.

49 tive in a number of circumstances, including endotoxemia.

50 ome in models of polymicrobial infection and endotoxemia.

51 endotoxin), and therapeutic hypercapnia with endotoxemia.

52 ion but suffered persistent injury following endotoxemia.

53 e of another caspase 1-dependent mediator of endotoxemia.

54 function (5A-aPC) to reduce the mortality of endotoxemia.

55 ccharide- or Acinetobacter baumannii-induced endotoxemia.

56 ctivation of coagulation in a mouse model of endotoxemia.

57 ociated thrombosis and high mortality during endotoxemia.

58 e that included muscle wasting and metabolic endotoxemia.

59 particularly on fructose intake and systemic endotoxemia.

60 educed systemic concentrations of TNF during endotoxemia.

61 from LysM-Cre:BVR (fl/fl) mice in a model of endotoxemia.

62 agulants; thrombocytopenia; neutrophilia and endotoxemia.

63 esearch into both rotavirus pathogenesis and endotoxemia.

64 O contributes importantly to protection from endotoxemia.

65 efense against A. fumigatus infection and to endotoxemia.

66 ammatory response frequently associated with endotoxemia.

67 nditions, particularly those associated with endotoxemia.

68 peritoneum, and blood using a mouse model of endotoxemia.

69 ty and restoring Th17/Tregs polarization and endotoxemia.

70 tiated mortality to both neonatal sepsis and endotoxemia.

71 esulting in improved tolerance to sepsis and endotoxemia.

72 during both polymicrobial sepsis and sterile endotoxemia.

73 er endotoxin levels than survivors on day 1 (endotoxemia, 0.48 vs 0.28; p = 0.048).

74 our swine were instrumented and subjected to endotoxemia (100 microg/kg), followed by serial plasma s

75 arterial pressure decreased similarly during endotoxemia (-11% +/- 16%) and endotoxemia + hypoxia (-1

76 th 5% CO2 (therapeutic hypercapnia), air and endotoxemia (5 mg/kg endotoxin), and therapeutic hyperca

77 uced TJ disruption, barrier dysfunction, and endotoxemia accompanied by protein thiol oxidation and d

78 ere hepatic insulin resistance under chronic endotoxemia, accompanied by increased inflammatory respo

79 ur data demonstrate that in a mouse model of endotoxemia activation of the coagulation cascade is ini

80 erosis (chronic inflammation) and 70% during endotoxemia (acute inflammation).

81 We conclude that endotoxemia adaptively activates Sox17 expression to med

82 isorders, including fat-mass gain, metabolic endotoxemia, adipose tissue inflammation, and insulin re

83 oxin levels and predicted subsequent maximal endotoxemia, after adjusting for other significant covar

84 at in the acute inflammatory response during endotoxemia, aged neutrophils cease returning to the bon

85 uces mortality in lipopolysaccharide-induced endotoxemia and a bacterial infusion mouse sepsis model.

86 rmeability to bacterial products, leading to endotoxemia and a variety of deleterious effects in both

87 oles for beta-arr2 in inflammation following endotoxemia and cecal ligation and puncture (CLP) models

88 y administered leptin increased mortality in endotoxemia and cecal ligation puncture models and was a

89 In mouse endotoxemia and cecal ligation puncture models of sepsis

90 Both endotoxemia and combined hypoxia and endotoxemia blunted

91 are resistant to lipopolysaccharide-induced endotoxemia and display a marked inability to mount infl

92 ng correlated with IgA deficiency-associated endotoxemia and endotoxin-induced expression of activin

93 ted against lipopolysaccharide (LPS)-induced endotoxemia and hepatic damage associated with decreased

94 adipose and blood during experimental human endotoxemia and in lean and obese human adipose.

95 7 (Th17) responses during experimental human endotoxemia and in patients with sepsis admitted to the

96 aling both in vivo during experimental human endotoxemia and in vitro.

97 displayed increased mortality in LPS-induced endotoxemia and increased vascular permeability in respo

98 tory cell signaling by aPC in the context of endotoxemia and infection.

99 meability, and ultimately, reduced metabolic endotoxemia and inflammation.

100 Pepcan-12 was increased upon endotoxemia and ischemia reperfusion damage where CB2 re

101 augments its protective effects in models of endotoxemia and ischemia-reperfusion injury.

102 liver damage that we suggest is secondary to endotoxemia and MT.

103 odify gut microbiota and to reduce metabolic endotoxemia and other obesity-related biochemical abnorm

104 Following endotoxemia and pneumonia, however, hepSTAT3(-/-) mice,

105 M2-EIF2AK2 pathway protects mice from lethal endotoxemia and polymicrobial sepsis.

106 flammatory activity of APC in the setting of endotoxemia and provide clear evidence that the antiinfl

107 preventing ALI in lipopolysaccharide-induced endotoxemia and raise the possibility of an essential ro

108 own to control disease tolerance pathways in endotoxemia and Salmonella infection.

109 e, ZAA significantly ameliorated LPS-induced endotoxemia and Salmonella-induced diarrhea in mice.

110 In mouse endotoxemia and sepsis models, mortality reduction requi

111 ion and thus provides protection from lethal endotoxemia and sepsis.

112 HMGB1 levels, and protects mice from lethal endotoxemia and sepsis.

113 mechanisms were operant in the kidney during endotoxemia and served a cytoprotective role in mitigati

114 Recently, we reported that, during endotoxemia and severe polymicrobial peritonitis, integr

115 er they depended on the mechanism of injury: endotoxemia and surfactant depletion.

116 ism of injury and appears to be additive for endotoxemia and surfactant depletion.

117 tty acids exhibit higher levels of metabolic endotoxemia and systemic low-grade inflammation, while t

118 myogenesis through suppression of metabolic endotoxemia and that Zip14 ablation coincides with susta

119 lin G (IVIG) treatment significantly reduced endotoxemia and the percentage of PD-1(+) CD4 T cells, a

120 Endotoxemia and ureteral obstruction also increased NGAL

121 metic peptide L-4F in ARDS and gram-negative endotoxemia and warrant further clinical evaluation.

122 ss relates to distended smooth muscles or to endotoxemia and/or hypoxia.

123 and mediates severity of LPS-induced sepsis (endotoxemia) and disease outcome in mice.

124 ilator control), 2) hypoxia (FIO2 = 10%), 3) endotoxemia, and 4) endotoxemia + hypoxia.

125 rated, exposed to lipopolysaccharide-induced endotoxemia, and injected with caspase 1 inhibitor.

126 ant increases in biomarkers of liver damage, endotoxemia, and MT indexes and a trend for greater hepa

127 at IAP detoxifies bacterial toxins, prevents endotoxemia, and preserves intestinal microbiotal homeos

128 The bacteremia, endotoxemia, and systemic low-grade inflammation associa

129 17A and IL-23 both appeared in plasma during endotoxemia, and their neutralization improved survival.

130 ffects on the organism such as hyperthermia, endotoxemia, and/or systemic inflammation.

131 sing fructose intake and addressing systemic endotoxemia are plausible targets for improving metaboli

132 estinal permeability and decreased metabolic endotoxemia as evidenced by reduced plasma LPS level, an

133 ves survival in a mouse model of LPS-induced endotoxemia as well as decreases progression in a mouse

134 n addition, patients with CVID+AIC had serum endotoxemia associated with a dearth of isotype-switched

135 Heparanase inhibition prevented endotoxemia-associated glycocalyx loss and neutrophil ad

136 to therapeutic hypercapnia with and without endotoxemia before and at 4, 12, and 24 hrs into the stu

137 Both endotoxemia and combined hypoxia and endotoxemia blunted sympathetic vasoconstrictor responsi

138 n-style diet might, therefore, contribute to endotoxemia by causing changes in gastrointestinal barri

139 followed by induction of abdominal sepsis or endotoxemia by intraperitoneal injection with cecal slur

140 ralization of D-DT protects mice from lethal endotoxemia by reducing the expression of downstream eff

141 In endotoxemia, C5a levels peaked at 6 h, while IL-17F leve

142 After endotoxemia, C5aR(-/-) mice displayed higher plasma leve

143 Saturated-fat intake and endotoxemia can impair cognition.

144 Acute endotoxemia caused hypoglycemia in mice lacking murine r

145 Pyroptotic cell death during endotoxemia causes death via unknown mechanisms.

146 pe littermates after polymicrobial sepsis or endotoxemia challenge.

147 Endotoxemia, characterized by an excess of circulating b

148 Metabolic endotoxemia, commonly derived from gut dysbiosis, is a p

149 Th17 response was significantly lower during endotoxemia, compared with baseline.

150 ized LDL (mmLDL), as a model for subclinical endotoxemia-complicated atherosclerosis.

151 Whether treatment targeting endotoxemia could be beneficial in the management of pos

152 dying childhood resistance to mortality from endotoxemia, demonstrate that oestrogen is responsible f

153 ecretion in vivo, in a MC-dependent model of endotoxemia, demonstrating that TLR4 engagement leads to

154 ay stored autologous RBCs in the presence of endotoxemia does not result in lung injury in humans.

155 phages, prevents cachexia, neutrophilia, and endotoxemia during acute schistosomiasis.

156 Following experimental endotoxemia, endogenous adenosine concentrations increas

157 and early surgery predict the development of endotoxemia; endotoxemia is particularly associated with

158 Lcn2KO mice were markedly more sensitive to endotoxemia, exhibiting elevated indices of organ damage

159 e observed that mice that survived sepsis or endotoxemia experienced loss of hippocampal long-term po

160 -/-) mice manifested a decreased survival in endotoxemia following bacterial LPS injection.

161 e first study to detect increasing levels of endotoxemia following multiple trauma.

162 was associated with a decrease in metabolic endotoxemia, glucose insulinotropic peptide, glucose int

163 Endotoxemia had no influence on mean arterial pressure (

164 Recently, gut-derived chronic endotoxemia has been identified as a primary mediator fo

165 The role of fructose intake and metabolic endotoxemia has gained attention recently, but data in k

166 that betaArr1 deficiency protects mice from endotoxemia, here we demonstrate that the absence of bet

167 During endotoxemia, however, excessive caspase-11 activation ca

168 ilarly during endotoxemia (-11% +/- 16%) and endotoxemia + hypoxia (-10% +/- 15%; both p < 0.05).

169 Also, endotoxemia + hypoxia (-17% +/- 21%) attenuated the tyra

170 g vascular conductance, +100% +/- 115%), and endotoxemia + hypoxia (leg blood flow, +67% +/- 120%; le

171 hypoxia (FIO2 = 10%), 3) endotoxemia, and 4) endotoxemia + hypoxia.

172 n mice were assessed after acute and chronic endotoxemia (i.e., exposure to inflammatory lipopolysacc

173 quently, all subjects underwent experimental endotoxemia (i.v. administration of 2 ng/kg Escherichia

174 mice) with intact IL-1R8 were protected from endotoxemia, IL-1R8-deficient IL-37tg mice were not.

175 vo, and antibody blockade of IFN-gamma after endotoxemia improved survival of secondary candidemia.

176 n in beta-cells by hyperlipidemia-associated endotoxemia improves the adaptation of beta-cells to ins

177 rogens may modulate M2-like responses during endotoxemia in a DUSP3-dependent manner.

178 and collagen were exacerbated 24 hours after endotoxemia in alcohol-fed rats.

179 Super-low-dose endotoxemia in experimental animals and humans is linked

180 okine signaling, suggesting that subclinical endotoxemia in healthy individuals might lead to signifi

181 e nanoparticles (GVNPs) for the treatment of endotoxemia in high-risk patients, using a murine model

182 In addition, the presence of endotoxemia in human liver disease was documented in the

183 regulation of Lp-PLA(2) during experimental endotoxemia in humans, probed the source of Lp-PLA(2) in

184 lungs and liver were markedly reduced during endotoxemia in IL-37Tg mice but not observed in IL-37D20

185 Using intravital microscopy, we found that endotoxemia in mice rapidly induced pulmonary microvascu

186 splayed a strong protective effect on lethal endotoxemia in mice survival study.

187 sed cytokine induction following LPS-induced endotoxemia in mice.

188 the cardiac dysfunction caused by sepsis or endotoxemia in mice; this effect may be caused by increa

189 the gut microbiota and preventing metabolic endotoxemia in rats fed a high fat and sucrose diet.

190 In a model of endotoxemia in the mouse, treatment with glycerophosphoi

191 uble CORM-401 using an experimental model of endotoxemia in vitro.

192 the injurious increase of Angpt-2 in murine endotoxemia in vivo.

193 Induction of acute endotoxemia in young and aged mice with a low dose of ba

194 Endotoxemia increased body temperature from 36.9 +/- 0.4

195 toneal neutrophil recruitment during sterile endotoxemia independent of the vagus nerve, without affe

196 Endotoxemia induced adipose CX3CL1 mRNA (32.7-fold, P <

197 ptibility to lethal effects of gram-negative endotoxemia induced by lipopolysaccharide (LPS), whereas

198 est, T3 significantly protected mice against endotoxemia induced by lipopolysaccharide i.p. injection

199 hibitor temsirolimus, even after established endotoxemia, induced autophagy and protected against the

200 atin A (herein referred to as Aza+TSA) after endotoxemia-induced mouse lung injury.

201 ges was observed in the spleen in vivo after endotoxemia induction with LPS injection.

202 ion correlated with disease severity scores, endotoxemia, infections, and short-term mortality, thus

203 is by promoting nitroxidative and ER stress, endotoxemia, inflammation, IR, and low TEE.

204 l inflammation, and its dysregulation during endotoxemia is a novel mechanism for LPS-induced vascula

205 Endotoxemia is associated with early commitment to the f

206 Endotoxemia is caused by excessive inflammation, but the

207 th a postcardiac arrest shock, high level of endotoxemia is independently associated with duration of

208 addition, low-level but persistent metabolic endotoxemia is often found in diabetic and obese subject

209 gery predict the development of endotoxemia; endotoxemia is particularly associated with cardiovascul

210 Low-dose endotoxemia is prevalent in humans with adverse health c

211 In a rat model of severe endotoxemia, L-4F significantly decreased mortality and

212 ota by swallowed bacteria induce a metabolic endotoxemia leading metabolic disorders.

213 thelial injury in animal models of sepsis or endotoxemia leads to shedding of heparan fragments from

214 Endotoxemia lessened the tyramine-induced reduction in l

215 r than 25, and patients with an intermediate endotoxemia level (>/= 0.4) had more cardiovascular dysf

216 Endotoxemia level was higher in patients with postcardia

217 The capability to both measure endotoxemia levels and offer an adapted response treatme

218 Maximal endotoxemia levels were higher in patients who developed

219 cohort of HIV-negative men with subclinical endotoxemia linked to alterations in CD4/CD8 T cell rati

220 nome-wide association study (GWAS) of evoked endotoxemia (lipopolysaccharide (LPS) 1 ng/kg IV) in hea

221 Using a murine model of endotoxemia (LPS injection), we demonstrate that adrenal

222 st (CPT) and had their blood drawn to assess endotoxemia markers LPS binding protein (LBP), soluble C

223 d mitochondrial TFAM abundance in sepsis and endotoxemia, may help to explain the paradox of lacking

224 Endotoxemia might also develop in individuals with gastr

225 Therapeutic reagents that reduce endotoxemia might reduce systemic inflammation in patien

226 dels, such as the lipopolysaccharide-induced endotoxemia model and the cecal ligation and puncture (C

227 lity seen under very low PC conditions in an endotoxemia model in mice.

228 x17 promotes endothelial regeneration in the endotoxemia model of endothelial injury.

229 e this phenomenon experimentally, we used an endotoxemia model of sepsis in mice.

230 in proinflammatory cytokine production in an endotoxemia model of sepsis.

231 In a human experimental endotoxemia model, a transient but profound monocytopeni

232 ed arthritis model and a murine experimental endotoxemia model.

233 n the pulmonary circulation in a mouse acute endotoxemia model.

234 ading to diaphragmatic weakness during acute endotoxemia, most likely via effects on multiple inflamm

235 er suppresses the adrenocortical response to endotoxemia nor enhances the accompanying production of

236 Thus, HMGB1 secretion, which is critical for endotoxemia, occurs downstream of inflammasome assembly

237 Here we observe that subclinical endotoxemia, often seen in humans with chronic inflammat

238 assessed the impact of 2 high-fat meals and endotoxemia on attention.

239 The present study addressed the effect of endotoxemia on the functional and molecular mechanisms t

240 mer all were increased greatly in mice after endotoxemia or cecal ligation and puncture as compared w

241 glands, mice had much higher mortality after endotoxemia or cecal ligation and puncture.

242 grated into an extracorporeal circuit in pig endotoxemia or heparin therapy models, it produces real-

243 FN-gamma axis in immunosuppression following endotoxemia or sepsis.

244 om mice with intrarenal (maleate), prerenal (endotoxemia), or postrenal (ureteral obstruction) injury

245 and IL-6 compared to rats subjected to only endotoxemia (p > .05 and p < .001).

246 mpared to the lung of rats subjected to only endotoxemia (p < .05 and p < .001, respectively).

247 after sepsis; p < 0.001 and 86% vs 12% after endotoxemia; p = 0.013) and significantly reduced viscer

248 g both acute (sepsis) and chronic (metabolic endotoxemia) pathologies wherein aberrant TLR4/MD2 activ

249 keywords: sepsis, septicemia, septic shock, endotoxemia, persistent pulmonary hypertension, nitric o

250 vels, improved colonic integrity, normalized endotoxemia, plasma trimethylamine (TMA) levels, and res

251 ectious diseases, where intestinal flora and endotoxemia play a role.

252 We employed a two-hit endotoxemia/pneumonia model, whereby administration of 1

253 appaBalpha super-repressor mice subjected to endotoxemia, proinflammatory cytokines, muscle RING-fing

254 o adaptive changes during human experimental endotoxemia promoting higher levels of adenosine thereby

255 fatty acids on gut microbiota and metabolic endotoxemia provide insight into the etiology and manage

256 ne system, displayed enhanced sensitivity to endotoxemia, rapid progression of chemical-induced colit

257 monocytes from volunteers with experimental endotoxemia re-instates their capacity for cytokine prod

258 Here we have shown that endotoxemia reduces oxygen delivery to the kidney, witho

259 Full in vivo production of IL-17F during endotoxemia required C5a.

260 led to increased or decreased survival from endotoxemia, respectively.

261 By promoting endotoxemia, schistosomiasis may exert additional, malad

262 e cells and are induced in in vivo models of endotoxemia, sepsis, and hemorrhagic shock.

263 theranostic, personalized treatment of blood endotoxemia/sepsis.

264 In wild-type mice, endotoxemia significantly increased proinflammatory cyto

265 challenge, with rapid development of typical endotoxemia signs and extensive organ damage, and elevat

266 Clinical conditions that result in endotoxemia, such as sepsis and alcoholic hepatitis (AH)

267 ptomic analysis of innate lymphocytes during endotoxemia suggested that NKT cells drove IFN-gamma pro

268 During endotoxemia, TF expression leads to disseminated intrava

269 However, in acute endotoxemia, the Tie1 ectodomain that is responsible for

270 Upon LPS-induced endotoxemia, these animals displayed symptoms of severe

271 for the P2X1 receptor in LPS-induced lethal endotoxemia through its critical involvement in neutroph

272 itment to liver and LPS-induced death during endotoxemia, thus highlighting a previously unrecognized

273 Using peripheral endotoxemia to establish the method, we reveal highly sp

274 was evoked in a human model of experimental endotoxemia to recruit neutrophil subsets with different

275 This effect is driven by low-level endotoxemia, unaffected by CFTR (cystic fibrosis transme

276 Endotoxemia upregulates Hypoxia inducible factor 1alpha,

277 e demonstrate that hyperlipidemia-associated endotoxemia upregulates miR-155-5p in murine pancreatic

278 n regard to dynamic cerebral autoregulation, endotoxemia was associated with lower middle cerebral ar

279 Of note, endotoxemia was associated with significantly higher exp

280 Such exacerbated endotoxemia was associated with substantially increased

281 Traumatic soft-tissue injury with additional endotoxemia was characterized by nutritive perfusion fai

282 r gene expression in response to LPS-induced endotoxemia was conducted.

283 A critical role for HMGB1 in endotoxemia was confirmed when mice deficient for IL-1be

284 Six hours later, endotoxemia was induced by intraperitoneal injection of

285 Endotoxemia was not evident on initial presentation, but

286 Pneumonia alone (without endotoxemia) was effectively controlled in the absence o

287 study the role of neutrophils in LPS-induced endotoxemia, we developed a new mouse model, PMN(DTR) mi

288 In a mouse model of endotoxemia, we discovered that LPS induced plasma sMER,

289 e receptors for coagulation factors in mouse endotoxemia, we found that the protein C receptor (ProcR

290 sing this human in vivo model of subclinical endotoxemia, we furthermore show that plasma LPS leads t

291 hrough genomic interrogation of experimental endotoxemia, we identified and replicated a novel fever

292 Using a model of endotoxemia, we present an example of the way in which p

293 Finally, using a model of endotoxemia, we present examples of the way in which int

294 Using an LPS-induced mouse model of lethal endotoxemia, we showed that APC administration reduced t

295 eability, bacterial translocation, and serum endotoxemia were measured.

296 The relevant sources of IL-17A during endotoxemia were not CD4(+) cells, gammadelta T cells, o

297 and gastrointestinal barrier dysfunction and endotoxemia when mice were forced to consume alcohol.

298 ease in plasma levels of endotoxin activity (endotoxemia), whereas a prudent-style diet reduced level

299 eg vascular conductance were not affected by endotoxemia, whereas both were elevated by adenosine inf

300 lysaccharide (4 or 20 mg/kg, i.p.) to induce endotoxemia with and without recombinant human annexin A