ライフサイエンスコーパス: iron oxide

1 ic matter was stabilized by association with iron oxide.

2 anoparticles made of polystyrene, silica, or iron oxide.

3 Fe-O bond both in crystalline and amorphous iron oxide.

4 and mineralize iron to produce mixed-valent iron oxides.

5 to sulfide oxidation by molecular oxygen or iron oxides.

6 through the reduction of large quantities of iron oxides.

7 while Cu and Zn are strongly associated with iron oxides.

8 long-lasting storage facility for As(5+) by iron oxides.

9 FeCO3 partially dissociates to form various iron oxides.

10 s on the same order of magnitude as those of iron oxides.

11 ng the microbial reductive transformation of iron oxides.

12 live (60)Fe atoms contained within secondary iron oxides, among which are magnetofossils, the fossili

13 column filled with silica beads coated with iron oxide and flooded initially with an acidic solution

14 tite (alpha-Fe2O3) is one of the most common iron oxides and a sink for the toxic metalloid arsenic.

15 r-infrared (vis-NIR) spectrometer to measure iron oxides and clay mineralogy.

16 Abundant iron oxides and high dissolved ferrous iron indicate iro

17 Two other components of the Martian surface, iron oxides and hydrogen peroxide, act in synergy with i

18 predominantly co-located with aluminium and iron oxides and hydroxides, which are known to strongly

19 ire extracellular electron acceptors such as iron oxides and uranium and to wire electroactive biofil

20 irreducible supports as on reducible ceria, iron oxide, and titania supports, apparently all sharing

21 a higher affinity of TcO(4)(-) for FeS than iron oxides, and electron microscopy confirmed that the

22 ceramic nanopowders (titania, two different iron oxides, and iron oxide nanocrystallites embedded in

23 , typical of coprecipitation of uranium with iron oxides, and uranium-sulfur distances indicating bid

24 Iron oxides are important structural and biogeochemical

25 Iron oxides are ubiquitous in soils and sediments and pl

26 However, little is known about the role of iron oxides as an oxidant for AOM.

27 synthesized an exendin-4 conjugated magnetic iron oxide-based nanoparticle probe targeting glucagon-l

28 eria generates a large buffer of sedimentary iron oxides before the onset of summer hypoxia, which ca

29 ble the sharing of electrons in mixed-valent iron oxides between bacteria with different metabolisms.

30 manganese oxides results in a large stock of iron-oxide-bound phosphorus below the oxic zone.

31 search should elucidate whether formation of iron-oxide-bound phosphorus driven by cable bacteria, as

32 ynthesis of amorphous and crystalline cobalt iron oxides by controlling the crystallinity of the mate

33 The use of manganese and iron oxides by late Neandertals is well documented in Eu

34 In these environments iron oxides can become main agents for AOM, but the unde

35 commonly precipitate during bioreduction of iron oxides, captured arsenic species.

36 emediation but also for the doping design of iron oxide catalysts.

37 The r2 values of iron oxide clusters and Landau-Lifshitz-Gilbert simulati

38 errous iron (Fe(II)) on the ability of aged (iron oxide coated) Fe(0) to degrade trichloroethylene (T

39 In this study, aged (iron oxide coated) Fe(0) was applied to the degradation

40 iltration systems containing quartz sand and iron oxide-coated quartz sand (IOCS) to remove two FIB (

41 i zoospores in saturated columns packed with iron-oxide-coated sand (IOCS) or uncoated sand in Na(+)

42 nteractions, mineral surface modification by iron oxide coating, and pollutant transport.

43 roton release during adsorption of Fe(II) to iron oxide coatings was identified as being responsible

44 nge in total metallic iron concentration and iron oxide concentration for the experimental duration o

45 ese results suggest that naturally occurring iron oxides containing insoluble elements are less susce

46 drophilic conditions, as well as protect the iron oxide core from degradation.

47 lenide-based core-shell quantum dots to gold-iron oxide core-shell nanocrystals compared to random mi

48 redox chemistry is demonstrated in gold@iron/iron oxide core-shell nanoparticles with ambient oxidati

49 e show that dextran-coated superparamagnetic iron oxide core-shell nanoworms incubated in human serum

50 (MNPs-oSUD) consisted of a concatenation of iron oxide cores, with an average size of 7.7 nm, bound

51 wed that reactions between hydroquinones and iron oxides could produce favorable conditions for forma

52 been linked to the reductive dissolution of iron oxides coupled to the microbial respiration of orga

53 states, spin states and phase stabilities of iron oxides, creating new stoichiometries, such as Fe4O5

54 ation of organic matter coupled to reductive iron oxide dissolution is widely recognized as the domin

55 These results highlight a role for natural iron oxides during bacterial sulfate reduction in methan

56 by about 50%, indicating the involvement of iron oxides during sulfate reduction in methane seeps.

57 on irradiation, iron hydroxide transforms to iron oxide, during which bubbles are generated, and they

58 Magnetite (Fe3O4) is a widespread magnetic iron oxide encountered in many biological and geological

59 ect inner-sphere complexation between OC and iron oxides (Fe-O-C) is responsible for transferring a l

60 embrane integrity of bacteria attached to an iron oxide (Fe2O3) surface was measured over a range of

61 voltammetry of solution-dispersed magnetite iron oxide Fe3O4 nanoparticles is described.

62 we demonstrate that Fe in APC is present as iron oxide (Fe3O4) magnetite nanoparticles.

63 Iron oxide (Fe3O4) nanocrystals generated in situ from a

64 A new enzyme-free sensor based on iron oxide (Fe3O4) nanodots fabricated on an indium tin

65 ogical toxicity of nanoparticles (NPs) using iron oxide (Fe3O4) NPs as models.

66 Gold (Au)-decorated iron oxide (Fe3O4), Au/Fe3O4, Janus nanoparticles were f

67 tems are discussed: titanium dioxide (TiO2), iron oxides (Fe3O4), and, as an example for a post-trans

68 y systemically delivered magnetically guided iron oxide (FeO) nanoparticles during radiofrequency app

69 identify a highly stable, pyrite-structured iron oxide (FeO2) at 76 gigapascals and 1,800 kelvin tha

70 Colloidal iron oxides (FeOx) are increasingly released to the envi

71 ands form on the bare film, the hydroxylated iron oxide film acts as a hydrophilic nanotemplate, caus

72 ductive and protective nature of the optimal iron oxide film led to a high capacity retention (~93% a

73 ynergetic effect of electrochemically active iron oxide films coating and partial doping of iron on L

74 Owing to the conductive nature of iron oxide films, with an optimal film thickness of ~0.6

75 he promising potentialities of mixed valence iron oxides for the treatment of soils and wastewater co

76 nslational potential, we leverage a clinical iron oxide formulation, altered with minimal modificatio

77 oil by providing reactive organic matter and iron oxide fractions.

78 FIB-SEM revealed that iron oxide grains left undetected by conventional SEM co

79 ctive magnetic actuation, while both PVP and iron oxide have low toxicity.

80 In this context, titanium dioxide (TiO2) and iron oxide (hematite, alpha-Fe2O3) are among the most in

81 circumneutral pH values, goethite, amorphous iron oxide, hematite, iron-coated sand, and montmorillon

82 if solutions containing two commonly studied iron oxides-hematite and goethite-and aqueous Fe2+ reach

83 A novel T1 agent, antiferromagnetic alpha-iron oxide-hydroxide (alpha-FeOOH) nanocolloids with a d

84 associated with the in situ generated nickel-iron oxide/hydroxide and iron oxyhydroxide catalysts at

85 Nickel-iron oxides/hydroxides are among the most active electro

86 f most likely small fragments of iron and/or iron oxide in the void of the hollow NPs.

87 ed that As was predominantly associated with iron oxides in periphyton.

88 e Ridge, we provide insight into the role of iron oxides in sulfate-driven AOM.

89 to chemistry reported for the dissolution of iron oxides in sulfidic waters and during bioleaching of

90 ining lymph node (LN), it was shown that the iron oxide-induced decrease in LN magnetic resonance (MR

91 ted to provide insights into "redox mediator-iron oxide" interaction in the presence of DIRB.

92 tered NOM, converting approximately 6 muM of iron oxides into settable forms that removed between 0.5

93 This study explored the novel use of iron oxide (IO) nanoparticles (<20 nm) as a vaccine deli

94 of toxic trace elements via adsorption onto iron oxides is an inexpensive and robust treatment metho

95 Bioreduction of As(V) and As-bearing iron oxides is considered to be one of the key processes

96 ctable, the phosphorus associated with these iron oxides is released, strongly increasing phosphorus

97 Additionally, we observe that small iron oxide islands on the Pt surface of the Pt-Fe3O4 see

98 Next, iron oxide-labeled allogeneic islets were transplanted i

99 In the proof-of-principle studies, iron oxide-labeled autologous pancreatic islets were tra

100 g with the preferential removal of (65)Cu by iron oxides, left seawater and marine biomass depleted i

101 Here, we use iron oxide-loaded ferritin proteins to create a stable a

102 ata could be explained by the presence of an iron oxide lowering EH values of aqueous Fe3+/Fe2+ redox

103 y of positively charged surfactant supported iron oxide magnetic nanoparticles (Mag-NPs), is reported

104 Monodisperse iron oxide magnetic nanoparticles assemble along the M13

105 nd ultrasmall superparamagnetic particles of iron oxide magnetic resonance imaging are 2 novel approa

106 sensing platform based on fractal-pattern of iron oxides magnetic nanostructures (FIOMNs) and mixed h

107 It argues that intracellular crystals of the iron oxide magnetite (Fe3O4) are coupled to mechanosensi

108 ound level of control over particle size and iron oxide (magnetite) homogeneity in chemical precipita

109 The AFM coupling in iron oxide-manganese oxide based, soft/hard and hard/sof

110 omologous proteins produce imprecise various iron oxide materials, which is a striking difference for

111 Our findings suggest that mixed-valence iron oxides may play a significant role in oxygen cyclin

112 The iron oxide mineral magnetite (Fe3O4) is produced by vari

113 ction and contained mostly Fe, suggesting an iron oxide mineral such as magnetite (Fe3O4).

114 potentially alter how metals associate with iron oxide minerals through a series of cooperative or c

115 to "shuttle" electrons between microbes and iron oxide minerals.

116 Arsenic is released from sediments when iron-oxide minerals, onto which arsenic is adsorbed or i

117 e binary assembly of cobalt chalcogenide and iron oxide molecular clusters are reported.

118 monolayer of [SiO4] tetrahedra on top of an iron oxide monolayer.

119 Ligand-conjugated microparticles of iron oxide (MPIO) have the potential to provide high sen

120 contrast agent [anti-VCAM-microparticles of iron oxide (MPIO)] to identify conventionally undetectab

121 ntrast agent consisting of microparticles of iron oxide (MPIOs) conjugated to a single-chain antibody

122 ers (titania, two different iron oxides, and iron oxide nanocrystallites embedded in a closed silica

123 Using cyanine 5.5-superparamagnetic iron oxide nanoparticle (Cy5.5-SPION) labeling and fluor

124 7-T MR unit before and after monocrystalline iron oxide nanoparticle (MION) injection.

125 This matrix contains an iron oxide nanoparticle (NP) core with gluthathione (GSH

126 ta-cyclodextrin-conjugated superparamagnetic iron oxide nanoparticle and polymerized paclitaxel allow

127 geting based on various polymer and magnetic iron oxide nanoparticle carriers with drug attached by b

128 les with a model eicosane- superparamagnetic iron oxide nanoparticle composite coating, which is acti

129 The investigated particles consist of iron oxide nanoparticle cores (9 nm) embedded in poly(st

130 ng the Food and Drug Administration-approved iron oxide nanoparticle ferumoxytol.

131 Advanced molecular imaging, such as iron oxide nanoparticle imaging, can allow direct imagin

132 ample with arsenic exclusively sorbed on the iron oxide nanoparticle surface.

133 lly developed by utilizing superparamagnetic iron oxide nanoparticle, beta-cyclodextrin, and polymeri

134 MRI of pretransplantation superparamagnetic iron oxide nanoparticle-labeled islet grafts allows time

135 To that end, we present an iron oxide nanoparticle/wax composite capsule coating us

136 nium salts were electrochemically grafted on iron-oxide-nanoparticle-decorated SWCNTs to functionaliz

137 abbits received ultrasmall superparamagnetic iron oxide nanoparticles (CLIO) derivatized with a near-

138 and choline oxidase (ChO), on the surface of iron oxide nanoparticles (Fe2O3NPs), poly(3,4-ethylenedi

139 (GO-CNT), Graphene oxide nanosheets (GO) and Iron oxide nanoparticles (Fe3O4).

140 Here we demonstrate that clinically approved iron oxide nanoparticles (Ferumoxytol) can be utilized t

141 We synthesized ICAM-1 antibody-conjugated iron oxide nanoparticles (ICAM-IONPs) as a magnetic reso

142 noleic acid hydroperoxide (LAHP) tethered on iron oxide nanoparticles (IO NPs) and the released iron(

143 edicine is an urgent need, superparamagnetic iron oxide nanoparticles (IONPs) could be used as contra

144 f effective polypeptide ligands for magnetic iron oxide nanoparticles (IONPs) could considerably acce

145 Iron oxide nanoparticles (IONPs) have been extensively u

146 Engineered, superparamagnetic, iron oxide nanoparticles (IONPs) have significant potent

147 icially aged, oleic acid (OA) bilayer coated iron oxide nanoparticles (IONPs) under different scenari

148 rization of electrode surface indicated that iron oxide nanoparticles (IONPs) were generated in situ

149 In this study, two sets of iron oxide nanoparticles (IONPs) were synthesized that w

150 Iron oxide nanoparticles (IONPs, sometimes called superp

151 sodium dodecyl sulfate (SDS)-coated magnetic iron oxide nanoparticles (MHAMS-MIONPs) were used as an

152 cylenate (oSUD) were chemisorbed to magnetic iron oxide nanoparticles (MNPs) through a single-step sy

153 iron complexes with concomitant formation of iron oxide nanoparticles (NPs) that were responsible for

154 ntration (CCC) for oleic acid bilayer coated iron oxide nanoparticles (OA-IONPs) were determined to b

155 MR contrast, superparamagnetic iron oxide nanoparticles (SPIO) were packed into the cor

156 Design and structure of superparamagnetic iron oxide nanoparticles (SPION) and condensed magnetic

157 elanoma cells labeled with superparamagnetic iron oxide nanoparticles (SPION) were injected into the

158 with NeutrAvidin-activated superparamagnetic iron oxide nanoparticles (SPION).

159 melanoma exosomes with 5nm superparamagnetic iron oxide nanoparticles (SPION5) while maintaining orig

160 Superparamagnetic iron oxide nanoparticles (SPIONs) as a contrast agent ha

161 Superparamagnetic iron oxide nanoparticles (SPIONs) have mainly been used

162 s stem cell labelling with superparamagnetic iron oxide nanoparticles (SPIONs) prior to transplantati

163 Nanovaccines based on superparamagnetic iron oxide nanoparticles (SPIONs) provide a novel approa

164 e modified and tagged with superparamagnetic iron oxide nanoparticles (SPIONs), gold, or fluorescein

165 ver nanoparticles (AgNPs), superparamagnetic iron oxide nanoparticles (SPIONs), VNIR dye Nile Blue (N

166 protein (HDL) labeled with superparamagnetic iron oxide nanoparticles (SPIOs) and quantum dots was ab

167 Although superparamagnetic iron oxide nanoparticles (SPIOs) are recognized as a pro

168 dipose tissue triggered by injection of P904 iron oxide nanoparticles (USPIO).

169 n-coated exceedingly small superparamagnetic iron oxide nanoparticles (ZES-SPIONs) consisting of appr

170 ly label macrophages with super-paramagnetic iron oxide nanoparticles and apply pulsed magnetic field

171 gous pancreatic islets could be labeled with iron oxide nanoparticles and monitored after transplanta

172 Iron oxide nanoparticles are detected in vivo as hypoint

173 The iron oxide nanoparticles are generated in a colloidal fo

174 sh one tracer from another, and paramagnetic iron oxide nanoparticles are included in the tracer to f

175 owever, conventional liquid marbles based on iron oxide nanoparticles are opaque and inadequate for p

176 Iron oxide nanoparticles are synthesized intracellularly

177 ally germanium-69-labeled super-paramagnetic iron oxide nanoparticles are synthesized via a newly dev

178 eptor was transfected with superparamagnetic iron oxide nanoparticles before intravenous injection, b

179 lt and zinc ions, these results suggest that iron oxide nanoparticles can be doped to sufficiently ta

180 These magnetoluminescent agents consist of iron oxide nanoparticles conjugated with metallointercal

181 hMSC labeling with iron oxide nanoparticles enables non-invasive in vivo mo

182 d MRI and fluorescently labeled cross-linked iron oxide nanoparticles for cell tracking.

183 perties of two responsive magnetoluminescent iron oxide nanoparticles for dual detection of DNA by MR

184 nanotubes (PNT) could be functionalized with iron oxide nanoparticles for magnetic manipulation, with

185 Iron oxide nanoparticles grafted with small organic mole

186 proved iron supplement ferumoxytol and other iron oxide nanoparticles have been used for treating iro

187 offers 10 important insights for the use of iron oxide nanoparticles in clinical MR imaging.

188 sensitive determination of silver, gold, and iron oxide nanoparticles in environmental samples.

189 Clusterized superparamagnetic iron oxide nanoparticles in the nano-assembly permitted

190 cost hydrophilic polyvinylpyrrolidone-coated iron oxide nanoparticles is reported for the first time.

191 t ligand-targeted MPIO derived from multiple iron oxide nanoparticles may be coupled covalently throu

192 s (IONPs, sometimes called superparamagnetic iron oxide nanoparticles or SPIONs) have already shown p

193 nsitive channel, TRPV1, with antibody-coated iron oxide nanoparticles that are heated in a low-freque

194 With electron microscopy, iron oxide nanoparticles were localized in secondary lys

195 lial adherens junctions through internalized iron oxide nanoparticles, activating the paracellular tr

196 ed through reactions with Fe(II) adsorbed on iron oxide nanoparticles, although little is known about

197 However, except for iron oxide nanoparticles, diagnostic nanoparticles have

198 Iron oxide nanoparticles, extensively used for MRI of pr

199 polymeric particles using super paramagnetic iron oxide nanoparticles, specifically by measuring spin

200 possible to obtain accurate DOSY spectra on iron oxide nanoparticles.

201 second approach, SWCNTs were decorated with iron oxide nanoparticles.

202 nd using microbubbles, and superparamagnetic iron oxide nanoparticles.

203 ed pretransplantation with superparamagnetic iron oxide nanoparticles.

204 ilic lysine derivative and superparamagnetic iron oxide nanoparticles.

205 yl acrylamide) copolymer networks containing iron oxide nanoparticles.

206 sing thin, long nanotubes coated inside with iron oxide nanoparticles.

207 ro-apoptotic peptide [D(KLAKLAK)2] coated on iron oxide nanoparticles.

208 metallointercalators are not affected by the iron oxide nanoparticles; upon binding to DNA the lumine

209 In this study, iron-oxide nanoparticles (fAb-IONs) were used as magneti

210 antibody (pAb), and pAb functionalized with iron-oxide nanoparticles (FpAb) assays were detected usi

211 A novel application using iron-oxide nanoparticles (IONPs) and a photonic crystal

212 Superparamagnetic iron-oxide nanoparticles can be used in medical applicat

213 ormula: see text]m-long microrods containing iron-oxide nanoparticles connected by a polymer mesh.

214 cting approximately 100ng of carboxyl-coated iron-oxide nanoparticles in under a second.

215 The particles also encapsulated iron-oxide nanoparticles permitting magnetic resonance i

216 an penetrate brain tumors, composed of three iron oxide nanospheres and one drug-loaded liposome link

217 Highly-ordered and conformal iron oxide nanotube arrays on an atomic scale are succes

218 Iron oxide nanoworms (NWs) functionalized with the linTT

219 (CMC)-stabilized nZVI, bare nZVI, nanoscale iron oxide (nFe(3)O(4)) or ferrous ion [Fe(II)(aq)] at m

220 Nanoparticulate iron oxide (npOx), commonly detected in Martian regolith

221 agnitude smaller than any current ultrasmall iron oxide NPs (>5 emu g(-1)) reported to date, hence en

222 The proteins bound to the superparamagnetic iron oxide NPs (SPION) present in an IgG/albumin deplete

223 ptake and translocation of superparamagnetic iron oxide NPs (SPIONs), with various surface charges, o

224 re, interfacial assemblies of fullerene with iron oxide NPs resulted in short-range periodic structur

225 n oxide NPs, but not zerovalent iron NPs nor iron oxide NPs that were surrounded by a protein corona,

226 0 fullerene with naturally abundant magnetic iron oxide NPs will affect their fate and transformation

227 e further elevated by artificially involving iron oxide NPs with heterogeneous geometries in terms of

228 ation dynamics and we have demonstrated that iron oxide NPs, but not zerovalent iron NPs nor iron oxi

229 lution, fullerene association to aggregating iron oxide NPs/clusters greatly enhanced the overall col

230 oved magnetism arises in part from increased iron oxide nucleation efficiency.

231 etrital basaltic minerals, calcium sulfates, iron oxide or hydroxides, iron sulfides, amorphous mater

232 onanoparticles (GNPs) are sugar-coated gold, iron oxide or semiconductor nanoparticles with defined t

233 plasmonic gold or silver, superparamagnetic iron oxide, or fluorescent quantum dot NPs after they ha

234 -sided approach which uses superparamagnetic iron oxide particles (SPION) in combination with fructos

235 ole body imaging, which respectively tracked iron oxide particles and indocyanine green (ICG) encapsu

236 where algae procure iron via dissolution of iron oxide particles as a result of either reaction with

237 The obtained iron oxide particles catalyze soot oxidation in filters.

238 The exudate also affects the reactivity of iron oxide particles formed with exudate coated particle

239 RI with in vivo ultrasmall superparamagnetic iron oxide particles labeling.

240 g intravascular ultrasmall superparamagnetic iron oxide particles to quantify and evaluate tumor frac

241 be explained by deposition of semiconducting iron oxide particles within LSLs.

242 on-weighted MR imaging, MR lymphography with iron oxide particles, and targeted positron emission tom

243 cles undergoing faster dissolution than bare iron oxide particles.

244 ANPs and released P from HANPs interact with iron oxides, particularly naturally occurring goethite n

245 have explored the reactivity of either pure iron oxide phases or those containing small quantities o

246 al membrane caused by the oscillation of the iron oxide portion of the nanochain.

247 tistep swelling polymerization combined with iron oxide precipitation afford carboxyl functional grou

248 ainable subsurface life, a Martian site with iron oxide precipitation bands, if one were found, may o

249 Widespread iron oxide precipitation from groundwater in fine-graine

250 Notably, the amorphous cobalt iron oxide produces superior catalytic activity over the

251 Iron oxide provides effective magnetic actuation, while

252 luding titania, nickel oxide, silver, ceria, iron oxide, quantum dots, and C60-fullerene, in a labora

253 , MER can also be used to capture changes in iron oxide reducibility during phase transformations, as

254 se is thought to be controlled by changes in iron oxide reduction driven by variations in external en

255 Beyond allowing to study iron oxide reduction under defined thermodynamic conditi

256 y is capable of linking methane oxidation to iron oxide reduction.

257 ke of Fe(II) by Cu-, Co-, and Mn-substituted iron oxides relative to analogues containing only redox-

258 ne during aging because of adsorption to the iron oxide-rich ash; this is aided by As(III) oxidation.

259 toxicological relevance, that is, minerals, iron oxides, sea salts, ammonium salts, and carbonaceous

260 ons are observed in BiFeO3 based thin films, iron oxide second phases are often detected.

261 ility that organic molecules get through the iron oxide shell during synthesis.

262 The iron oxide shell seems to be non-porous and impenetrable

263 enhanced gold SPR can drive reduction of the iron oxide shell under broadband illumination to reversi

264 nonequilibrium formation of millimeter-scale iron oxide-silica tubes in experiments that tightly cont

265 successfully applied to the determination of iron oxide, silver, and gold nanoparticles in environmen

266 capacity (0.536 mg(As)/mg(Fe)) of unreacted iron oxide solids.

267 h doxorubicin (DOX)-loaded superparamagnetic iron oxide (SPIO) nanoparticles (SPIO-DOX), in a VX2 rab

268 could be encapsulated with superparamagnetic iron oxide (SPIO) nanoparticles and visualized by MRI in

269 ryl chitosan (FA-CLC), and superparamagnetic iron oxide (SPIO) nanoparticles were used for preparing

270 Specifically, superparamagnetic iron oxide (SPIO) nanoparticles with different targeting

271 r than those of a standard superparamagnetic iron oxide (SPIO) widely used in biomedical applications

272 Cellular MRI combined with superparamagnetic iron-oxide (SPIO) contrast agents is an effective cell-t

273 Recent work has shown that iron oxides, such as goethite and hematite, may recrysta

274 me by progressive oxidation to less magnetic iron oxides, such as maghemite (gamma-Fe2O3), with conse

275 Iron oxide surface patches on latex microspheres were se

276 dies have observed that Fe2+ associated with iron oxide surfaces (i.e., oxide-associated Fe2+) often

277 of the binding of an important antibiotic at iron oxide surfaces, and therefore provided additional c

278 resent the synthesis and characterization of iron oxides surrounded by nitrogen-doped-graphene shells

279 aging using antibody-based microparticles of iron oxide targeting P-selectin.

280 he formation, aggregation, and reactivity of iron oxides that are formed on addition of Fe(II) and Fe

281 (13)C-labeled methane and naturally abundant iron oxides the process was evidenced by significant (13

282 nt and quantify the reductive dissolution of iron oxides, the concomitant release of sorbed arsenic,

283 fter target preparation using mixed titanium/iron oxides, the final sample was measured by compact ac

284 licon photoanode with a catalytically active iron oxide thin film (see picture).

285 dy of water clustering on a moire-structured iron oxide thin film with a controlled density of hydrox

286 The iron shell can be oxidized to iron oxide through ambient oxidation, leading to an enha

287 factors (e.g., dexamethasone, rhodamine and iron oxide) to the cell's microenvironment.

288 irectly detects the intense magnetization of iron-oxide tracers using low-frequency magnetic fields.

289 cal process may have led to the formation of iron oxides under anoxic conditions.

290 Third, iron oxide undergoes spontaneous reduction on contact wi

291 Ultrasmall superparamagnetic particles of iron oxide (USPIO) detect cellular inflammation on magne

292 ent C3-targeted ultrasmall superparamagnetic iron oxide (USPIO) nanoparticles bind within the inflame

293 ed bifunctional ultrasmall superparamagnetic iron oxide (USPIO) nanoparticles, chemically coupled wit

294 reas MRI using ultra-small superparamagnetic iron oxide (USPIO) particles provided noninvasive inform

295 by UV radiation to produce hydrogen gas and iron oxides via a two-photon reaction.

296 Iron oxide was suggested as an important mineral preserv

297 IR spectroscopic sorption experiments at the iron oxide-water interface evidenced the formation of a

298 The core of the MNPs is made of iron oxide, whereas the surface of the core is coated wi

299 The ALD deposition of iron oxide with well-controlled phase and tunable magnet

300 nances optically excited in a broad class of iron oxides with a canted spin configuration.