ライフサイエンスコーパス: hollow fiber

1 ion (20 microL) placed inside the lumen of a hollow fiber.

2 l structures composed of hepatocytes between hollow fibers.

3 ng from roller bottles to stacked plates and hollow fibers.

4 as the structure of fibrin around individual hollow fibers.

5 tration of five 5'-mononucleotides using the hollow fibers.

6 On the basis of a thin polypropylene hollow fiber (50 mum of wall-thickness and 280 mum i.d.)

7 ity in the NCI-60 cell line panel, promising hollow fiber activity (score of 32) and activity against

8 The tight UF hollow fibers also exhibit robust performance in a conti

9 Both hollow fiber and flat sheet FO membranes were tested and

10 e basis of sensitivity of cells grown in the hollow fiber and in vitro time course assays: LOX IMVI a

11 immobilized in the pores of a polypropylene hollow fiber and led to nearly 250% enrichment enhanceme

12 In this study, for the first time, hollow fiber and monolithic fiber were fabricated based

13 ochloropsis sp. was evaluated with polymeric hollow fiber and tubular inorganic membranes to demonstr

14 cell proliferation and tumor volume in mouse hollow fiber and xenograft models, respectively.

15 ponses, KB-V1 or KB-8-5 cells were placed in hollow fibers and implanted into NCr nu/nu mice.

16 Labeled cells were encapsulated in hollow fibers and were implanted in a nude mouse.

17 Granulomatous lesions develop around these hollow fibers, and in this microenvironment, the organis

18 gnificant anticancer activity in the in vivo hollow fiber animal model.

19 tent compounds were examined for activity in hollow fiber animal models.

20 displayed promising anticancer activities in hollow fiber animal models.

21 e latest advances in the manufacture of M(4) hollow fibers are discussed.

22 Flexible composite polymer/oxide hollow fibers are used as flow reactors for heterogeneou

23 On the basis of the flux, a hollow fiber array based preconcentrator is proposed and

24 east milk samples were used to apply alumina hollow fibers, as a proof of concept.

25 l of these compounds was explored in the NCI hollow fiber assay and also in a mouse Matrigel model of

26 Studies with the hollow fiber assay and in vivo tumor xenografts showed s

27 Testing in the NCI standard hollow fiber assay produced prominent growth inhibition

28 ve optical imaging technology to the in vivo hollow fiber assay, using tumor cell lines in which opti

29 were also screened for in vivo activity in a hollow fiber assay.

30 ere selected for evaluation in a NCI in vivo hollow fiber assay.

31 is presented including in vivo activity in a hollow fiber assay.

32 i-tumor activity of TIR-199 was confirmed in hollow fiber assays in mice.

33 Hollow fiber assays of analogs of 1 indicate promising a

34 evaluation of its antitumor activity through hollow fiber assays, and in subcutaneous colon and melan

35 ddition, SJG-136 is highly active in vivo in hollow fiber assays.

36 PET-captured concentration-time profiles in hollow-fiber bacterial kill curve experiments provided e

37 rmination of Pb(II) in aqueous samples using hollow fiber based solid-liquid phase microextraction (H

38 ured in a three-dimensional four-compartment hollow fiber-based bioreactor for 3 to 5 weeks these cel

39 Finally, hollow fiber-based experiments indicated that macrophage

40 or malaria parasite was developed by using a hollow fiber bioreactor that preserves healthy erythrocy

41 Here, we report the ability of a scalable hollow fiber bioreactor to effectively maintain ideal MS

42 ted by chick sternal chondrocytes grown in a hollow fiber bioreactor, were placed either on calcium f

43 d and grown under serum free conditions in a hollow fiber bioreactor.

44 terna were inoculated into an MRI-compatible hollow-fiber bioreactor.

45 Application of the model to the microfluidic hollow fiber bundle chamber capture both gross features

46 exclusion and charge repulsion, the novel UF hollow fibers can effectively remove various dyes with i

47 e progenitors in diffusible polyethersulfone hollow fiber capsules that can be used to profile system

48 tudy reports 6FDA:BPDA-DAM polyimide-derived hollow fiber carbon molecular-sieve (CMS) membranes for

49 Here, we adapted a flow-based hollow-fiber cartridge system to better understand the c

50 Three hollow fiber cartridges (HFCs) were studied in duplicate

51 bers and their fusion with endosomes to form hollow fiber clusters.

52 te for processing MOF membranes in polymeric hollow fibers, combining a two-solvent interfacial appro

53 ed to flat-sheet membranes, membranes with a hollow fiber configuration are of great interest due to

54 e tested in an in vivo animal model in which hollow fibers containing cancer cell cultures were impla

55 alent to 13.72 W/m(2) of its inner-selective hollow fiber counterpart with the same module size, pack

56 confined inside a sealed, small segment of a hollow fiber dialysis membrane (diameter 0.5 mm, length

57 Because adsorptive capacity of hollow-fiber dialyzers is limited, we sought to determin

58 ation of microwave digestion and three-phase hollow fiber electromembrane extraction (HF-EME) with hi

59 The potent two-phase hollow fiber electromembrane extraction technique couple

60 maging of molecular pathways in cells within hollow fibers enables a rapid and accurate evaluation of

61 ostructure and macroscopic morphology of CMS hollow fibers enables significantly increased propylene

62 Hollow fiber encapsulation and implantation takes 2 d, a

63 A single-step coextrusion hollow fiber fabrication technique via immiscibility ind

64 phoresis and size-exclusion chromatography), hollow-fiber flow FFF coupled with MALS allows a flow-ba

65 Herein we describe a protocol that uses hollow-fiber flow field-flow fractionation (FFF) coupled

66 ted for seawater desalination using flat and hollow fiber FO membranes.

67 Combining precursor asymmetric hollow fiber formation and optimized pyrolysis creates a

68 With a phase-matched hollow-fiber geometry, the generated beam was found to e

69 els of anticancer activity, cytotoxicity and hollow fiber (HF) activity, for chemotherapeutic agents

70 ormance, water-stable MOF-303 membranes with hollow fiber (HF) geometry and preferentially tailored c

71 system, a silica/alumina (SiO(2)/Al(2)O(3)) hollow-fiber hydrogen membrane was packed with a selecti

72 in-line filter based on diffusion through a hollow fiber hydrophilic membrane served to separate sma

73 actor NF-kappaB, was induced in cells within hollow fibers implanted in living mice, and a detailed p

74 e model predictions were validated using the hollow fiber infection model (HFIM) system.

75 induced by PBP3 inhibition over 168 h in the hollow fiber infection model experiments with eventual r

76 rgistic (alpha = 2.475), as was shown in the hollow fiber infection model.

77 o be a promising combination in our in vitro hollow fiber infection model.

78 Therapy was started in our hollow-fiber infection model on day 0; garenoxacin was a

79 iquid membrane immobilized in the pores of a hollow fiber into 20 muL of the acceptor solution.

80 The outer layer of the I(2)PS hollow fiber is found to serve as a buffering layer that

81 edure for in vivo bioluminescence imaging of hollow fibers is described.

82 uminescence occurring within the translucent hollow fibers is detected using a miniature photomultipl

83 e flow (Q(d)) set at 42 +/- 3 ml/min using a hollow fiber kidney with mass transfer area coefficients

84 and are made to flow through capillary-like hollow fibers lined with endothelial cells.

85 oextraction of phthalate esters under termed hollow fiber liquid membrane-protected solid-phase micro

86 p all-in-one concept for at-line coupling of hollow fiber liquid-phase microextraction (HF-LPME) to c

87 A three-phase hollow-fiber liquid phase microextraction for o-phenylph

88 We developed and validated a three-phase hollow-fiber liquid-phase microextraction method, couple

89 his work presents a new generation multibore hollow fiber (MBF) membrane with excellent mechanical du

90 sludge supplemented with CO added through a hollow fiber membrane (HFM) module in continuous thermop

91 This study describes a combination between hollow fiber membrane and dispersive liquid-liquid micro

92 trated that the permeation properties of the hollow fiber membrane can be facilely tailored via manip

93 The COF thin film-alumina hollow fiber membrane composites have showcased promisin

94 Dissolved methane removal using a hollow fiber membrane contactor achieved an average remo

95 mploying a tube-in-tube configuration with a hollow fiber membrane demonstrates the efficiency and re

96 through a probe-mounted polydimethylsiloxane hollow fiber membrane directly immersed into a dichlorom

97 The newly fabricated NF hollow fiber membrane exhibits an average pure water per

98 Analytical enrichment during continuous hollow fiber membrane extraction involves the movement o

99 fined dry gel conversion (VCDGC) for zeolite hollow fiber membrane fabrication.

100 The fabricated hollow fiber membrane has a narrow pore size distributio

101 The method uses a semipermeable hollow fiber membrane immersion probe to transfer analyt

102 es and scaling up of the outer-selective TFC hollow fiber membrane modules for PRO power generation.

103 s through a microfluidic chamber mimicking a hollow fiber membrane oxygenator and validate the model

104 ion of a La0.6Sr0.4Co0.8Ga0.2O3-delta (LSCG) hollow fiber membrane reactor with Ni/LaAlO3-Al2O3 catal

105 hen grafting it on poly(ether sulfone) (PES) hollow fiber membrane supports.

106 A hollow fiber membrane system was evaluated to extract RE

107 ly permeable poly(ether sulfone) (PES) based hollow fiber membrane was developed via a one-step dry-j

108 For the first time, a hollow fiber membrane was used in removing the ultrafine

109 Analytes diffuse through a hollow fiber membrane, where they are then dissolved by

110 firming the structural integrity of the LSCG hollow fiber membrane.

111 in the inner and outer surface of an alumina hollow fiber membrane.

112 The CHM consists of a gas-permeable hollow-fiber membrane coated with an alginate-based hydr

113 e preconcentrated in a flow-through silicone hollow-fiber membrane inlet held in a GC oven.

114 For cost-effective processing, hollow fiber membranes can be utilized to recover 90-95%

115 sts demonstrate that the newly developed PRO hollow fiber membranes can withstand trans-membrane pres

116 The newly developed tight UF hollow fiber membranes display huge potential for treati

117 based membrane bioreactor system integrating hollow fiber membranes for efficient gas delivery and ul

118 d well-constructed thin-film composite (TFC) hollow fiber membranes for forward osmosis (FO) applicat

119 e support, one may substantially sustain PRO hollow fiber membranes for power generation.

120 Selective hollow fiber membranes have been fabricated with a singl

121 ts reveal that dry gel-processed CHA zeolite hollow fiber membranes have excellent gas and hydrocarbo

122 We believe that the developed TFC PRO hollow fiber membranes have great potential for osmotic

123 so, new reactor designs involving the use of hollow fiber membranes have reduced mass transfer barrie

124 concentration during on-line analysis using hollow fiber membranes is reported.

125 However, the development of PRO hollow fiber membranes is still in its infancy.

126 A bundle of porous polypropylene hollow fiber membranes is used to bring the gaseous samp

127 This approach is successfully extended to hollow fiber membranes operating in organic solvent reve

128 report hyperselective carbon molecular sieve hollow fiber membranes showing H(2)/CO(2) selectivity ex

129 We report on composite hollow fiber membranes that can efficiently separate a m

130 roach to fabricate thin-film composite (TFC) hollow fiber membranes via interfacial polymerization fo

131 Flat membranes as well as hollow fiber membranes were analyzed by MALDI imaging.

132 ayer asymmetric carbon molecular sieve (CMS) hollow fiber membranes with excellent gas separation pro

133 -nm thick, layered graphene oxide (GO)-based hollow fiber membranes with grafted, brush-like CO2-phil

134 highly robust thin film composite (TFC) PRO hollow fiber membranes with high power densities.

135 Asymmetric carbon molecular sieve (CMS) hollow fiber membranes with tunable micro- and macro-str

136 Novel UF hollow fiber membranes with well-defined nanopores and s

137 This study was designed to determine whether hollow fiber membranes, such as those used in a bioartif

138 ze outer-selective thin-film composite (TFC) hollow fiber membranes, which is in an urgent need for o

139 nd biogas separately supplied via bubbleless hollow fiber membranes.

140 human clonal ARPE-19 cells encapsulated into hollow fiber membranes.

141 eactor (MBfR), with methane supplied through hollow fiber membranes.

142 are used to form nanoparticle-functionalized hollow fiber membranes.

143 hesized and engineered into high-performance hollow fiber membranes.

144 and cost-effective approach to fabricate NF hollow fiber membranes.

145 s is presented in this study to fabricate NF hollow fiber membranes.

146 ng polymeric optical fibers (POFs) and using hollow-fiber membranes (HFMs) to deliver bubble-free CO(

147 lectrically conductive, porous, nickel-based hollow-fiber membranes (Ni-HFMs) was developed to treat

148 Thin-film composite (TFC) hollow-fiber membranes were prepared.

149 ds, such as tangential flow filtration using hollow-fiber membranes, suffer from membrane fouling, le

150 degrees C) pyrolysis of polyimide precursor hollow-fiber membranes.

151 ctic solvents (HDES) as extractant phases in hollow fiber microporous membrane liquid-liquid extracti

152 Furthermore, a hollow fiber model of Cryptosporidium infection replicat

153 ate pharmacokinetic profiles measured in the hollow fiber model were similar to the predicted in-vivo

154 ce, C3HeB/FeJ mice, guinea pigs, and a mouse hollow-fiber model of infection.

155 infected by the aerosol route and in a mouse hollow-fiber model that may mimic in vivo granulomatous

156 In the hollow-fiber model, the mutant phenotype was not differe

157 erosol model were also analyzed in the mouse hollow-fiber model.

158 elected mutants also attenuated in the mouse hollow-fiber model.

159 rane inlet mass spectrometry incorporating a hollow-fiber Nafion membrane has been evaluated for the

160 The newly developed tight UF hollow fibers not only possess a small mean pore diamete

161 nsion enclosed within a small semi-permeable hollow fiber (OD: 220 mum, membrane thickness: 20 mum, m

162 (allo-HD), the neonate's blood flows through hollow fibers of a miniature 0.075 m(2) hemodialyzer, wh

163 The gas-permeable hollow fibers of the MBfR enabled high H(2) and CO(2) ut

164 e AV-ECMO circuit was established by using a hollow fiber oxygenator, primed with maternal sheep bloo

165 AVCO2R was implanted using a hollow-fiber oxygenator attached to 12 F and 14 F vascul

166 low priming volume and a new high-efficiency hollow-fiber oxygenator in a circuit with a check valve

167 sents its individual constituents, we used a hollow-fiber peptide production scheme followed by the m

168 Electrically conductive, graphene-coated, hollow-fiber porous membranes were used as cathodes in a

169 em sensitive to galactose in a microdialysis hollow fiber receptacle.

170 ed surfaces of poly(amide-imide) macroporous hollow fibers (right).

171 lvent was placed into a polypropylene porous hollow fiber segment supported by capillary forces and s

172 A novel concept of a fluorescence affinity hollow fiber sensor for transdermal glucose monitoring i

173 However, when the hollow fiber sensor is exposed to glucose, glucose diffu

174 By placing the GIP within a dialysis hollow fiber sensor, a microsensor has been developed fo

175 e QCL beams were combined using a bifurcated hollow fiber, sent through the flue tube (inside diamete

176 cross section can be prepared in one step by hollow fiber spinning, double mantle spinning or centrif

177 We performed hollow fiber studies for both bactericidal and sterilizi

178 branes, particularly on industrial-preferred hollow fiber substrates, remains challenging.

179 l polymerization on a polyethersulfone (PES) hollow fiber support.

180 heet coatings were prepared on alpha-alumina hollow fiber supports by vacuum filtration and then tran

181 the lumen side of well-constructed Matrimid hollow fiber supports via interfacial polymerization.

182 We then used the hollow fiber system (HFS) model of intracellular tubercu

183 ed an exhaustive review of literature on the hollow fiber system (HFS) model, murine model, and guine

184 NA sequencing of repetitive samples from the hollow fiber system and in independent protein abundance

185 The in vitro hollow fiber system model has been qualified by the Euro

186 triaxone once-daily doses for 28 days in the hollow fiber system model of intracellular MAC (HFS-MAC)

187 We performed a series of studies in the hollow fiber system model of intracellular Mycobacterium

188 This poor GBT efficacy is mirrored in the hollow fiber system model of Mab (HFS-Mab).

189 ifloxacin was found to be efficacious in the hollow fiber system model of pediatric intracellular tub

190 The in vitro hollow fiber system model of tuberculosis (HFS-TB) is ab

191 The hollow fiber system model of tuberculosis (HFS-TB) is de

192 The in vitro hollow fiber system model of tuberculosis (HFS-TB), in t

193 The hollow fiber system model of tuberculosis (HFS-TB), in t

194 uestions: in vitro susceptibility tests, the hollow fiber system model of tuberculosis, mice, and gui

195 In the hollow fiber system model, lung concentration-time profi

196 Based on a hollow-fiber system model of tuberculosis, we hypothesiz

197 and T(1/2) = 8.0 hr)) were implemented in a hollow-fiber system.

198 pharmacokinetic-pharmacodynamic studies of a hollow-fiber system.

199 ndard beliefs have been tested in controlled hollow fiber systems experiments.

200 ed THP-1 macrophages with Mtb and inoculated hollow fiber systems.

201 rol (1) was further evaluated in vivo in the hollow fiber test and in the murine P-388 leukemia model

202 e encapsulation of bacilli in semidiffusible hollow fibers that are implanted subcutaneously into mic

203 ield sampler allows SPME fibers and silicone hollow fibers to be immersed and equilibrated in situ, w

204 branes on the inner lumen surface of alumina hollow fibers (TpPa-1/Alumina).

205 Using hollow-fiber tuberculosis studies, we recently demonstra

206 into scale-up considerations, an integrated hollow fiber-tubular membrane system can process microal

207 were discovered possessing among the highest hollow fiber tumor assay scores observed in hundreds of

208 an a (1-4) linked glucose polymer forms soft hollow fibers used for energy storage.

209 The polyethersulfone hollow fibers used, which have a 0.8-mm inner diameter,

210 talline membranes were fabricated on alumina hollow fibers using an in situ solvothermal synthesis me

211 c phase, impregnated within the pores of the hollow fiber wall which was immersed in the sample solut

212 uld be easily achieved when the self-support hollow fiber was challenged with less than 300 nm partic

213 a graphene oxide-silica composite reinforced hollow fiber was prepared via sol-gel technology and use

214 dissociation (IRMPD) is presented in which a hollow fiber waveguide (HFWG) is used to transmit IR rad

215 Alumina- and stannia-based hollow fibers were synthesized via simple sol-gel proced

216 00x concentration within about 1 min using a hollow fiber with a 50 mum internal radius.

217 ygenator, consisting of cross-wound silicone hollow fibers with a surface area of 1.5 m2 with a primi

218 nes in single and multiple poly(amide-imide) hollow fibers, with H2/C3H8 and C3H6/C3H8 separation fac

219 MSCs were seeded on the extraluminal side of hollow fibers within a bioreactor where they indirectly