ライフサイエンスコーパス: oil droplet

1 ries with ion size from diglycine to a 1 mum oil droplet.

2 ed the concentration of beta-carotene in the oil droplet.

3 than that of, macroscopic particles such as oil droplets.

4 of oleosin promotes the clustering of small oil droplets.

5 with a rising plume of small (< 1-mm radius) oil droplets.

6 the size distribution and rise speed of the oil droplets.

7 initially transported in the form of trapped oil droplets.

8 from adsorbing onto the surface of silicone oil droplets.

9 ) was similar, due to a scavenging effect of oil droplets.

10 ene microspheres, phospholipid vesicles, and oil droplets.

11 nduced caseating granulomas that centered on oil droplets.

12 exist with lipid-stabilized (400-800 nm) DAG oil droplets.

13 le phase separation and mixing inside binary oil droplets.

14 ) was similar, due to a scavenging effect of oil droplets.

15 ser protein network with uniformly dispersed oil droplets.

16 y the optical disturbance caused by adherent oil droplets.

17 salt) or extract ions from (desalt) water-in-oil droplets.

18 nucleic acid (NA) nanotubes inside water-in-oil droplets.

19 the thermoresponsive microstructure of crude oil droplets.

20 hieving high energy-efficient coalescence of oil droplets.

21 tion due to their internalization inside the oil droplets.

22 ) and bulk oil (27.11 %), due to the smaller oil droplets.

23 degradation and photo-oxidation of dispersed oil droplets.

24 ntaining soy protein isolate(SPI)-stabilized oil droplets.

25 ly inhibited the creaming and coalescence of oil droplets.

26 iquids was circumvented by employing mineral oil droplets.

27 tizing sample/reagent mixtures into water-in-oil droplets.

28 ani can actively modify the size-spectrum of oil droplets.

29 hich enables the generation and digestion of oil droplets.

30 d solid, simply because there are no ions in oil droplets.

31 bubbles induce a backpressure underneath the oil droplets.

32 dria surrounded by hundreds of small, orange oil droplets.

33 ue to the larger sizes of both complexes and oil droplets.

34 n by interconnected clusters of proteins and oil droplets.

35 ascribed to protein aggregates and entrapped oil droplets.

36 e molecules were not able to migrate between oil droplets.

37 nopus egg extracts into cell-sized 'water-in-oil' droplets.

38 of physically or chemically dispersed crude oil droplets (1-86 mum in diameter) by heterotrophic din

39 behaviour, with smaller and more homogeneous oil droplets ( ~ 12 um) than those from kappa-carrageena

40 dioxide particles (1% TiO(2)) and essential oil droplets (2% rosemary oil) as functional components.

41 ectrostatic zeta potential characteristic of oil droplets(9), we propose the existence of a strong el

42 floaters from presumed intravitreal silicone oil droplets after injections of pegcetacoplan using a M

43 determine the incidence of presumed silicone oil droplets after intravitreal bevacizumab was prepared

44 likely created a yield stress that prevented oil droplet aggregation and subsequent creaming.

45 ssibility or Caco-2 cell uptake and produced oil droplet aggregation.

46 otein aggregates due to exposure to silicone oil droplets, although oil droplets with surface-adsorbe

47 able assumptions about the properties of the oil droplets, an estimate of the flow rate was made that

48 that within minutes bacteria attach onto an oil droplet and extrude polymeric streamers that rapidly

49 ects of electrochemistry using the attoliter oil droplet and offers complementary analytical techniqu

50 ed lower digestibility, attributed to larger oil droplets and a minimized surface area.

51 The interactions between crude oil droplets and air bubbles were studied by the droplet

52 sted that protruding particles get torn from oil droplets and carry oil with them, causing the torn p

53 quantify the beta-carotene concentration in oil droplets and determine the partitioning characterist

54 However, uncertainties in the formation of oil droplets and difficulties in measuring their size in

55 Mexico, forming deep-sea plumes of dispersed oil droplets and dissolved gases that were largely degra

56 leukocytes with protease sensors in water-in-oil droplets and incubating for 1 h to measure protease

57 Results showed that the interaction between oil droplets and intertidal sediments was not particular

58 ed to further study the interactions between oil droplets and marine organisms and could significantl

59 can potentially distinguish between silicone oil droplets and protein particles in a size range that

60 tion of autonomic behavior in enzyme-powered oil droplets and provide a new platform for increasing t

61 ymeric microbial aggregates formed on rising oil droplets and their associated hydrodynamic impacts i

62 , tapetosomes are composed of oleosin-coated oil droplets and vesicles, both of which are assembled i

63 nic surfactants between shrinking microscale oil droplets and water under nonequilibrium conditions.

64 pared from the modified starches had smaller oil droplets and were more stable during storage, compar

65 eir different packaging (e.g., esterified in oil droplets) and light-absorbance properties compared w

66 ce, induced by lipid free radicals formed in oil droplets, and (2) in the continuous phase induced by

67 he surface of cellular or in vitro generated oil droplets, and decreases LD size.

68 The cones, along with their oil droplets, and rods are conserved across birds - with

69 with specific dipole arrangement to hydrate oil droplets, and that this arrangement is highly suscep

70 mechanoreceptors (C-LTMRs) were activated by oil droplets, and their optogenetic activation elicited

71 ns in the parabrachial nucleus impaired both oil droplet- and C-LTMR-evoked wet dog shakes.

72 n mediates wet dog shakes evoked by water or oil droplets applied to back hairy skin of mice.

73 croencapsulate lipid fraction, so that small oil droplets are entrapped within a dry matrix of roe pr

74 our strategy, monodisperse 1.5 nL agarose-in-oil droplets are produced with a high frequency using a

75 higher-energy micrometre and sub-micrometre oil droplets are spontaneously produced from larger ones

76 rsions of small water droplets within larger oil droplets are themselves dispersed in a continuous aq

77 h the aim of investigating the properties of oil droplets as a function of composition via an automat

78 s spectrometry (MS), widely applied water-in-oil droplet-based microfluidics for single cell analysis

79 stability, maintaining uniformly distributed oil droplets below 4 mum after 21 days-comparable to com

80 nce from membrane proteins by using water-in-oil droplet bilayers.

81 Because of oil droplet binding, a 24-hr exposure was sufficient to

82 Here we show that water-dispersed oil droplets can be reversibly temperature-tuned to icos

83 m-made glass microfluidic platform, in which oil droplets can be trapped as single droplets, or sever

84 Even preformed oil droplets can take in CNTs from the aqueous solution

85 onal structure formed by M-PIDF stacking and oil droplet capture.

86 WPCH-based interfacial layer prevented oil droplets coalescence during and after processing mor

87 We provide evidence of single attoliter oil droplet collisions at the surface of an ultra-microe

88 y a smaller size and lower uniformity of the oil droplets compared to the control and other samples.

89 n had a higher risk of intravitreal silicone oil droplets compared with priming the syringe (6.4% [47

90 hanced collision probability due to confined oil droplet concentration under dielectrophoretic forces

91 edented resolution for direct observation of oil droplet deposition, deformation, and detachment duri

92 ration resulted in a concomitant increase in oil droplet diameter and microcapsule surface oil conten

93 but did not prevent coalescence, because the oil droplets diameter doubled during 7days.

94 ese nutrients in the sea that when dispersed oil droplets dilute to low concentrations these low leve

95 The emulsions comprised oil droplets dispersed in the water, where glutelin and

96 he stabilization of nanoemulsions, nanosized oil droplets dispersed in water, is commonly achieved th

97 ified samples due to the finer, more uniform oil droplet dispersion.

98 live cells, improving the coalescence of the oil droplets due to substantial cellular and intracellul

99 m much deeper releases of 5 mm diameter live oil droplets, during which ebullition occurs at water de

100 or measurements of deformations in dye-doped oil droplets embedded in soft materials or biological ti

101 colony sizes in PicoShells than in water-in-oil droplet emulsions (P < 0.05).

102 ss production, such as well plates, water-in-oil droplet emulsions, and nanowell arrays, do not provi

103 acroscale bubbles add buoyancy on top of the oil droplets, enhancing the oil receding at the oil-wate

104 Within the SSAW field, water-in-oil droplets experience an acoustic radiation force and

105 cate fibrinogen adsorbed to docetaxel-loaded oil droplets facilitates the retention of the droplets w

106 A water-in-oil droplet formulation withstands the harsh chemical (S

107 red foam is employed for separation of micro-oil droplets from an aqueous solution.

108 Energy-efficient recovery of oil droplets from ice-cold water, such as oil sands tail

109 conductive membrane microchannels to confine oil droplets from the oil-water emulsion for achieving h

110 The wax-wetting sponge can adsorb oil droplets from wastewater between 5 and 40 C with 90

111 olution; and densities and volumes of liquid oil droplets, gas bubbles, and two-phase droplet-bubble

112 ith integrated metal electrodes for water-in-oil droplet generation to dynamically create and manipul

113 ontrol were implemented to provide efficient oil droplet generation, manipulation, and immobilization

114 docetaxel administered in fibrinogen-coated oil droplets improved the median survival time of B16F10

115 An oil droplet in water can be in the Cassie state (with wa

116 present an emulsion system in which silicone oil droplets in a nematic liquid crystal spontaneously i

117 cro-channels were made hydrophilic to obtain oil droplets in an aqueous continuous phase.

118 Oil droplets in an aqueous surfactant solution are drive

119 Xanthophylls were easily released into oil droplets in both 5% and 10% emulsions.

120 s measured for air bubbles approaching crude oil droplets in different aqueous phases.

121 be automated to detect and track oil spills/oil droplets in dynamic systems.

122 ant difference between the particle sizes of oil droplets in emulsions with roasted and raw hazelnut

123 mentally reproduced dispersed plumes of fine oil droplets in Gulf of Mexico seawater and successfully

124 matches the isoelectric point of bubbles and oil droplets in independent electrophoretic experiments.

125 of reactions in pico- to nanoliter water-in-oil droplets in microfluidic devices provides a solution

126 ipid oxidation products may transfer between oil droplets in model food emulsions stabilized by exces

127 The incorporation of oil droplets in MOS resulted in a two-way (rising and si

128 ther complicated by the presence of silicone oil droplets in solution.

129 this optimum can increase the persistence of oil droplets in the environment from weeks to years.

130 tients who experienced intravitreal silicone oil droplets in the eye after intravitreal bevacizumab i

131 irmed by the small and uniformly distributed oil droplets in the micrographs of the emulsions.

132 itiation of lipid autoxidation within single oil droplets in Tween-20-stabilized oil-in-water emulsio

133 were added to negatively charged nanoscopic oil droplets in water.

134 nt-moon and use these particles to stabilize oil droplets in water.

135 environments (e.g. microbes around a rising oil droplet) in microfluidics remains challenging.

136 Findings revealed that the size of oil droplets increased after six weeks and resulted in i

137 However, diffusion coefficients of oil droplets increased for emulsions containing roasted

138 ese results suggest that the presence of the oil droplets increased the extractability, stability, an

139 The incidence of silicone oil droplet injections was 0.03% (1 of 3230) from Octobe

140 increased the amount of protein both on the oil droplet interface and on the particle surface as con

141 he structural and functional augmentation of oil droplet interfaces and contributes to the surface en

142 abitats, including aggregation together with oil droplets into flocs and hydrocarbon degradation abil

143 e deep sea, facilitated the incorporation of oil droplets into microbial and planktonic food web, and

144 hat is capable of sorting picoliter water-in-oil droplets into multiple outputs using standing surfac

145 rs (Empidonax spp.) in which the traditional oil droplet is replaced with a complex of electron-dense

146 icity in vitro of docetaxel applied in olive oil droplets is at least as great as that of docetaxel a

147 he changes in the interfacial tension of the oil droplets is due to the partitioning of the surfactan

148 marine environments, where the abundance of oil droplets is much lower than in laboratory experiment

149 sed to impart biocompatibility to aqueous-in-oil droplets is to synthesize a triblock copolymer surfa

150 t in the retentate was 3.6 mg L(-1), and all oil droplets larger than 140 nm were removed.

151 storage of phospholipid-stabilized water-in-oil droplets, leading successfully to the scalable and a

152 to the formation of massive OPAs of smaller oil droplets (< approximately 5-10 mum).

153 Water-in-oil droplet microfluidics promises capacity for high-thr

154 The laser spectra from oil-droplet microlasers can chart cytoplasmic internal s

155 ces imply that the nanometric confinement of oil droplets modifies the fat crystal habit.

156 els: giant unilamellar vesicles and water-in-oil droplet monolayers.

157 ncentration reduction and correspondingly to oil droplet nucleation there.

158 th emitted soot particles, unlike the purely oil droplets observed at the lubrication system vent.

159 The size of the oil droplets of all double emulsions increased in oral p

160 ow chemotactic signalling between microscale oil droplets of different chemistries in micellar surfac

161 polymerase chain reaction (PCR) in water-in-oil droplets of nanoliter volumes.

162 onitoring the effects of subvisible silicone oil droplets on the stability of protein formulations.

163 ch as plastic micro-particles and emulsified oil droplets, our biomimetic filtration devices exhibit

164 hip and consistent encapsulation in water-in-oil droplets over extended periods of time.

165 increases leaf TAG accumulation, leading to oil droplet overexpansion through fusion.

166 n discrete, volumetrically defined, water-in-oil droplet partitions.

167 ck (Melanogrammus aeglefinus) bind dispersed oil droplets, potentially leading to more profound toxic

168 brane foulants, including organic molecules, oil droplets, proteins, bacteria and inorganic colloids,

169 For example, when an oil droplet rapidly shrinks in size, it can compress the

170 minutes, nonionic surfactants partition into oil droplets, reaching a nonequilibrium steady-state con

171 Understanding the fate of spilled oil droplets requires bridging these length scales and d

172 l ecosystems can interact with the dispersed oil droplets, resulting in the formation of Oil Particle

173 simulates environmental conditions around an oil droplet rising through ocean water as commonly occur

174 hases from a single mixed liquid phase, like oil droplets separating from water.

175 Variously colored oil droplets signify high color vision ability.

176 While many approaches use water-in-oil droplets (single emulsions) for fluorescence-activat

177 vealed RPE cells with intracellular silicone oil droplets, singly dispersed membrane-bound melanin gr

178 eceptor subtypes, including spectral tuning, oil droplet size and pigmentation, synaptic targets, and

179 from the modified starches were studied for oil droplet size distribution and storage stability.

180 olated by keeping the oil concentrations and oil droplet size distributions comparable between parall

181 The physical state of the bulk and the oil droplet size were the major structural levers to mod

182 o stable semi-solid emulsion-gels (20-31 mum oil droplet size, 105-115 Pa.s viscosity and 60-65 Pa yi

183 ughout the simulated gastrointestinal tract (oil droplet size, zeta-potential, and microstructure).

184 5.84 mins for the broth supernatant) and low oil droplet sizes (18.09 um for the broth).

185 All emulsions had similar initial oil droplet sizes and were submitted to simulated gastro

186 nt at different temperatures of seawater and oil droplet sizes was also investigated.

187 Variation in oil droplet sizes, overall surface area of oil/water int

188 Lg based emulsions, betaLg-polyCA had larger oil droplet sizes, stronger negative zeta potentials (-6

189 odynamic treadmill, developed to keep rising oil droplets stationary in the lab frame for continuous

190 d treatment were key factors influencing the oil droplet structuring and therefore the emulsion stabi

191 tion could be due to partial coverage of the oil droplet surface by particles.

192 -like polyvinyl alcohol (PVA) regions at the oil droplet surface to produce floating heterostructures

193 ein via protein adsorption onto the silicone oil droplet surface.

194 We have observed that aqueous-in-oil droplet surfaces can be made biocompatible and heat

195 ick and robust interfacial layers around the oil droplet surfaces, which increased the resistance of

196 : (1) rapid electric-field redistribution of oil droplet surfactant molecules, (2) enhanced collision

197 Liquid lipid nanocapsules are oil droplets surrounded by a protective shell, which ena

198 ighest in the 10% emulsion, which had larger oil droplets than the 5% emulsion.

199 compartmentalized and processed in water-in-oil droplets that are individually stored in cylindrical

200 e specific protease activities from water-in-oil droplets that contain single cells.

201 s and conditions experienced by solubilizing oil droplets that influence emulsion properties.

202 Microfluidic water-in-oil droplets that serve as separate, chemically isolated

203 When confined in cell-sized water-in-oil droplets, the DNA crosslinker design guides the loca

204 Using the surface charge of the foam and oil droplets, the solution pH (5.6) for maximum separati

205 ual transposon mutants into growth medium-in-oil droplets, thereby enabling isolated growth, free fro

206 ed that RPE cells can phagocytose emulsified oil droplets, this report represents the first in vivo d

207 ective attributes the negative charge on the oil droplet to charge transfer of electron density from

208 ed a high-stress state by injecting an inert oil droplet to generate high strain in the HFR, demonstr

209 ticles behave as projectiles penetrating the oil droplets to depths varying from approximately 2 to 1

210 veloped a method based on picoliter water-in-oil droplets to induce coacervation in Escherichia coli

211 istribution can increase the availability of oil droplets to organisms feeding on smaller particles,

212 The worms were encapsulated in water-in-oil droplets to restrict random locomotion.

213 Microbes reshape oil droplets to speed biodegradation.

214 Furthermore, the time needed for crude oil droplets to spread over the air bubble surfaces (ref

215 s from blood components, within the water-in-oil droplet, to increase PCR reaction efficiency with bl

216 stabilized by an ionic liquid, in which the oil droplet trapped a highly hydrophobic redox probe, ru

217 arting with phospholipid-stabilized water-in-oil droplets trapped in a static droplet array, lipid mo

218 surements on the thermophoretic behaviors of oil droplets under a light-generated temperature gradien

219 laboratory experiments on methane-saturated oil droplets under emulated deep-water conditions, provi

220 tene released from the plant matrix into the oil droplets was highest in the 10% emulsion, which had

221 concentration of carotenoids in the emulsion oil droplets was quantified.

222 izing manganese-Schiff base catalysts at the oil droplet-water interface or within the droplet core,

223 ted with docetaxel-loaded, fibrinogen-coated oil droplets were apparently free of disease after 139 d

224 Highly monodisperse oil droplets were generated, immobilized in an array of

225 Silicone oil droplets were reported in 109 eyes (71.7%).

226 SE relies on the formation of small oil droplets when an oil/surfactant mixture is titrated

227 inct constituents were isolated: low-density oil droplets, which contained oleosins and TAGs, and rel

228 , reported that some particles penetrate the oil droplets, which results in further breakup while for

229 fter gastric conditions leading to coalesced oil droplets, while Tween80 emulsions remained stable.

230 ells are encapsulated in individual media-in-oil droplets with a dual-fluorescent reporter HSV-1, ena

231 Using cell-sized oil droplets with controlled physicochemical properties

232 Linear polymersomes produced polydisperse oil droplets with diameters of ~50 mum regardless of the

233 opologies by fusing elastic hexadecapoles of oil droplets with elastic dipoles of glycerol droplets.

234 We report the collisions of single emulsion oil droplets with extremely low dielectric constants (e.

235 e emulsions (HIPEs) containing small uniform oil droplets with good storage and thermal stability.

236 re, we investigated the interaction of crude oil droplets with intertidal and subtidal sediments, as

237 t size (363.07 +/- 34.56 nm), orderly-packed oil droplets with monomodal distribution, the highest ze

238 s were found before and after mixing 'clean' oil droplets with pre-oxidized ones.

239 Oil droplets with radii 10 < R < 100 mum were colonized

240 exposure to silicone oil droplets, although oil droplets with surface-adsorbed trastuzumab exhibited

241 hen they were encapsulated within digestible oil droplets with the smallest size.

242 ypothesis also explains the fragmentation of oil droplets with time, which occurred after long hours

243 essure gradient, leading to the centering of oil droplets with velocities comparable to nuclear ones.

244 enerate such series of monodisperse water-in-oil droplets (with a frequency of up to 10 Hz) from a sa

245 emoved >95% of the methane from ~3.5 mm live oil droplets within 14.5 min, prior to gas bubble format

246 ecadienal, were found to equilibrate between oil droplets within 30 min.

247 tion within fibrillar networks by condensing oil droplets within biopolymer gels.

248 rough weak oil-water interactions, such that oil droplets would be unstable and coalesce, contrary to