ライフサイエンスコーパス: DIC

1 DIC during B. anthracis infection may be related more to

2 DIC examination of cells exposed to excitotoxins reveale

3 DIC image analysis also showed that the fiber elongation

4 DIC is always secondary to an underlying condition, such

5 DIC microscopy showed that when rotation stopped, the he

6 DIC was confirmed within 4 hours by changes in prothromb

7 DIC was induced in guinea pigs by infusing Staphylococcu

8 DIC was observed with WBI- or CPP-based therapy, and aft

9 [DIC] of the sample is then calculated from the mixing ra

10 In this paper, we present the first 3D DIC transmittance "z stack" images of live malarial para

11 equilibrated under a CO(2) atmosphere (pH 4, DIC approximately 25.2 mM).

12 erved in acidified NaHCO(3) solutions (pH 5, DIC approximately 25.5 mM) and in solutions that were eq

13 it this wavelength dependence by modifying a DIC microscope to enable simultaneous imaging at two wav

14 well in biofouling and turbid waters, with a DIC accuracy and precision of approximately 2 mumol kg(-

15 AT administered 24 hours after DIC-SA could not reverse pre-existing histopathologic ev

16 nd 1,000 IU/kg administered 30 minutes after DIC-SA infusion prevented fibrin formation in end-organs

17 between 125 and 1,000 IU/kg 30 minutes after DIC-SA infusion was associated with 100% survival (P < o

18 AHXR+/-DIC was observed in all recipients even in the absence o

19 Measurements of groundwater pH, alkalinity, DIC, and dissolved CO2 clearly deviated from their backg

20 eathering is more likely to yield alkalinity/DIC ratios less than 1, suggesting that enhanced sulfide

21 Among all DIC parameters, D-dimer levels are most predictive for t

22 mple water is first acidified to convert all DIC to carbon dioxide (CO2).

23 Although DIC in renal or bone marrow xenotransplantation develops

24 n are a few percent of the acidification and DIC increases due to the oceanic uptake of anthropogenic

25 d inorganic carbon (DIC); the alkalinity and DIC changes mostly offset each other, and the decline in

26 as the N source increased the alkalinity and DIC concentration in proportion to the increase in bioma

27 st, using ammonium caused the alkalinity and DIC to decline, while using ammonium nitrate left the DI

28 s and stable isotope compositions of CH4 and DIC at three depths in the soil, and soil moisture and t

29 ns, and stable isotope signatures of CH4 and DIC showed that acetate cleavage dominated CH4 productio

30 Flow cytometry and DIC microscopy demonstrated that HDECs exposed to SSc se

31 Near simultaneous fluorescence and DIC light microscopy reveals that the amount of gamma-tu

32 (GFP)-zyxin, by simultaneous fluorescent and DIC imaging.

33 diffusion and transport systems of H(+) and DIC.

34 wth other than the commonly postulated P and DIC limitations.

35 indicated that the accuracies of the pH and DIC channels over a three-week time-series deployment we

36 tion (PC) to develop means to control pH and DIC independently.

37 /-0.0010 and +/- 2.5 mumol kg(-1) for pH and DIC, respectively.

38 ts demonstrate that as O(2) was produced and DIC was consumed over two annual cycles, a corresponding

39 is interpreted in terms of Mie's theory and DIC working principles.

40 the increases in calcification fluid pH and [DIC] yields high calcification fluid [CO3(2-)] and induc

41 and fibrinogen were used most frequently as DIC diagnostic tests.

42 be a possible cause of xenograft-associated DIC.

43 For 2 min average [DIC], a precision of <0.03% was achieved.

44 o elevated primary production and biological DIC drawdown that reverses in some places the sign of th

45 sing only DIC and astrocytes expressing both DIC and OGC.

46 se changes in laboratory measures induced by DIC-SA in this guinea pig model and were not associated

47 surements of length changes were obtained by DIC microscopy.

48 Measurement of wall thickness by DIC was only possible with lily due to limitations of mi

49 The delta(13)C(DIC) values suggest that the biological contribution is

50 on of dissolved inorganic carbon (delta(13)C(DIC)), and other physicochemical parameters.

51 1.11%) gradually dilutes the initial x((13)C)DIC allowing to quantify microbial mineralization using

52 beled DIC with (13)C atom fractions (x((13)C)DIC) higher than natural abundance (typically 2-50%).

53 Calculations of delta(13)C-DIC based on CRDS measured delta(13)C-CO2 and published

54 excellent agreement with measured delta(13)C-DIC using isotope ratio mass spectroscopy (IRMS).

55 The calculated DIC score significantly predicted venous and arterial th

56 ds to changes in dissolved inorganic carbon (DIC) (DIC = CO(2) + HCO(3)(-) + CO(3)(-2)) availability

57 Dissolved inorganic carbon (DIC) and pH are key factors that control the growth rate

58 rements of total dissolved inorganic carbon (DIC) and pH in seawater.

59 ncentration, and dissolved inorganic carbon (DIC) concentration using continuously stirred tank react

60 fold increase in dissolved inorganic carbon (DIC) concentration.

61 Dissolved inorganic carbon (DIC) content of aqueous systems is a key function of the

62 oncentrations of dissolved inorganic carbon (DIC) decrease in the surface mixed layers during spring

63 ation of ancient dissolved inorganic carbon (DIC) derived from carbonate bedrocks or other sources.

64 carbon (DOC) and dissolved inorganic carbon (DIC) from inundated sediments, and carbon dioxide (CO2(g

65 of alkalinity to dissolved inorganic carbon (DIC) generated by weathering reactions.

66 rements of total dissolved inorganic carbon (DIC) in seawater.

67 nd speciation of dissolved inorganic carbon (DIC) inside corals remain unclear, as only pH has been m

68 eted relative to dissolved inorganic carbon (DIC) of +24 +/- 30 per thousand and dissolved organic ca

69 st surface ocean dissolved inorganic carbon (DIC) sensor capable of extended (>year) field deployment

70 The sources of dissolved inorganic carbon (DIC) used to produce scleractinian coral skeletons are n

71 alkalinity, and dissolved inorganic carbon (DIC) using the periodic groundwater sampling method and

72 measurements of dissolved inorganic carbon (DIC) with satisfactory accuracy and resolution.

73 rbon (POC, DOC), dissolved inorganic carbon (DIC), CO2 , CH4 and N2 O.

74 organic carbon, dissolved inorganic carbon (DIC), oil indices, and other optical properties to exami

75 nalysis (RIL) of dissolved inorganic carbon (DIC).

76 reducing surface dissolved inorganic carbon (DIC); the alkalinity and DIC changes mostly offset each

77 pH (7.65-8.61), dissolved inorganic carbon (DIC, 929-3223 muM) and partial pressure of CO2 (pCO2, 50

78 onse to elevated dissolved inorganic carbon [DIC], carbon dioxide [CO2 ], and lower carbonate [CO3 (2

79 ected by doxorubicin-induced cardiotoxicity (DIC).

80 hosphorylation of dynein intermediate chain (DIC) and that this increase was partially suppressed by

81 te endosomes through its intermediate chain (DIC).

82 eraction with the dynein intermediate chain (DIC).

83 binds directly to dynein intermediate chain (DIC).

84 FRS patients with intravascular coagulation (DIC and thromboembolic complications) as shown by sP-sel

85 s of disseminated intravascular coagulation (DIC) (fibrinogen, D-dimer, alpha-2-antiplasmin, antitrom

86 elop disseminated intravascular coagulation (DIC) and microvascular thrombosis within hours of reperf

87 for disseminated intravascular coagulation (DIC) and recording thromboembolic complications.

88 with disseminated intravascular coagulation (DIC) and that coagulation activation of human whole bloo

89 with disseminated intravascular coagulation (DIC) and the lack of strict diagnostic criteria.

90 Disseminated intravascular coagulation (DIC) appears to be important in the pathogenesis of Baci

91 and disseminated intravascular coagulation (DIC) associated with sepsis and endotoxemia.

92 n of disseminated intravascular coagulation (DIC) by characterizing the difference between compensate

93 Disseminated intravascular coagulation (DIC) has been observed with the rejection of renal and b

94 e of disseminated intravascular coagulation (DIC) in four.

95 l of disseminated intravascular coagulation (DIC) in mice; (2) a reverse passive Arthus model in guin

96 uced disseminated intravascular coagulation (DIC) in micro-capillary circulation are poorly understoo

97 Disseminated intravascular coagulation (DIC) is a condition characterized by systemic activation

98 ving disseminated intravascular coagulation (DIC) score that awarded 1 point for each of the followin

99 vere disseminated intravascular coagulation (DIC) were observed in wild-type or PC(+/-) mice, as indi

100 h as disseminated intravascular coagulation (DIC), hyperfibrinolysis, dysfibrinogenemia, hemolysis, a

101 s of disseminated intravascular coagulation (DIC), with reductions of fibrinogen and platelets and in

102 Disseminated intravascular coagulation (DIC)-positive kidneys have historically been turned down

103 arly disseminated intravascular coagulation (DIC).

104 d to disseminated intravascular coagulation (DIC).

105 mics disseminated intravascular coagulation (DIC).

106 s of disseminated intravascular coagulation (DIC).

107 with disseminated intravascular coagulation (DIC); after graft excision, the DIC generally resolved.

108 An iPhone-based digital image colorimeter (DIC) was fabricated as a portable tool for monitoring te

109 hat prospective, randomized trials comparing DIC and RIC-based transplants should be carried out, wit

110 We show that corals concentrate DIC at the calcification site substantially above seawat

111 f dissolved inorganic carbon concentration ([DIC]) in surface water.

112 Dose-intense conditioning (DIC) (myeloablative) regimens for allogeneic stem cell t

113 alkalinity of the seawater with a consequent DIC increase due to CO2 invasion, thus confirming viabil

114 Differential interference contrast (DIC) image analysis also showed that fibers in the mixtu

115 ombining differential interference contrast (DIC) image pattern recognition with DIC polarization ani

116 solution differential interference contrast (DIC) images of nuclear and cellular morphology [4], and

117 Nomarski differential interference contrast (DIC) images were acquired in rapid succession.

118 me-lapse differential interference contrast (DIC) imaging to observe the development of cell-cell con

119 me-lapse differential interference contrast (DIC) imaging was performed both before and after needle

120 under a differential interference contrast (DIC) microscope.

121 hed to a differential interference contrast (DIC) microscope.

122 ours) by differential interference contrast (DIC) microscopy after exposure to excitotoxins in the pr

123 Differential interference contrast (DIC) microscopy allows for simultaneous monitoring of co

124 Differential interference contrast (DIC) microscopy and birefringence also show crystal form

125 rasts in differential interference contrast (DIC) microscopy has been exploited previously for unambi

126 gated by differential interference contrast (DIC) microscopy, microarrays of proapoptotic gene expres

127 help of differential interference contrast (DIC) microscopy, offers excellent resolution down to a s

128 Using differential interference contrast (DIC) microscopy, we measure spontaneous, thermal fluctua

129 by both differential interference contrast (DIC) microscopy, which allows the flagella of swimming c

130 such as differential interference contrast (DIC) microscopy.

131 ngths in differential interference contrast (DIC) microscopy.

132 zed with differential interference contrast (DIC) optics in horizontal brainstem slices.

133 Nomarski differential interference contrast (DIC), (2) changes in apical cell wall fluorescence in ce

134 y (FSM), differential interference contrast (DIC), and phase contrast microscopy, we tracked the move

135 into the differential interference-contrast (DIC) slider bay of a commercial microscope, without furt

136 mmonium nitrate makes it possible to control DIC and pH independently in a pH-stat.

137 and also for deviance information criteria (DIC) computed for a range of prior distributions.

138 nsplantation develops over a period of days, DIC associated with hyperacute pulmonary xenograft dysfu

139 ed from blood cultures of patients with DIC (DIC-SA) or without DIC (non-DIC-SA).

140 changes in dissolved inorganic carbon (DIC) (DIC = CO(2) + HCO(3)(-) + CO(3)(-2)) availability with a

141 However, the dicarboxylate (DIC) and 2-oxoglutarate (OGC) carriers localized to the

142 in the presence of diisopropylcarbodiimide (DIC) to give P1-(2',3'-O-isopropylideneadenosin-5'-yl)-P

143 2 +/- 0.06 per thousand) compared to the DOC/DIC-free configuration (delta(238)U = 0.39 +/- 0.04 per

144 Video-enhanced DIC microscopy of fla3-1 cells shows that the frequency

145 scopy, an improved version of video-enhanced DIC.

146 sion, was associated with clinically evident DIC.

147 The simple evolving DIC score calculated in the first 48 hrs from two readil

148 The simple evolving DIC score increased with worsening clinical class and wa

149 ted with monthly means in all species except DIC.

150 PSC-CMs from patients who did not experience DIC, with decreased cell viability, impaired mitochondri

151 dividuals with breast cancer who experienced DIC were consistently more sensitive to doxorubicin toxi

152 this enzyme (i.e. reductase(DIC), ferredoxin(DIC), and oxygenase(DIC)) and classified the oxygenase c

153 anism (CCM) in which whole-cell affinity for DIC, as well as the intracellular DIC concentration, inc

154 endent, but similar measurement channels for DIC and pH.

155 al computer system as having been tested for DIC in a 3-month period.

156 Screening tests for DIC were ordered for the suspected patients.

157 f LMWH was adminstered alone, mortality from DIC-SA was slightly, but not significantly reduced compa

158 ical series demonstrating good outcomes from DIC-positive kidneys when the extent of glomeruli contai

159 rombosis with a hazard ratio (HR) for a high DIC score (>/=5) of 4.79 (1.71-13.45).

160 Abnormal coagulation parameters and high DIC scores (primarily due to fibrinogen and platelets) c

161 mumol kg(-1) and successfully captured high DIC variability down to minute scales.

162 for upregulating pH compared with the high [DIC] scenario and thus may allow corals to be more resis

163 pended cells that were cultivated under high-DIC conditions in chemostats in growth medium with low c

164 Being able to quantify how DIC and pH independently affect growth kinetics requires

165 However, DIC microscopy also revealed that the coiled filament co

166 the suitability of multiplexing detection in DIC microscopy was investigated systematically with 19 k

167 ing polarization adjustments is important in DIC microscopy, because it affects bias retardation and

168 rease in groundwater pH and the increases in DIC and dissolved CO2 observed in the pulselike CO2-rele

169 nerite dissolution, but further increases in DIC concentration did not affect the dissolution rate.

170 ulation may provide convincing protection in DIC.

171 Foremost, both models result in DIC and endotoxic shock, neither of which is likely to r

172 een pvWF and GPIb play a significant role in DIC associated with pulmonary xenotransplantation.

173 ice in a lethal model of carrageenan-induced DIC and inhibits vascular leak in both the mouse DIC mod

174 toplasmic dynein heavy (DHCs), intermediate (DICs), and light intermediate (LICs) chains, and the dyn

175 finity for DIC, as well as the intracellular DIC concentration, increases substantially under DIC lim

176 In conclusion, IR DIC videomicroscopy can be used to follow quantitatively

177 rared differential interference contrast (IR DIC) videomicroscopy was used to measure and characteriz

178 elevating pH while at the same time keeping [DIC] low.

179 th kidneys from brain dead donors with known DIC.

180 The presence of 10 mg C/L DIC accelerated plattnerite dissolution, but further inc

181 regular organic compounds and (13)C-labeled DIC with (13)C atom fractions (x((13)C)DIC) higher than

182 anism were found to be upregulated under low-DIC conditions.

183 ion, which is further supported by the lower DIC and partial pressure of carbon dioxide (pCO2) associ

184 xing detection was accomplished by measuring DIC contrasts at a minimum of two specific illumination

185 he improved accuracy from directly measuring DIC gives rise to new opportunities for quantitative, au

186 is not understood how biologically mediated DIC uptake can be supported in the absence of nutrients.

187 fferential interference contrast microscopy (DIC).

188 alance calculations require that the missing DIC is converted into particulate carbon by photosynthes

189 ion by SPORT, we constructed a dual-modality DIC/fluorescence microscope to simultaneously image fluo

190 and inhibits vascular leak in both the mouse DIC model and a guinea pig reverse passive Arthus reacti

191 tients with DIC (DIC-SA) or without DIC (non-DIC-SA).

192 The non-DIC-SA animals and animals infused with sterile saline s

193 non-overt consumptive coagulopathy (nonovert DIC).

194 er, most are not saturated at current ocean [DIC].

195 new method over the typical range of oceanic DIC showed good agreement with measurements made by an e

196 The main advantages of DIC microscopy for multiplexing detection over other non

197 Immunoblot analysis of DIC and OGC in primary cultures of rat cerebellar granul

198 Increased awareness of DIC as a diagnostic possibility may enable prompt recogn

199 in growth medium with low concentrations of DIC and tracked CCM development in the presence and abse

200 The wavelength dependence of DIC contrast of gold/silver nanoparticles is interpreted

201 lial cell activation with the development of DIC, even when there are only minimal histologic changes

202 eutic target for impeding the development of DIC.

203 A reliable diagnosis of DIC can be made through simple scoring algorithms based

204 ered the best test panel in the diagnosis of DIC.

205 ximately 90% more accurate than estimates of DIC calculated from contemporaneous and collocated measu

206 rse pre-existing histopathologic evidence of DIC but favorably affected survival, which reached stati

207 ter masses is only the controlling factor of DIC and pCO2 concentrations.

208 Group 3 animals developed features of DIC in two of three cases during the fourth week, with A

209 Finally, knockdown of DIC with adenoviral siRNA also rendered CGNs more suscep

210 ototype sensor indicate that measurements of DIC are approximately 90% more accurate than estimates o

211 d, high-frequency, long-term measurements of DIC in marine and fresh waters.

212 he genetic basis and molecular mechanisms of DIC.

213 To better understand the pathogenesis of DIC during anthrax, we compared the effects of 24-hour i

214 and CK1epsilon-dependent phosphorylation of DIC, which stimulates dynein motor activity and increase

215 e was superseded by a consumptive picture of DIC within the first week, necessitating graft removal.

216 e extent can be predicted by the presence of DIC at time of AML diagnosis.

217 fication fluid, decreasing the proportion of DIC present as CO2 and creating a diffusion gradient fav

218 Time-lapse video records of DIC imaged embryos show that nuclei in injected regions

219 mber 30, 2004, the FDA received 6 reports of DIC associated with "acute hemolysis" (or similar terms)

220 The resolution of DIC microscopy made it impossible to identify whether th

221 his review presents the first case series of DIC associated with acute hemoglobinemia or hemoglobinur

222 of these carriers, with CGNs expressing only DIC and astrocytes expressing both DIC and OGC.

223 physicians assessed that acute hemolysis or DIC caused or contributed to each death.

224 increase the risk of bypass (e.g., sepsis or DIC), or severe hypercyanotic spells (HS) at the time of

225 ecting overt consumptive coagulopathy (overt DIC) near the time of challenge or injury (1 to 6 hrs).

226 c response to inflammatory stress (ie, overt DIC).

227 sponse to inflammatory stress (ie, non-overt DIC).

228 were much less reliable as markers of overt DIC because the fibrinogen underwent an acute phase resp

229 ductase(DIC), ferredoxin(DIC), and oxygenase(DIC)) and classified the oxygenase component of dicamba

230 Computer modeling suggests that oxygenase(DIC) has strong similarities with the core alphasubunits

231 emorrhage and appeared to develop pathologic DIC.

232 y sensitive in comparison to groundwater pH, DIC, and alkalinity.

233 nding or pleiotropy had significantly poorer DIC scores.

234 utomated in situ DIC measurements, positions DIC to become a key parameter for in situ CO2-system cha

235 The proposed DIC-iPhone is able to provide a limit of detection (LOD)

236 with the carbodiimide-based coupling reagent DIC leads to a six-membered-ring intermediate acting as

237 ee components of this enzyme (i.e. reductase(DIC), ferredoxin(DIC), and oxygenase(DIC)) and classifie

238 reagent pH can thereby determine the sample DIC over a wide dynamic range, with inherent calibration

239 SEAS-DIC is a new in situ instrument designed to provide cali

240 Field trials indicate that SEAS-DIC performs well in biofouling and turbid waters, with

241 zed cultures and voxel analysis of sharpened DIC z stacks, we present the first quantitative in vivo

242 on ([Ca(2+)](i)) as revealed by simultaneous DIC and fluorescent indicator dye microscopy.

243 tometric system capable of automated in situ DIC measurements, positions DIC to become a key paramete

244 ed better fit than non-linear model (smaller DIC).

245 hts new mechanistic insights into how Snapin-DIC coordinates retrograde transport and late endosomal-

246 as expressing the mutant defective in Snapin-DIC coupling shows a dominant-negative effect.

247 Therefore, the SPE-DIC-iPhone could be used for the assay of TC residues in

248 ized aminoalkyl silica gels using a standard DIC/HOBt coupling protocol.

249 We hypothesize that DIC may be important for the early control of leukemia i

250 ans and other health care professionals that DIC may be a rare but potentially severe complication of

251 Preliminary results suggest that DIC with maximum prophylaxis and support is safe for eld

252 The DIC channel adapts a recently developed spectrophotometr

253 systematically affect the alkalinity and the DIC in distinct ways.

254 rothrombin time, and platelet count) and the DIC score according the International Society of Thrombo

255 oagulation parameters were assessed, and the DIC score was calculated based on platelets, fibrinogen,

256 use of D-dimer, FDP, and antithrombin as the DIC diagnostic test panel, with D-dimer and FDP providin

257 omboplastin time, and d-dimer as well as the DIC score differed significantly between patients with a

258 analytical techniques used to determine the DIC content in water are unable to operate under high CO

259 coagulation (DIC); after graft excision, the DIC generally resolved.

260 (delta(13)C(spiked_sample)) derived from the DIC in the mixture, and the D/H ratio of the mixed water

261 cline, while using ammonium nitrate left the DIC nearly unchanged.

262 rovides a mechanistic basis for managing the DIC for photoautotrophic cultures through the N source.

263 expressing the snapin transgene, but not the DIC-binding-defective Snapin-L99K mutant.

264 nate contributes a significant amount of the DIC pool used to build the skeleton.

265 -11 media and a pH-stat confirmed all of the DIC predictions of the PC-based model.

266 erved premortem and at autopsy in all of the DIC-SA animals but in substantially fewer animals that r

267 eletal boron geochemistry to reconstruct the DIC chemistry of the fluid used for coral calcification.

268 This study indicates that the DIC associated with the hyperacute dysfunction of pulmon

269 Thus, the DIC in pulmonary xenotransplantation may represent a uni

270 e has generated interest in the use of these DIC-positive grafts.

271 This DIC uptake represents one of the largest components of n

272 (SDCM) system and its initial application to DIC imaging of hemozoin within live, synchronized, intra

273 SC-CMs) can recapitulate the predilection to DIC of individual patients at the cellular level.

274 Higher severity injuries, which are prone to DIC, are typically seen in younger, otherwise healthy po

275 transcription patterns for cells grown under DIC limitation and those grown under ammonia limitation

276 concentration, increases substantially under DIC limitation.

277 A unique DIC contrast spectrum was found for each kind of nanopar

278 Mortality of untreated DIC-SA animals was 36% within 24 hours and up to 75% by

279 detected in all guinea pigs in the untreated DIC-SA group and in the groups treated with 125 IU/kg AT

280 ignificantly reduced compared with untreated DIC-SA.

281 Using DIC and specially designed microfluidic channels, we wer

282 re investigated after temperature jump using DIC microscopy to gain a basic understanding of the dete

283 cal and electron imaging methods such as VEC-DIC and transmission electron microscopy regarding the f

284 ential interference contrast microscopy (VEC-DIC), ICP-OES was able to detect nanoparticles inside fr

285 imilar (13)C loss from PHY and ASB plots via DIC (58% and 56%, respectively) and CO2(g) fluxes (<1%),

286 its dynamic instability was studied by video-DIC microscopy, rescues were found to occur at a mean fr

287 Dual-wavelength DIC microscopy thus presents a new approach to the simul

288 method is <0.02% (+/-0.4 mumol kg(-1) when [DIC] = 2000 mumol kg(-1)).

289 lates inflammatory responses associated with DIC.

290 ansplantation using kidneys from donors with DIC.

291 solated from blood cultures of patients with DIC (DIC-SA) or without DIC (non-DIC-SA).

292 dying the use of AT therapy in patients with DIC-SA.

293 ontrast (DIC) image pattern recognition with DIC polarization anisotropy, the exact full three-dimens

294 d the polarization setting when working with DIC microscopy.

295 res of patients with DIC (DIC-SA) or without DIC (non-DIC-SA).