ライフサイエンスコーパス: foam

1 nal insulation product, expanded polystyrene foam.

2 ates in the United States that produce sheet foam.

3 method is demonstrated to produce auxetic PU foam.

4 es on self-standing porous nickel diselenide foam.

5 petitively incubated on biospecific chitosan foam.

6 ere reported more frequently with budesonide foam.

7 he trapping zone and a further growth of the foam.

8 m water using polyester polyurethane (PESPU) foam.

9 individual pure TiO2 sheets or pure graphene foam.

10 in the large-scale production of auxetic PU foams.

11 carbon nanotube (CNT) films and 3D graphene foams.

12 ve proctosigmoiditis who received budesonide foam 2 mg/25 mL twice daily for 2 weeks, then once daily

13 Foaming activity was nearly doubled compared to non-ferm

14 the development of a new class of engineered foam adsorbents with the potential to revolutionize wate

15 on experiments were conducted using National Foam AFFF, which contains anionic fluorotelomer sulfonat

16 eployment of 33000 L of aqueous film forming foam (AFFF) concentrate that contained proprietary fluor

17 o the use of 33000 L of aqueous film forming foam (AFFF) concentrate.

18 nic surfactants used in aqueous film-forming foam (AFFF) formulations were studied for their environm

19 rocosms amended with an aqueous film-forming foam (AFFF) solution.

20 n biosolids-amended and aqueous film-forming foam (AFFF)-impacted soils results in two potential path

21 use of PFAS-containing aqueous film-forming foams (AFFF) in firefighting activities.

22 inated surfactant-based aqueous film-forming foams (AFFFs) are made up of per- and polyfluorinated al

23 ommonly associated with aqueous film forming foams (AFFFs) at sites without known AFFF contamination

24 impacted by the use of aqueous film-forming foams (AFFFs) present elevated concentrations of perfluo

25 The application of aqueous film-forming foams (AFFFs) to extinguish chlorinated solvent-fueled f

26 Aqueous film-forming foams (AFFFs), containing per- and polyfluoroalkyl subst

27 mergency responses with aqueous film-forming foams (AFFFs), milligrams per liter concentrations of an

28 es with PFAS-containing aqueous firefighting foams (AFFFs).

29 Herein, we propose anodized Fe foams (AFFs) with multidimensional nano/micro-architectu

30 ity parameters HM (maximum height reached by foam after CO2 injection) and HS (foam stability height

31 The SMCLs for corrosivity and foaming agents may be outdated.

32 oride, color, copper, corrosivity, fluoride, foaming agents, iron, manganese, odor, pH, silver, sulfa

33 Over 4 h, stomach contents (foam, air, and liquid) were imaged using magnetic resona

34 Open-celled, elastomeric foams allow the simple design of fully 3D pneumatic soft

35 rowth of 2D amorphous FePO4 nanosheets on Ni foam (Am FePO4 /NF).

36 Using chitosan foam and a luminescence bioassay we obtained maximum inh

37 ionship between amount of gas trapped in the foam and amount of gas emitted during each episode, we d

38 y inhibit Ostwald ripening in a multitude of foam and emulsion applications.

39 of 5.42g/g and 1.23g/g, respectively, a good foam and emulsion stability and important DPPH radical s

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

41 affects the ability to form a stable head of foam and plays an important role in beer staling.

42 thermal stability, solubility, emulsifying, foaming and antioxidant activity.

43 vergrowth of filamentous bacteria results in foaming and bulking associated disruptions.

44 , while significant decrease was observed in foaming and emulsion properties upon roasting.

45 In addition, it presented good foaming and emulsion properties.

46 degrees C or 90 degrees C for 30min) on the foaming and interfacial properties of acid and sweet whe

47 These results confirmed the pronounced foaming and interfacial properties of acid camel whey, e

48 The increase in foaming and reduction in foam degradation of the protein

49 evolution of size and shape distributions in foams and biological materials.

50 ng capacity: WHC, oil holding capacity: OHC, foaming, and emulsion properties) of this polymer were s

51 widely exploited to stabilize emulsions and foams, and in materials synthesis.

52 Fragments, films, foams, and pellets/beads were positively correlated with

53 emonstration of a SnO2-coated macroporous Cu foam anode by employing a facile and scalable combinatio

54 The NiO nanowire foam anode possesses low equivalent series resistance ca

55 pace volume six times the volume of graphene foam anode.

56 Infant products containing polyurethane foam are commonly treated with organophosphate flame ret

57 te for the emulsion's oil phase, elastomeric foams are created by polymerizing the continuous oil pha

58 tly synthesized on commercially available Ni foam as a renovated anode for Li-ion batteries.

59 ted the suitability of this N,P-doped carbon foam as an air electrode for primary and rechargeable Zn

60 idic chamber with three-dimensional graphene foam as anode, allowing nutritional medium to flow throu

61 terfacial films that stabilize emulsions and foams as well as interact to make networks that play key

62 Foaming-associated filamentous bacteria were isolated fr

63 d for their potential to reduce the titer of foaming bacteria in a mixed-microbial activated sludge m

64 pture under tension, it mimics the open cell foam behavior under compression and exhibits hysteresis

65 atalyzed by a hierarchically porous Ni3S2/Ni foam bifunctional electrocatalyst (Ni3S2/NF).

66 ances and long-lived greenhouse gases in the foam-blowing, refrigeration, and solvent sectors.

67 The combustion of foam boxes, rubber tires, and plastic bottles/bags in th

68 tructural transition in bilayer monodisperse foams by changing the foam liquid fraction in a physical

69 3D printing of polymeric foams by direct-ink-write is a recent technological brea

70 products (all 110 kcal): 2 drinks aerated to foams by whipping (to 490 mL), one drink that was stable

71 The NiO nanowire foam can be manufactured with bio-friendly chemicals and

72 The morphology of graphene-based foams can be engineered by reinforcing them with nanocry

73 Auxetic PU foams can be fabricated at room temperature (25 degrees

74 which tissue level material heterogeneity in foams can be used to improve deformation recovery after

75 Especially, emulsifying and foaming capacities were positively correlated to the pro

76 oil holding capacity, emulsifying capacity, foam capacity, gelatinization temperature, least gelatio

77 citric acid (THC) or water (THW), had a good foaming capacity (32-36%), whereas the pulp hydrocolloid

78 otein powders from oil cake exhibited better foaming capacity and a better emulsifying activity index

79 Foaming capacity and foam stability of CPI were found to

80 cellent water holding index, swelling index, foaming capacity and foam stability.

81 ding water absorption index, swelling index, foaming capacity and stability (3.38g/g, 5.24ml/g, 4.09

82 Foaming capacity and stability of rice flours increased

83 ture and the emulsion opacity as well as the foaming capacity and the foam stability were shown to be

84 nol (THE) or 20mM HEPES buffer (THH), had no foaming capacity.

85 ced the nitrogen solubility, emulsifying and foaming capacity.

86 etal anode and a three-dimensional graphitic-foam cathode.

87 Compared with the LC, both foams caused significantly increased gastric volumes and

88 ge IGF1R signaling suppresses macrophage and foam cell accumulation in lesions and reduces plaque vul

89 macrophages exhibit increased expression of foam cell differentiation markers including 15-lipoxygen

90 n of excess cholesterol, as well as improves foam cell efferocytic function.

91 ation antagonizes this program, resulting in foam cell formation and atherosclerosis; however, the mo

92 choline diet-enhanced endogenous macrophage foam cell formation and atherosclerotic lesion developme

93 macrophages may be an important mechanism of foam cell formation and contributor to atherosclerosis d

94 by oxidized low-density lipoprotein promotes foam cell formation and the progression of atheroscleros

95 ogenitor cell expansion and differentiation, foam cell formation and vascular inflammation.

96 thways that link innate immune activation to foam cell formation are still poorly identified.

97 amma in the induction of CD36 expression and foam cell formation by 15(S)-HETE.

98 t ANGPTL4 deficiency in macrophages promotes foam cell formation by enhancing CD36 expression and red

99 ctive role during atherosclerosis-associated foam cell formation by signaling through the miR-155-CAR

100 ogenic cytokine TGF-beta inhibits macrophage foam cell formation by suppressing the expression of key

101 No role for LKB1 in foam cell formation has previously been reported.

102 Inflammatory processes accompany Mvarphi foam cell formation in the artery wall, yet the relation

103 ration, differentiation into macrophages and foam cell formation in vitro and in vivo.

104 ced uptake of native LDL ex vivo and reduced foam cell formation in vivo, whereas sortilin overexpres

105 MC1-R confers protection against macrophage foam cell formation through a dual mechanism: It prevent

106 yte/macrophage proinflammatory responses and foam cell formation through coordinated and combined act

107 intracellular cholesterol accumulation (ie, foam cell formation) and inflammasome activation, the ex

108 modified low-density lipoprotein uptake and foam cell formation, all of which were abolished by bloc

109 oxidized low density lipoprotein uptake, and foam cell formation, critical events underlying the path

110 aining plasma lipoproteins lead to increased foam cell formation, the first step in the development o

111 stablish the role of LKB1 in atherosclerotic foam cell formation.

112 ol LDLR(-/-) mice, using an in vivo model of foam cell formation.

113 ophages resulted in increased LDL uptake and foam cell formation.

114 ich is a counterregulatory mechanism against foam cell formation.

115 rotein (oxLDL) by macrophages (Mvarphis) and foam cell formation.

116 Foam cell infiltration was responsible for 70% of false

117 n mediating cellular cholesterol efflux from foam cell macrophages and to identify the cellular chole

118 LDL in the presence of C1q alters macrophage foam cell survival or function.

119 tivation and thereby regulates macrophage to foam cell transformation.

120 open new avenues for an innovative anti-VSMC foam cell-based strategy for the treatment of vascular l

121 Thus, macrophage Hilpda is crucial to foam-cell formation and lipid deposition, and to control

122 iate into macrophages and macrophage-derived foam cells and cause atherosclerotic lesions.

123 ly associated with cardiovascular disease in foam cells and clinical specimens from patients with AS.

124 promotes cholesterol efflux from macrophage foam cells by directly up-regulating its key cellular me

125 to the plaque and impaired the formation of foam cells by enhancing cholesterol efflux from macropha

126 ich necroptosis was induced in THP-1-derived foam cells by serum deprivation.

127 otein degradation and uptake into macrophage foam cells in the arterial intima.

128 subsequent accumulation of leukocyte-derived foam cells in the artery wall.

129 iltration, thereby stimulating regression of foam cells in the artery.

130 cholesterol efflux capacity from macrophage foam cells is not associated with cardiovascular or all-

131 age phenotype, but how this is controlled in foam cells is not known.

132 /-)LDLR(-/-) mice develop significantly more foam cells than control LDLR(-/-) mice, using an in vivo

133 Foam cells undergo apoptosis and, if not efficiently cle

134 Macrophages transform into foam cells upon taking-in lipids.

135 them, we found that the level of miR-155 in foam cells was the most significantly elevated in a dose

136 as quantified by incubating human macrophage foam cells with apoB-depleted serum.

137 ntified using incubation of human macrophage foam cells with apolipoprotein B-depleted plasma.

138 internalize modified lipids, and convert to foam cells with diseased phenotypes.

139 efficient to promote the formation of hVSMC foam cells, a crucial vascular component determining the

140 ns (e.g. collagen, elastin) and lipids (e.g. foam cells, extracellular lipids) in the first 200 mum o

141 ated the caspase-3 and caspase-8 pathways in foam cells, which is responsible for the switch from nec

142 after SCI, macrophages are best described as foam cells, with lipid catabolism representing the main

143 after SCI, macrophages are best described as foam cells, with lipid catabolism representing the main

144 reby promoting the formation of inflammatory foam cells.

145 lated cholesterol is removed from macrophage foam cells.

146 y lipoproteins (LDLs), generating macrophage foam cells.

147 phagocytosis and efferocytosis in macrophage foam cells.

148 Here, we describe a mesoporous carbon foam co-doped with nitrogen and phosphorus that has a la

149 ted herein is a study of monolithic polyHIPE foam columns surface-grafted with a brush of polymer con

150 relative to the amount of Pu loaded onto the foam columns.

151 A metal-elastomer-foam composite that varies in stiffness, that can change

152 Here, by using a model soap foam consisting of compressible spherical bubbles, whose

153 Many natural structures use a foam core and solid outer shell to achieve high strength

154 ds (PFAAs) derived from aqueous film-forming foams could have adverse impacts on the microbiological

155 Appetite suppression induced by foams could largely be explained by effects on gastric v

156 iable replacement for traditional stochastic foams critically depends on their mechanical performance

157 The increase in foaming and reduction in foam degradation of the proteins highlights their use in

158 A 93% incommensurate graphene foam demonstrated a reversible specific capacity of 1,54

159 A decreased emulsifying capacity, foaming density, and quantity of soluble proteins at pH

160 sive air samplers equipped with polyurethane foam disks to find spatial information in and around Chi

161 This resulted in NFC/PEI foams displaying a sheet structure with porosity above 9

162 commends that clinicians use hydrocolloid or foam dressings in patients with pressure ulcers to reduc

163 was also positively identified in one of the foaming drinking water wells at nanogram-per-liter conce

164 A hierarchical mesoporous carbon foam (ECF) with an interconnected micro-/mesoporous arch

165 ropores (>50 nm) underneath resulting from a foaming effect during release gaseous decomposition prod

166 igh-capacity stretchable graphitic carbon/Si foam electrode is enabled by a conformal self-healing el

167 on (0.186 microM) than NiO nanosheet (NS)-Ni foam electrode pattern, indicating the effectiveness of

168 s study, the ability of a nanocrystalline Bi foam electrode to serve as an efficient and high capacit

169 flame retardant added to building insulation foams, electronics, and textiles.

170 droplet interface, a key process involved in foaming, emulsification, and droplet coarsening.

171 The graphene foam enabled microfluidic flow-through approach will all

172 tions, including the provision of protective foam environments for vulnerable reproductive stages, ev

173 seamlessly grown on the CNTs, and the hybrid foam exhibits excellent EMI shielding effectiveness whic

174 t of the atmospheric impact of the potential foam expansion agent, CF3(CF2)2CH horizontal lineCH2 (HF

175 hat of HCFC-141b (782) and to that of modern foam-expansion blowing agents (148, 882, and 804 for HFC

176 Fe foams fabricated by freeze-casting and sintering were el

177 The composite has a unique film-foam-film hierarchical top-down architecture from the ma

178 categorized as fibers/lines, pellets/beads, foams, films, and fragments.

179 We also examine the activity of our carbon foam for both OER and ORR independently, in a three-elec

180 trials evaluated the efficacy of budesonide foam for induction of remission in 546 patients with mil

181 ead to the use of our polymer-based graphene foams for a variety of novel applications in future such

182 cellular structures allow for fabrication of foams for use in a wide range of fields ranging from bio

183 energy consumption of 62 kWh/kg COD, reduced foam formation due to less gas bubble production, minimu

184 ng capacity (52.2% with 12% of moisture) and foam formation, compared with sample obtained at the sta

185 in arabinose and galactose (PRAG) were poor foam formers but good foam stabilizers.

186 to evaluate the ability of budesonide rectal foam, formulated to optimize retention and provide unifo

187 Monolithic and macroporous graphene foam grown by chemical vapor deposition (CVD) served as

188 On a gravimetric basis, the foams had a similar or greater Pu capacity than the resi

189 The metal foams have a long flat stress-train curve in compression

190 raphene, electrically conductive elastomeric foams have been synthesized by the controlled reassembly

191 The resultant ultralight monolithic metal foams have remarkably low densities down to 7.4 mg/cm3 o

192 The printed and sintered ceramic foam honeycombs possess low relative density ( approxima

193 Biological foams, however, must also resist crack growth.

194 ayered samples consisting of bioactive glass foams (IEIC16), three-dimensional (3D)-printed biodegrad

195 At many aqueous film-forming foam-impacted sites, perfluoroalkyl acids (PFAAs) can al

196 d by annealing a freeze-dried graphene oxide foam in ammonia.

197 ylvania caused inundation of natural gas and foam in initially potable groundwater used by several ho

198 been increasingly used to treat polyurethane foam in residential upholstered furniture.

199 rior long-term performance of the 3D printed foam in terms of two different metrics, i.e., compressio

200 The foam ink contains bubbles stabilized by attractive collo

201 highlights their use in beverages where the foam is an important factor.

202 Herein, an acid-base engineered foam is employed for separation of micro-oil droplets fr

203 raphene edge plane (MLGEP) core-shell hybrid foam is fabricated using chemical vapor deposition.

204 of crack propagation within the struts of a foam is not well understood and is complicated by the fo

205 sis process used to make this elastic carbon foam is readily scalable to industrial applications in e

206 nism eventually leads to the collapse of the foam layer and to the onset of lava fountaining.

207 e possibility to detect the development of a foam layer at depth and to set quantitative constraints

208 due to the pre-fountaining accumulation of a foam layer at shallow levels in the plumbing system of t

209 Gas leakage from the foam layer during the late stages of its accumulation in

210 ance the penetration losses of microwaves in foams, leading to a greatly improved EMI shielding perfo

211 We demonstrate that in cancellous bone, the foam-like component of whole bones, damage propagation d

212 nuous deposition, ultimately assembling into foam-like microstructures with a highly accessible surfa

213 n bilayer monodisperse foams by changing the foam liquid fraction in a physical experiment.

214 ated drinks by measuring separate volumes of foam, liquid, and air layers in the stomach.

215 was less stable in the stomach [less-stable foam (LSF)], and a nonaerated drink [liquid control (LC)

216 In this study, foam mat drying was applied to Tommy Atkins mango.

217 It was found that the loading curves of the foam material are steeper than a similarly scaled resin-

218 equency (35.9%[0.4, 83.9%]) and BDE-209 with foam mattress use (48.9%[5.8, 109.7%]).

219 sumption, higher housekeeping frequency, and foam mattress were associated with prenatal PBDE exposur

220 mingly different soft materials-such as soap foams, mayonnaise, toothpaste and living cells-display s

221 ot well understood and is complicated by the foam microstructure.

222 (Rsn-2) is a surfactant protein found in the foam nests of the tungara frog.

223 ed by 3D Ni2 P nanoparticle arrays on nickel foam (Ni2 P NPA/NF).

224 The resulting polymer-based graphene foams not only effectively transfer the functional prope

225 ation of conductive porous polymers based on foaming of an aqueous dispersion of polymeric particles

226 pproach exhibit higher strength than ceramic foams of similar density.

227 e tested the hypothesis that aerated drinks (foams) of differing gastric stability would increase gas

228 n homogeneously auxetic materials are porous foams or artificial macrostructures and there are few ex

229 collected as in/out pairs using polyurethane foam passive air samplers (PUF-PAS) from January 2012 to

230 imilar compounds captured using polyurethane foam passive air samplers (PUF-PAS).

231 The passive methods included polyurethane foam passive air samplers deployed outdoors and indoors

232 ystems to treat gaseous emissions from sheet-foam production.

233 ource recovery from (and treatment of) sheet-foam-production exhaust gas.

234 stability of either protein, but it impaired foaming properties of both.

235 ed, demonstrating the poorest solubility and foaming properties of the latter.

236 ution of the different wine compounds to the foaming properties of white and rose sparkling wines.

237 jor result to correlate with the surface and foaming properties of wine, the solubility, allergenicit

238 increasing conjugation time and improved the foaming properties of WPI and WPH.

239 o acid composition, solubility, emulsion and foaming properties were evaluated.

240 As a result, the colloidal stability and foaming properties were improved.

241 der to improve their colloidal stability and foaming properties.

242 e of FRs in products containing polyurethane foam (PUF), we established a screening service for the g

243 sparkling wines is directly related to their foam quality, but the compounds responsible are not yet

244 ictated by energy minimization, we study the foam's dynamics as it corresponds to downhill motion on

245 substrates with those formed on 3D graphene foam scaffolds.

246 was completed with either ultrasound-guided foam sclerotherapy or local anesthetic phlebectomy.

247 g ulcers and receiving microsclerotherapy or foam sclerotherapy treatments, being unwilling to enter

248 drink that was stable in the stomach [stable foam (SF)], and one drink that was less stable in the st

249 ing activity index (from 5.9 to 52.5m(2)/g), foam stability (from 68.2 to 82.8%), and oil holding cap

250 reached by foam after CO2 injection) and HS (foam stability height during CO2 injection), and the neg

251 Foaming capacity and foam stability of CPI were found to increase with increa

252 The model to explain foam stability was only predicted by polysaccharides fro

253 The maximum foamability and foam stability were observed for acid whey when compared

254 city as well as the foaming capacity and the foam stability were shown to be greatly affected by pH.

255 index, swelling index, foaming capacity and foam stability.

256 d emptying, which may be further enhanced by foam stability.

257 (L) and carboxymethylcellulose (CMC) used as foam stabilizers (0-1.50g/100g), as well as temperature

258 ctose (PRAG) were poor foam formers but good foam stabilizers.

259 ted NiO nanostrands (NSTs) onto 3D porous Ni foam substrate for monitoring, as well as selective and

260 of radially oriented NSTs onto 3D porous Ni foam substrate.

261 3 -blended NiO layer synthesized on metallic foam substrates.

262 lyzing the interfacial energy of two bilayer foam systems with varying liquid fractions.

263 hosphate on self-supported conductive nickel foam that is commercially available in large scale.

264 mer cocktail that yielded poly(HEMA-co-AEMA) foam that was prepared in-situ by UV crosslinking and by

265 study, we report the polymer-based graphene foams through combination of bottom-up assembly and simp

266 This graphene foam/TiO2 nanosheet hybrid was synthesized via a facile

267 g the very facile synthesis of this graphene foam/TiO2 nanosheet hybrid, and its excellent water trea

268 Herein, we designed a graphene foam/TiO2 nanosheet hybrid, which is able to effectively

269 micals have often been added to polyurethane foam to meet required state and federal flammability sta

270 d electronic control of molybdenum disulfide foam to synergistically promote the hydrogen evolution p

271 ilable polymeric embolics range from gelatin foam to synthetic polymers such as poly(vinyl alcohol).

272 Second, we used F-one association mapping (FOAM) to map the genes that control flowering time, acro

273 ucts dominating PBDE usage were polyurethane foam used in furniture (65% of pentaBDE), casings of ele

274 ophosphate compounds applied to polyurethane foam used in furniture and baby products.

275 phorization of commercially available nickel foam using phosphorus vapor.

276 ated in bursting films within aqueous bubble foams using both laboratory buffer and ocean water.

277 anding, we imaged the microstructure of both foams using X-ray computed tomography, and performed fin

278 A 3D graphitic foam vertically aligned graphitic structure and a low de

279 lubility and hence gelation, emulsification, foaming, viscosity and water-holding capacity, which all

280 in the total gastric content (P < 0.05) and foam volume (P < 0.0001) and a longer TTRTB (197 compare

281 The droplet adsorption onto the foam was governed by physisorption, and the driving forc

282 The foam was regenerated and reused multiple times by simple

283 The density and temperature of the ionized foam was retrieved by using x-ray radiography and proton

284 he long-term performance of the two types of foams we employed multi-year-long accelerated aging stud

285 he physicochemical surface properties of the foam were characterized using X-ray photoelectron spectr

286 ased column, and the elution profiles of the foams were narrower than the resin, generating more conc

287 , where PFAS-containing aqueous film-forming foams were used historically.

288 ube filled with an ultra low-density plastic foam where it was heated by x-rays, produced by a long p

289 es a template for the formation of composite foams, whose swelling behavior is sensitive to the compo

290 A 3D N-doped graphene foam with a 6.8 at% nitrogen content is prepared by anne

291 e densification strain epsilonD of the Ni/Ag foam with a porosity of 99.8% can reach 82%.

292 Graphene foam with highly enriched incommensurately-stacked layer

293 s a wider stress variation in the stochastic foam with points of more extreme local stress as compare

294 mized three-dimensional molybdenum disulfide foam with uniform mesopores, vertically aligned two-dime

295 e fabricate ultra-thin, porous PMMA films by foaming with CO2 saturation.

296 ered structures for bilayer monodisperse wet foams with arbitrary liquid fraction.

297 167-545 mum), are obtained using the Ti2AlC foams with different pore structures as preforms for mol

298 ic-graphene composites by combining graphene foams with pre-ceramic polymers and spark plasma sinteri

299 exagonal and triangular honeycombs by direct foam writing.

300 Sintering this bi-constituent foam yields solid closed-cell porous structure which can