ライフサイエンスコーパス: nanomaterial

1 stic effect of graphene and AuNPs (2D and 0D nanomaterials).

2 ctrical properties and stability of prepared nanomaterial.

3 ch graphene is without any doubt a forefront nanomaterial.

4 emely versatile and polyedric aspect of this nanomaterial.

5 nanothreads, a one-dimensional sp(3) carbon nanomaterial.

6 s, and the emerging benefits of inclusion of nanomaterials.

7 near-infrared light-responsive upconversion nanomaterials.

8 reduce the immunogenicity of a wide range of nanomaterials.

9 oxidizing agents for combustion of reactive nanomaterials.

10 optical lithography of functional inorganic nanomaterials.

11 'free-standing' information about supported nanomaterials.

12 urface plasmon-polariton waves on conducting nanomaterials.

13 nar micro-supercapacitors electrodes made of nanomaterials.

14 entally friendly process for creating silica nanomaterials.

15 context of increasingly complex chiral meta/nanomaterials.

16 but cannot fully explain the in vivo fate of nanomaterials.

17 es are compared with those of graphene-based nanomaterials.

18 rbon in the environmental fate of engineered nanomaterials.

19 nge of applications in synthetic biology and nanomaterials.

20 and the associated surface stress changes of nanomaterials.

21 predictive models for environmental risks of nanomaterials.

22 ical biomarkers based on different hybrid 2D-nanomaterials.

23 candidates for the tailoring of fluorescent nanomaterials.

24 s of better and more fibrous materials of 2D nanomaterials.

25 fabricate environmentally benign functional nanomaterials.

26 omplex, optically diverse nucleobase-derived nanomaterials.

27 ting potential therapeutic uses of catalytic nanomaterials.

28 gineering of multilayer and core-shell oxide nanomaterials.

29 ution NMR methods to the characterization of nanomaterials.

30 rs using functional nucleic acids (FNAs) and nanomaterials.

31 se based biosensor devices using metal oxide nanomaterials.

32 or the atomic-level manipulation of metallic nanomaterials.

33 scinating properties of two-dimensional (2D)-nanomaterials, 2D-based nanohybrids have shown unparalle

34 e first report of a fully solution-processed nanomaterial achieving performance equivalent to its bul

35 Aniline-based copolymer, modified with the nanomaterials, allowed to enhance the electrode conducti

36 chia coli was investigated with standard and nanomaterial amplified immunoassays in the concentration

37 ptical and catalytic functions of the hybrid nanomaterial and determine that the flow of energy is st

38 Current nanomaterial and dispersant remediation methods neglect

39 immunosensors, technology of transducers and nanomaterials and a general overview of the possible app

40 Introduction of novel functional nanomaterials and analytical technologies signify a fore

41 ay that is free of optical interference from nanomaterials and can be performed in a high-throughput

42 Examining interactions between nanomaterials and cell membranes can expose underlying m

43 fore, the combination of 2D transition metal nanomaterials and nucleic acids brings intriguing opport

44 CHs) through the incorporation of conductive nanomaterials and polymers exhibit major technical limit

45 HIV capsid and protein-based two-dimensional nanomaterials and the design of anti-HIV drugs targeting

46 To investigate the presence of these nanomaterials and the impacts they might have, a compara

47 nt efforts in the design of graphene-like 2D nanomaterials and their derived biointerfaces and exploi

48 nges from bio-inspired molecular design over nanomaterials and thin films to solid materials tuning.

49 ess on par with the highest-performing known nanomaterials, and a phase transition between stable 1D

50 ence for preparing alloys or series of doped nanomaterials, and its continuous operation mode, suitab

51 ike reactivity of different manganese oxides nanomaterials, and provide a basis for future design and

52 al form to express the in-plane merits of 2D nanomaterials, and the formation of liquid crystals (LCs

53 proteins, encapsulation and concentration of nanomaterials, and the study of lipid membrane remodelin

54 peptide was exposed to low concentrations of nanomaterials, and we further show that the nanomaterial

55 Recent advances in nanomaterials are becoming pivotal to generate the high-

56 Layered double hydroxide (LDH)-based nanomaterials are considered as promising electrocatalys

57 Engineered nanomaterials are directly applied to the agricultural s

58 sed on the combination of different FNAs and nanomaterials are discussed.

59 ucture and properties of 2D transition metal nanomaterials are first discussed, emphasizing the inter

60 ges of low toxicity and photostability, such nanomaterials are inhomogeneous and have limited wavelen

61 Indeed, for several imaging modalities, nanomaterials are now not simply ancillary contrast enti

62 Nanomaterials are playing major roles in imaging by deli

63 2D black phosphorus (BP) nanomaterials are presented as a delivery platform.

64 We believe that the supported Au-Pd-xCoO nanomaterials are promising catalysts in practical appli

65 Transition metal oxide nanomaterials are promising electrodes for alkali-ion ba

66 nt biosensing structures created from hybrid nanomaterials are reviewed, with a distinct emphasis on

67 Carbon nanomaterials are robust and possess fascinating propert

68 Two-dimensional colloidal nanomaterials are running into renaissance after the enl

69 based on membrane-permeabilizing agents and nanomaterials as drug carriers.

70 s and future directions for the use of these nanomaterials as novel platforms for the development of

71 In an era of graphene-based nanomaterials as the most widely studied two-dimensional

72 ) and titanium dioxide (TiO2) as photoactive nanomaterials, ascorbic acid (AA) as electron donor and

73 method for the synthesis and transfer of 2D nanomaterials at the scale demanded for applications.

74 d to quantitatively investigate the covering nanomaterial based on subtle changes in the transmission

75 and demerits of TG biosensors, specifically nanomaterials based biosensors.

76 eversibly reconfigurable colloidal plasmonic nanomaterials based on the actuation of interparticle co

77 g with a myriad of other photonically active nanomaterial-based bioconjugates.

78 ion of mechanical energy into electricity by nanomaterial-based devices offers potential for green en

79 This review offers a summary of FNA- and nanomaterial-based metal ion detection methods.

80 tin (FN) results in the production of carbon nanomaterial-based microtubular fibers.

81 trategy and intuition for the development of nanomaterial-based saturable absorbers opening new avenu

82 hybrid films with potential applications in nanomaterial-based technologies.

83 (SAMN@TA) resulted as one of the most robust nanomaterial bearing TA to date.

84 s lipids or proteins, but not from inorganic nanomaterials because of difficulties with the replicati

85 ectrochemical surface stress is important in nanomaterials because of their large surface-to-volume r

86 With the increasing diversity of engineered nanomaterials being considered for large-scale use, this

87 gations would allow rational applications of nanomaterials', beyond cancer, facilitating the expansio

88 Nanomaterial-biomolecule interactions result in the form

89 always prevent immunological reactions to 2D nanomaterials but also suggest applications for PEGylate

90 ls have been extended to substrate-supported nanomaterials, but generally non-quantitatively.

91 dissolution of a wide range of important 2D nanomaterials by forming layered material salts that spo

92 e-ring effect represents a new mode by which nanomaterials can be used to enhance the MALDI-based det

93 Nanomaterials can increase the surface of the transducin

94 including metals, metal films, metal oxides, nanomaterials, carbon nano tubes, polymers, microspheres

95 f alkenyl anions in anionic cyclization) and nanomaterials chemistry (facile doping of the central at

96 environmental fate of functionalized carbon nanomaterials (CNM) remains poorly understood.

97 Despite carbon nanomaterials' (CNMs) potential to alter the bioavailabi

98 Cellulose nanomaterials (CNs)-incorporated emulsion coatings with

99 lypyridyl ruthenium complexes, and ruthenium nanomaterial complexes.

100 pplications; the ability to design synthetic nanomaterials computationally and to optimize them throu

101 Nanomaterials containing high-Z elements to absorb radia

102 sizing a low bandgap electrospun metal-oxide nanomaterial corresponding to a specific oxidation state

103 demonstrate that the rational integration of nanomaterials could be a fruitful path towards building

104 the growth, organization, and activation of nanomaterials could be more widely expanded via the eluc

105 -quadruplexes, and mismatched base pairs and nanomaterials cover gold nanoparticles (GNPs), quantum d

106 antum dots (QDs) are one of the more popular nanomaterials currently utilized within biological appli

107 embranes can expose underlying mechanisms of nanomaterial cytotoxicity and guide the design of safer

108 rt, for the first time, the incorporation of nanomaterial-derived C into soil microbial biomass, prim

109 es and in applications to drug discovery and nanomaterial development.

110 lvent present challenges for spectroscopy of nanomaterial dispersions; most notably the possibility o

111 nd representation of the processes governing nanomaterial distribution in the environment and by scar

112 biomarker owes much credit to functionalized nanomaterials due to their unique opto-electronic proper

113 more versatile and tunable graphene-like 2D nanomaterials (e.g. graphitic carbon nitride, boron nitr

114 nge allows us to integrate this bio-inspired nanomaterial either in an enzymatic fuel cell together w

115 which are combining the advantages of using nanomaterials, electrochemical methods and biosensors.

116 ing life-cycle release models for engineered nanomaterials (ENM) are static, ignoring the dynamics of

117 umber of other characteristics of engineered nanomaterials (ENM) in environmental matrices.

118 ependent accumulation of metallic engineered nanomaterials (ENMs) across environmental media.

119 The rapid development of engineered nanomaterials (ENMs) has grown dramatically in the last

120 The increasing applications of engineered nanomaterials (ENMs) in consumer products warrant a care

121 ed with the vertical transport of engineered nanomaterials (ENMs) in saturated porous media is the oc

122 Ag(0)- and CuO-engineered nanomaterials (ENMs) or their sulfidized forms are intro

123 eractions between crop plants and engineered nanomaterials (ENMs), there is increasing interest in un

124 hazard assessment and ranking of engineered nanomaterials (ENMs).

125 nts are limited in their ability to simulate nanomaterials' environmental behavior by incomplete unde

126 of these organisms have been developed using nanomaterials; Exfoliated Graphene Oxide and Gold Nano-U

127 ed to the lungs of mice, this anti-infective nanomaterial exhibits improved safety profiles over free

128 The functionalized redox nanomaterial exhibits reversible electrocatalytic activi

129 increasing concern, and the implications of nanomaterial exposure on the human immune response is po

130 Recent advances in nanomaterial fabrication and characterization, specifica

131 In particular, nanomaterial facilitated electrochemical detection of DN

132 urvivability in oil reservoirs or to control nanomaterial fate in other aqueous environments.

133 injection fluid salinity and composition on nanomaterial fate is explored using atomic force microsc

134 Functional graphene nanomaterials (FGNs) are fast emerging materials with ex

135 dditionally, the latest advances of other 2D nanomaterial fibers are also summarized.

136 colloids and discuss about the concept of 2D nanomaterial fibers in the context of LCs, elaborating t

137 t and environmentally friendly antimicrobial nanomaterial for the food industry applications.

138 thiol graphene quantum dots (GQD-SH) as the nanomaterial for ultrasensitive and selective detection

139 and biosensing platforms based on functional nanomaterials for biological and biomedical applications

140 CPNs) were also prepared as Raman-responsive nanomaterials for distinct imaging application.

141 ch in nanotechnology contemplates the use of nanomaterials for environmental engineering applications

142 rface is crucial in order to select suitable nanomaterials for further in vitro or in vivo experiment

143 Therefore, the unique properties of nanomaterials for LFAs must be exploited in a way that a

144 importance of designing and synthesizing new nanomaterials for nucleic acid delivery.

145 the integration of recognition elements with nanomaterials for the detection and sensing of pathogeni

146 The cytotoxicity of 2D graphene-based nanomaterials (GBNs) is highly important for engineered

147 lids and thin films assembled from colloidal nanomaterials give rise to versatile properties that can

148 graphene and other graphene-like 2D-layered nanomaterials (GLNs).

149 topic of reversibly reconfigurable plasmonic nanomaterials has become an intensive research area offe

150 d multifunctionalities, two-dimensional (2D) nanomaterials have aroused increasing interest in the co

151 2D Si nanomaterials have attracted tremendous attention due to

152 Nanomaterials have been developed for many biomedical ap

153 Nanomaterials have been extensively used as alternate ma

154 Nanomaterials have been proposed as radiation damage tol

155 to concentrate and scatter light, plasmonic nanomaterials have been the focus of tremendous synthesi

156 t of this multidisciplinary research, carbon nanomaterials have demonstrated unprecedented potential

157 dvances in bioinspired design principles and nanomaterials have led to tremendous progress in autonom

158 Heteroatom-doped carbon nanomaterials have proven to be robust metal-free electr

159 fective biosensing systems based on advanced nanomaterials have received a key attention for developm

160 For hybrid organic-inorganic nanomaterials, here we show that by using 1,3,5 silyl be

161 Several recent strategies for using such 2D-nanomaterial heterostructures in the development of mode

162 Engineered nanomaterials hold great promise for the future developm

163 ovel photovoltaics involving low-dimensional nanomaterials, hot-carrier relaxation and extraction mec

164 required to perform new chemical reviews of nanomaterials identified in premanufacture notices.

165 Thus, the mBiNE represents a new targeted, nanomaterial-immunotherapy platform to stimulate innate

166 iated signaling to inhibit nuclear YAP using nanomaterials implicating an innovative avenue for treat

167 nation of different kinds of low-dimensional nanomaterials in a tube-shaped 3D structure, enabling th

168 However, interfacing to nanomaterials in complex biological environments is chal

169 and in biological systems, the detection of nanomaterials in complex matrices by fluorescence method

170 ities and remaining challenges for colloidal nanomaterials in electronic applications, thereby provid

171 The role of nanomaterials in inhibition-based biosensors for the ana

172 s and bioavailability of soluble metal-based nanomaterials in organic-rich waters.

173 venue for a new spectrum of applications of nanomaterials in preventing clinically significant drug

174 e technique for the synthesis of ligand-free nanomaterials in sealed environments.

175 t in understanding the fate and transport of nanomaterials in the environment and in biological syste

176 ncerns about the potential toxicity of these nanomaterials in the environment.

177 system to explore the fate and transport of nanomaterials in the environment.

178 our attention on their use as components of nanomaterials in the management of cancer and inflammato

179 the fate and toxicity of metallic engineered nanomaterials in the soil environment.

180 effect transistor - as a platform, colloidal nanomaterials in three electronic material categories ar

181 -subpulse train, the production rate of MoS2 nanomaterials (including nanosheets, nanoparticles, and

182 the development of drug products containing nanomaterials, including the relative rate of approvals

183 Two-dimensional (2D) transition metal nanomaterials, including transition metal chalcogenides

184 Because the pace of nanomaterial innovation far outstrips acquisition of env

185 , it is important to elucidate how synthetic nanomaterials interact with critical biological systems

186 ip with a calcite surface, as surrogates for nanomaterials interacting with carbonate reservoir rock.

187 The complete profiling of the bio/nanomaterials interface and interaction should have prof

188 reconfigurable, noncovalent interactions at nanomaterial interfaces, the composite nanofiber network

189 The structure-based design of multivalent nanomaterials, involving modulation of nanoscale backbon

190 ve antibacterial delivery, an anti-infective nanomaterial is developed that utilizes two strategies f

191 The biological contamination of nanomaterials is a serious problem hampering their wides

192 terization, the investigation of non-layered nanomaterials is also proceeding as new types of ultrath

193 biological molecules, such as proteins, and nanomaterials is crucial for developing various biocompa

194 systematic strategy for designing structured nanomaterials is demonstrated through self-assembly of g

195 lenge limiting the practical applications of nanomaterials is that the activities of nanostructures (

196 Sorption to carbon-based nanomaterials is typically studied in batch experiments.

197 However, a single-layer nanomaterial may not possess a particular property adequ

198 The toxicity of soluble metal-based nanomaterials may be due to the uptake of metals in both

199 ferent inhibition biosensor systems based on nanomaterials modification has been proposed and applied

200 . coli quantification in water samples using nanomaterial modified assay.

201 A comparative study of six different carbon nanomaterial-modified electrodes (carbon, graphene (G),

202 fer of triplet excitons across semiconductor nanomaterial-molecular interfaces will play an important

203 has important implications in the fields of nanomaterial, nanomedicine and nanotoxicology, where ass

204 Enzyme-mimicking nanomaterials (nanozymes) are more cost-effective and ro

205 th or epidemiology data exist for engineered nanomaterials (NMs) despite clear parallels in their phy

206 n of current research trends with a focus on nanomaterials (NMs) to considerably improve the performa

207 However, developing nanomaterials (NMs)-based photothermal agents (PTAs) wit

208 e laccase-like reactivity of manganese oxide nanomaterials of different crystallinity, including alph

209 signals that hamper detection of fluorescent nanomaterials of interest.

210 Development of nanomaterials of previously unavailable shapes and compo

211 These nanomaterials offer improved selectivity, activity, and

212 sors comprising of graphene-based conductive nanomaterials offer the advantage of higher sensitivity

213 Use of nanomaterials offers to biosensing platforms exceptional

214 approach for the analysis of the effects of nanomaterials on distinct immune cells, laying the found

215 for the cognate imaging modality-we stratify nanomaterials on the basis of their (i) magnetic, (ii) o

216 the submissions of drug products containing nanomaterials over the last two decades.

217 nanomaterials, and we further show that the nanomaterial-peptide interaction resulted in a significa

218 The formation of the BC is governed by the nanomaterial physicochemical properties and the physiolo

219 of the metal nanoparticles on the 2D carbon nanomaterial planar sheets.

220 design and fabrication of aligned biohybrid nanomaterials potentially useful for future electronic a

221 r significantly from those of graphene-based nanomaterials, potentially leading to new environmental

222 The utilization of nanomaterials, printed technology, and microfluidics in

223 Since current conventional nanomaterial production technologies lack such level of

224 Engineered nanomaterials promise to transform medicine at the bio-n

225 ry challenge is understanding the effects of nanomaterial properties on industrial device performance

226 ormation of the biocorona (BC), which alters nanomaterial properties, function, and biological respon

227 as metal nanoparticles (MNPs), carbon based nanomaterials, quantum dots (QDs), magnetic nanoparticle

228 the first holistic confirmation that pigment nanomaterials remain strongly contained in a plastic tha

229 s is an important development in agriculture nanomaterial research where biodegradable Cu-chitosan NP

230 cell behaviour and the precise control of a nanomaterial's structure and surface chemistry allow for

231 Mesoporous silica nanomaterials show great potential to deliver chemothera

232 This is because the nanomaterial signals are inevitably buried in the signal

233 dularity in being fused to create multimodal nanomaterials (spanning multiple different physical imag

234 -dimensional (3D) assemblies based on carbon nanomaterials still lag behind their individual one-dime

235 tion methods for atomically thin non-layered nanomaterials, study their exotic electronic structures,

236 g a technical profile of products containing nanomaterials submitted to CDER.

237 amino acid or peptide derivatives on carbon nanomaterials such as [60]fullerene.

238 ntly increased through the addition of metal nanomaterials such as aluminium.

239 ition, recent advances in the application of nanomaterials such as gold nanoparticles, carbon nanotub

240 It has been found that a range of nanomaterials such as metal nanoparticles (MNPs), carbon

241 preparation of native CDs-modified inorganic nanomaterials such as metal, metal oxide, and semiconduc

242 The use of different nanomaterials such as nanochannels and metallic nanopart

243 rrent status of challenging light-harvesting nanomaterials, such as semiconducting quantum dots (QDs)

244 thetical trends in the market development of nanomaterials, such as the emergence of a new widely use

245 cal techniques and instrumentation involving nanomaterials, surface plasmon resonance, and aptasensor

246 es are known to recognize and bind different nanomaterial surfaces, which has resulted in the screeni

247 t the pN-scale, a possible means to increase nanomaterial survivability in oil reservoirs or to contr

248 applications such as catalysis, electronics, nanomaterial synthesis and biosensing.

249 eps require careful consideration, including nanomaterial synthesis or exfoliation, purification, sep

250 y for a variety of applications ranging from nanomaterial synthesis to distributed monitoring of atmo

251 electrode architecture over other routes to nanomaterials synthesis for device applications.

252 eir targeted delivery, and their activity in nanomaterial systems.

253 h the loss of aroma compounds was lower with nanomaterials than with bentonite.

254 vinyl alcohol (PVA), creating an amphiphilic nanomaterial that is water-soluble.

255 des are extraordinarily skilled engineers of nanomaterials that contribute significantly to global bi

256 Changes in the material structure of Bi2Se3 nanomaterials that have been milled using a focused ion

257 n the exciting potential of high-performance nanomaterials that will cause disruptive improvements in

258 self-assembly for the bottom-up synthesis of nanomaterials, the effects of chemical control (strength

259 address the physicochemical makeup/design of nanomaterials through the lens of the physical propertie

260 ars great progress has been made in applying nanomaterials to design novel biosensors.

261 In the current study, the ability of nanomaterials to prevent drug incompatibilities in clini

262 e ban on certain substances, on the flows of nanomaterials to the environment in years to come.

263 ending the applicability of LSPC-synthesized nanomaterials to various fields.

264 Self-assembly of nanomaterials to yield a wide diversity of high-order st

265 ystallographic analysis for liquid-dispersed nanomaterials, to improve the precision of nanocrystal e

266 ng method will facilitate rapid screening of nanomaterial toxicity and thus inform the risk assessmen

267 rferences observed in typical MALDI but such nanomaterials typically do not improve the spot-to-spot

268 Using (13)C-labeled nanomaterial we present the results of a study investiga

269 e to introduce selectivity in graphene-based nanomaterials were tried collected together.

270 Mesoporous nanomaterials were used to prevent protein haze in Musca

271 nsured minimal optical interference from the nanomaterial when reading optical density, and the resid

272 lled in single-crystalline halide perovskite nanomaterials when combined with nanofabrication techniq

273 but also suggest applications for PEGylated nanomaterials wherein immune stimulation is desired.

274 Porous 1D nanomaterials which combine the advantages of 1D nanoarc

275 transitional metal doped iron oxy-hydroxides nanomaterials, which show good catalytic performances fo

276 nd second approaches were designed to employ nanomaterials while third and fourth approaches were dev

277 graphane, outlining how the new modified 2D nanomaterials will improve the electrochemical performan

278 s of inhibition-based biosensors that employ nanomaterials will serve researchers as a guideline for

279 on subtle changes in the transmission of the nanomaterial with high efficiency rivalling that of conv

280 the translation of theoretical research into nanomaterials with applicability within the drug-deliver

281 r the discovery of graphene, two-dimensional nanomaterials with atomic thickness and large lateral si

282 Nanomaterials with different characteristics are offerin

283 mpirical data quantifying the interaction of nanomaterials with environmental surfaces.

284 Biocompatible nanomaterials with enzymatic properties could play a cru

285 Recently, these catalytic nanomaterials with enzyme-mimetic properties have found

286 sualization of a phase reaction of composite nanomaterials with high spatial and temporal resolution

287 olecular assemblies are a promising class of nanomaterials with important biomedical applications, sp

288 tudies are mainly focused on atomically thin nanomaterials with layered structures due to their easy

289 y simple and facile methods to fabricate ZnO nanomaterials with low cost and energy consumption.

290 ction environment for the synthesis of oxide nanomaterials with low dimensionality.

291 BN) nanosheets are important two-dimensional nanomaterials with many unique properties distinct from

292 In vitro incubation of nanomaterials with plasma offer insights on biological i

293 ent strategies and endowing designed protein nanomaterials with properties useful in nanomedicine and

294 perconnected network architectures can endow nanomaterials with remarkable mechanical properties that

295 cles (NPs) could enable access to functional nanomaterials with significant performance benefits.

296 able effort to understand the interaction of nanomaterials with the skin.

297 ns, microfabrication techniques, and diverse nanomaterials with unique properties for in vivo and in

298 Graphenes are two-dimensional (2D) nanomaterials with unprecedented physical, optical, and

299 In this regard, the incorporation of nanomaterials within hydrogels has shown great promise,

300 ethod in infrared astronomy, to characterize nanomaterials without the influence of underlying substr