ライフサイエンスコーパス: nanomaterial

1 ligand binding and the surface structure of nanomaterials.

2 (AgNPs) are one of the most used engineered nanomaterials.

3 esent an attractive alternative to DNA-based nanomaterials.

4 ntrollable self-assembling 2D macromolecular nanomaterials.

5 advantageous for the design of adaptive bio/nanomaterials.

6 modifications for both organic and inorganic nanomaterials.

7 activity in neuronal cultures in response to nanomaterials.

8 tive structural motif for creating DNA-based nanomaterials.

9 proach to extracting dielectric functions of nanomaterials.

10 n of discoveries in the design of functional nanomaterials.

11 ay affect the surface chemistry of colloidal nanomaterials.

12 ed proteins across species and for other TMO nanomaterials.

13 py, including ions, small-molecule drugs and nanomaterials.

14 to its broad compatibility with a variety of nanomaterials.

15 o targeting of IDPs by specifically designed nanomaterials.

16 d offers novel tools to investigate biogenic nanomaterials.

17 for the synthesis of inorganic-protein based nanomaterials.

18 articular advantages and applications of FNA nanomaterials.

19 tly identified as a mechanism of toxicity of nanomaterials.

20 e biological interactions and trafficking of nanomaterials.

21 dful due to innumerable after-effects of the nanomaterials.

22 ctive biological applications of crystalline nanomaterials.

23 n promoting cyclic deformability of metallic nanomaterials.

24 rated numerous experimental data for various nanomaterials.

25 compared to other reported organic electrode nanomaterials.

26 erials as elements for creating advanced FNA nanomaterials.

27 and biofunctionalization approaches of these nanomaterials.

28 tion of the metal evaporation from the three nanomaterials.

29 f magnitude lower than Au-, C-, and Si-based nanomaterials.

30 trolling the morphology and structure of the nanomaterials.

31 , represent an exciting and growing class of nanomaterials.

32 own to catalyze the biodegradation of carbon nanomaterials.

33 esis of functional and tunable polyelemental nanomaterials.

34 ploited toward the synthesis of well-defined nanomaterials.

35 scavenging extracellular ROS using advanced nanomaterials.

36 e reported numerous methods to construct FNA nanomaterials.

37 ch as solar materials, electrocatalysts, and nanomaterials.

38 nced through the geometric structures of the nanomaterials.

39 into the structure-function relationships of nanomaterials.

40 structure; (2) Application and synthesis of nanomaterial; (3) The detection principle of the propose

41 well suited to immunotherapy on the basis of nanomaterials' ability to direct immunomodulators to tum

42 will discuss these aspects along with recent nanomaterial advances towards vaccines against infectiou

43 n residues present in MWCNTs-Av/RuNPs hybrid nanomaterial allowed the anchoring by bioaffinity of bio

44 we first introduce some widely used FNAs and nanomaterials along with their classification, structure

45 ensor based on hybrid epitope imprinting and nanomaterial amplification was developed.

46 The simultaneous injection of the nanomaterial and the dye in a flow injection analysis sy

47 Here, we report the preparation of five nanomaterials and a study of their ability to modulate P

48 ons, ranging from foodstuff to processing of nanomaterials and advanced manufacturing.

49 ght after for the construction of innovative nanomaterials and applications in medicinal chemistry su

50 the development of geometrically structured nanomaterials and associated devices is summarized.

51 ing, at the single particle level, catalytic nanomaterials and deactivation processes under operando

52 em promising for the fabrication of advanced nanomaterials and devices for diverse applications.

53 The applications of nanomaterials and electrochemical aptasensors for the de

54 n the study of interactions between FNAs and nanomaterials and explores the particular advantages and

55 vior similar to other small clusters such as nanomaterials and fullerenes.

56 Recent advances in nanomaterials and nano-microfabrication have enabled the

57 ten the innovative construction of composite nanomaterials and nanoarchitectonics for bio-sensing sys

58 ructural insights into the protein corona on nanomaterials and offers a new strategy to manipulate it

59 heds light on structurally unexplored copper nanomaterials and paves the way for the synthesis of hig

60 Structural designs of nanomaterials and platforms for stretchable respiration

61 deformation behavior of future DNA-assembled nanomaterials and provide evidence that supramolecular c

62 niform ultralarge elastic strains (4-10%) of nanomaterials and the uniform crystallographic lattice d

63 e outline the future challenges of TMN-based nanomaterials and their possible research directions bey

64 ces in the development of aptamer-conjugated nanomaterials and their utilization for the detection of

65 r results were obtained on model metal oxide nanomaterials and they shed light on a general process t

66 scuss the opportunity of utilizing plasmonic nanomaterials and tools for biomarker detection beyond b

67 se optical properties and functionalities of nanomaterials, and compare it with ensemble fluorescence

68 effective method for preparing amorphous Pd nanomaterials, and demonstrates their promising electroc

69 ysis promoted by the PA rim/cavity, PA-based nanomaterials, and PA-based polymeric materials.

70 l characterization of 2D materials and other nanomaterials, and potentially accelerate new material d

71 t heave, biomineralization, the synthesis of nanomaterials, and scale formation, occur in small volum

72 yclodextrins, 1,1'-binaphthyl compounds, and nanomaterials, and uses them to illustrate the design st

73 se cell entry processes will not only aid in nanomaterial applications but also broaden our knowledge

74 ence of surface oxides on other carbon-based nanomaterials are also evaluated and discussed.

75 mensional (2D) molybdenum disulfide (MoS(2)) nanomaterials are an emerging class of biomaterials that

76 Nanomaterials are being increasingly utilized for enviro

77 Antibody-modified gold nanomaterials are central to many novel biosensing techn

78 r achievements in the development of helical nanomaterials are highlighted.

79 hnology benefits modern vaccine design since nanomaterials are ideal for antigen delivery, as adjuvan

80 low temperatures (250 to 450 degrees C) the nanomaterials are most probably entrained in the flue ga

81 phase-based heterostructures of noble metal nanomaterials are of great research interest for various

82 argely of egg-derived polymers and cellulose nanomaterials as a conformal coating onto fresh produce

83 in controlling the mechanical properties of nanomaterials as a function of their hierarchical design

84 es for widespread clinical implementation of nanomaterials as antimicrobial therapeutics.

85 e most successful methods employing FNAs and nanomaterials as elements for creating advanced FNA nano

86 materials, the interactions between FNAs and nanomaterials as well as FNA self-assembly technologies

87 ared innovative drug-integrating amphiphilic nanomaterial assemblies (DIANA) with tunable hydrophobic

88 This novel nanomaterial-assisted anti-TB strategy manipulating anti

89 s) against Mtb and further introduce a novel nanomaterial-assisted anti-TB strategy manipulating Ison

90 The programming of nanomaterials at molecular length-scales to control arch

91 ight recent progress based on using advanced nanomaterials at the electrode-enzyme interface of three

92 ative technique for the development of other nanomaterials based on isoimperatorin under green condit

93 uminescence of lanthanide ions makes optical nanomaterials based on these elements uniquely attractiv

94 An advanced nanomaterial-based biosensing platform that detects COVI

95 cancer theranostics and perspectives for Gd nanomaterial-based cancer theranostics are provided.

96 Nanomaterial-based drug delivery may overcome these limi

97 Nanomaterial-based drug delivery vehicles are able to de

98 The development of advanced nanomaterial-based electrochemical sensors and biosensor

99 y-enabled thermally transferred (XTT) carbon nanomaterial-based electrochemical sensors is proposed.

100 tentially employed to develop pure or hybrid nanomaterial-based electrodes.

101 romise to be used as self-calibrating carbon nanomaterial-based MPO activity indicators.

102 ntanyl down to the nanomolar level through a nanomaterial-based multilayered surface architecture.

103 Nanomaterial-based therapies are promising tools to comb

104 tems, immunotherapy, microbiome restoration, nanomaterial-based therapy and phage therapy may help to

105 This review article surveys state-of-the-art nanomaterials-based electrochemical sensors and biosenso

106 carried out prior to clinical translation of nanomaterials-based formulations to avoid serious neurot

107 assisting the design of ordered, anisotropic nanomaterials but also broaden the available toolbox for

108 vestigate the enhanced uptake of theranostic nanomaterials by CAP.

109 Several nanomaterials can be entrapped in lysosomes, but the dev

110 we highlight the general mechanisms by which nanomaterials can be used to target bacterial infections

111 -response, and delivery potential of various nanomaterials can give rise to a variety of novel fascin

112 Nanomaterials can play an essential role in bacterial se

113 ic analysis, as well as many other fields of nanomaterial characterization.

114 Cellulose nanomaterials (CNMs) are a class of materials that have

115 t to be extensively adopted by the colloidal nanomaterial community.

116 are summarized from the view of the role of nanomaterial components, i.e. immobilization matrix, cat

117 es for the modification of LDG sensors using nanomaterials, conducting polymers, biological and artif

118 version to Cr (III), indicating polymers and nanomaterials containing alcohol groups can remove and c

119 to fulfill the regulation requirement on the nanomaterial-containing products.

120 e tremendous technological impact that these nanomaterials could have in fields like biomedicine and

121 wly discovered nanomaterial quarantining and nanomaterial cycling between different lung cell types.

122 Here, we report the construction of a large nanomaterial database containing annotated nanostructure

123 However, the few nanomaterial databases available are not suitable for mo

124 Current approaches for nanomaterial delivery in plants are unable to target spe

125 offers significantly expedited and enhanced nanomaterial discovery, optimization, and manufacturing.

126 e is a growing concern about the toxicity of nanomaterials dispersed in air and water effluents that

127 (LA-ICP-MSI) can be used together to obtain nanomaterial distributions and biochemical consequences.

128 ited analytical methods that can detect both nanomaterial distributions and their biochemical effects

129 challenging to prepare amorphous noble-metal nanomaterials due to the strong interatomic metallic bon

130 Unlike most titania nanomaterials, during pyrolysis the NPs undergo no trans

131 Nanomaterial-enabled flexible and stretchable electronic

132 Then, representative nanomaterial-enabled flexible and stretchable sensing sy

133 Compared with nanomaterial-enabled sensors with a single function, int

134 While novel nanomaterials enhance delivery efficiency, uncontrolled

135 about the inflammatory effects of engineered nanomaterial (ENM) have been raised, experimentally asse

136 he effects and modes of action of engineered nanomaterials (ENMs) in this way.

137 he environmental fate and risk of engineered nanomaterials (ENMs) require a better understanding of E

138 shed that toners contain multiple engineered nanomaterials (ENMs), little is known about inhalation e

139 origami technique hold tremendous promise in nanomaterial fabrication and biotechnology.

140 agnitude larger and broadens the methods for nanomaterial fabrication.

141 However, many commercial irregular porous nanomaterials face the challenge to realize satisfactory

142 Semiconductor nanomaterials feature size-tunable energy level engineer

143 It was possible to reuse the same magnetic nanomaterial for 6 successive cycles, and we obtained a

144 ns of aptamer sensors (aptasensors) based-on nanomaterial for arsenic detection, in particular with e

145 We propose PPNs as a new nanomaterial for delivery of therapeutics, which can be

146 Gold is a highly useful nanomaterial for many clinical applications, but its poo

147 esponse, graphene is an especially promising nanomaterial for nonlinear optoelectronic applications.

148 Here, we report a breakthrough hybrid nanomaterial for remote, nongenetic, photothermal stimul

149 advances in the design of fullerene-based LD nanomaterials for (photo)electrocatalytic applications a

150 integration and synergy between proteins and nanomaterials for biosensing is emphasized and discussed

151 to overview recent advances in the Gd-based nanomaterials for cancer theranostics and perspectives f

152 edure generates 2142 nanodescriptors for all nanomaterials for machine learning purposes, which are a

153 o support exposure assessment for engineered nanomaterials for regulatory and research applications.

154 e properties and functionalities of existing nanomaterials for the detection of pharmaceuticals; and

155 s, and new advances based on implications of nanomaterials for the development of biosensors detectin

156 gly, the demand for using aptamer-conjugated nanomaterials for various applications has progressively

157 of high-performance, multi-functional carbon nanomaterials for various applications.

158 These particles present a novel nanomaterial formulation and address a critical unresolv

159 I, which can induce the transformation of Pd nanomaterials from face-centered-cubic (fcc) phase into

160 The fabrication of nanomaterials from the top-down gives precise structures

161 A new iron-magnetic nanomaterial functionalized with organophosphorus compou

162 , the unique size and physical properties of nanomaterials give them the capability to target biofilm

163 O USNPs enables rapid renal clearance of the nanomaterial, guaranteeing the biocompatibility.

164 Each nanomaterial has up to six physicochemical properties an

165 ling in neurons related to interactions with nanomaterials has become of interest due to its therapeu

166 the use of various geometrically structured nanomaterials has been actively reported in enhanced-per

167 The study of different chiral inorganic nanomaterials has been experiencing rapid growth during

168 Even though high-pressure research on nanomaterials has been widely conducted, their shape-dep

169 tic-based strategies and promising work with nanomaterials has recently started to emerge.

170 Copper-based nanomaterials have attracted tremendous interest due to

171 Nanomaterials have been extensively utilized in biosensi

172 gard, several types of gadolinium (Gd)-based nanomaterials have been introduced to combine different

173 ochemical biosensors with the integration of nanomaterials have emerged as a better platform for neon

174 Printing techniques using nanomaterials have emerged as a versatile tool for fast

175 Recently, geometrically structured nanomaterials have received great attention due to their

176 ottom-up approaches based on low-dimensional nanomaterials have shown novel device functionality that

177 Many nanomaterials have shown to have the ability to mimic th

178 transformation fills a high priority gap in nanomaterial hazard assessment and is proposed for the i

179 Thermal-stimuli responsive nanomaterials hold great promise in designing multifunct

180 physicochemical properties, numerous protein-nanomaterial hybrids (PN hybrids) have been designed and

181 The incorporation of different nanomaterial in bio-based polymers such as (Chitosan, po

182 he ability to pattern, organize, or assemble nanomaterials in a 3D printing process.

183 cle counting on different populations of the nanomaterials in a mixture, which cannot be done by eith

184 we review the extensive applications of FNA nanomaterials in bioimaging, biosensing, biomedicine, an

185 The use of DNA-based nanomaterials in biomedical applications is continuing t

186 Increasing applications of nanomaterials in consumer goods, industrial products, me

187 s enabled advances in the use of luminescent nanomaterials in imaging, sensing and photonic devices.

188 operties and uses of this important class of nanomaterials in many fields.

189 opens a new strategy for the application of nanomaterials in soil remediation that could simultaneou

190 Overall, the concentrations of these nanomaterials in the Barcelonan coast were significantly

191 es new questions about the roles of biogenic nanomaterials in the coevolution of the lithosphere and

192 pectrum of structural diversity of cellulose nanomaterials in the form of micro-nano-sized particles

193 s are a rapidly expanding subclass of chiral nanomaterials in which NPs are arranged in three dimensi

194 d optimization of various solution-processed nanomaterials, including semiconductor quantum dots and

195 While positively charged nanomaterials induce cytotoxicity in many organisms, muc

196 in this review, we have primarily focused on nanomaterials-induced neurotoxicity of the brain.

197 technology industry and the incorporation of nanomaterials into consumer applications will inevitably

198 ly, the recent introduction of semiconductor nanomaterials into hybrid TADPL constructs is discussed,

199 The precise preparation of monodisperse nanomaterials is among the most fundamental tasks in ino

200 We confirm that the enhanced uptake of nanomaterials is clathrin-dependent using chemical inhib

201 n, the most up-to-date progress on TMN-based nanomaterials is comprehensively reviewed, focusing on g

202 he convergence of 3D printing techniques and nanomaterials is generating a compelling opportunity spa

203 rication of various geometrically structured nanomaterials is given, and then the performance enhance

204 ances that helped define the field of chiral nanomaterials is provided, and some of the major achieve

205 A highly coveted class of such nanomaterials is represented by colloidal lanthanide-dop

206 impurities during the chemical synthesis of nanomaterials is usually uncontrolled and rarely reporte

207 e physical and chemical advantages of carbon nanomaterials like single-walled carbon nanotubes (SWNTs

208 etal oxide (TMO) lithium-ion battery cathode nanomaterial, lithium cobalt oxide (LCO), on the growth,

209 physicochemical properties of graphene-based nanomaterials make them ideal candidates for engineering

210 nt MNPs, corresponding modifiers, and porous nanomaterials makes our strategy promising in selective

211 teristics, the fate of the thermally treated nanomaterials may differ or not from the conventional on

212 Novel versatile nanomaterials may facilitate strategies for simultaneous

213 ocation into different regions of the brain, nanomaterials may induce neurotoxicity through multiple

214 Although the thickness of the nanomaterials measured by PSI can be highly sensitive to

215 The increasing use of manufactured nanomaterials (MNMs) and their inevitable release into t

216 lidate the key particle features that govern nanomaterial-mucosa interactions and that are relevant i

217 udy the thermal release of metals from three nanomaterials, namely CuO, ZnO, and TiO(2), embedded in

218 ncements achieved in devices utilizing these nanomaterials, namely, i) physical and gas nanosensors,

219 resented for preparing and forming cellulose nanomaterial nanocomposites.

220 active proteins (enzyme, antibody, etc.) and nanomaterials (nanoparticles, nanotubes, nanosheets, nan

221 The use of novel pesticides containing nanomaterials (nanopesticides) is growing and is conside

222 The development of enzyme-mimicking nanomaterials (nanozymes) with good reactive oxygen spec

223 Filtered nanomaterial (NM) films were transferred from Teflon fil

224 of specific sensor technologies integrating nanomaterials offers a viable alternative for rapid and

225 the aptamer-based sensors (aptasensors) with nanomaterials offers enhanced specificity and sensitivit

226 Direct synthesis of thin-film carbon nanomaterials on oxide-coated silicon substrates provide

227 xicity and no influence of engineered carbon nanomaterials on the cell cycle of PANC-1 and AsPC-1 can

228 or understanding the properties of catalytic nanomaterials, one at a time.

229 unique characteristic features, a variety of nanomaterials (particularly, ultra-fine particles (UFPs)

230 In this context, nanomaterials, particularly dye-doped silica nanoparticl

231 lls in a solution display variable uptake of nanomaterials, peptides, and nutrients.

232 le for characterization of pure, homogeneous nanomaterial preparations, particle sizing and counting

233 ctions, and the unique optical properties of nanomaterials provide excellent properties for biosensor

234 m the interplay between the newly discovered nanomaterial quarantining and nanomaterial cycling betwe

235 al and functional group features of FNAs and nanomaterials rapidly develops, many laboratories have r

236 The size distribution of both nanomaterials remained virtually unchanged.

237 Fe protein to light-harvesting semiconductor nanomaterials replaces the natural electron transfer com

238 dous substances, and sensitive and selective nanomaterials represent only a few of these potential ap

239 anocomposites with various (bio)polymers and nanomaterials, respectively.

240 hemical sensors to demonstrate the impact of nanomaterial's modification in the polymer network for b

241 elivery, as well as for assessing engineered nanomaterial safety.

242 s coordination polymers, are a major part of nanomaterials science, and their role in catalysis is be

243 ith dual functionality (indicator and host), nanomaterials, sensors based on upconversion and 2-photo

244 for rapid characterization of heterogeneous nanomaterial solutions without purification to fulfill t

245 ly, perspectives on the development of novel nanomaterial structures and associated devices are prese

246 In order for sustainable nanomaterials such as cellulose nanocrystals (CNCs) to b

247 The large-scale processing of nanomaterials such as graphene and MoS(2) relies on unde

248 Two-dimensional (2D) nanomaterials, such as graphene and single layer covalen

249 mination of the gas adsorption capacities of nanomaterials, such as metal-organic frameworks (MOF), h

250 is assisted by the GNPs scaffold through the nanomaterial-surface energy transfer (NSET) effect, whic

251 ol crystallization in applications including nanomaterial synthesis, heavy metal remediation, and the

252 of these unique tools in bioconjugation and nanomaterial synthesis.

253 ured catalysts are a relatively new class of nanomaterials that allow a controlled integration of the

254 porous N- or P-doped graphitized MOF-derived nanomaterials that are increasingly used as efficient ca

255 emphasize design elements and properties of nanomaterials that can be engineered to enhance potency.

256 r the continuous manufacturing of hollow HEA nanomaterials that can find broad applications in energy

257 Copper nanoclusters are a new class of nanomaterials that can provide an atomic-level view of t

258 gy for producing engineered thin-film carbon nanomaterials that have a nano-graphitic structure.

259 ypes of nanocomposites are examples of smart nanomaterials that have drawn intense attention in the f

260 ials that combine the advantages of FNAs and nanomaterials, the interactions between FNAs and nanomat

261 The deposition processes of the nanomaterials, the procedure of attaching NDS to the fib

262 of creating shape selectivity in MNPs/porous nanomaterials through intentionally poisoning certain MN

263 gn and preparation of multifunctional hybrid nanomaterials through the stabilization of gold nanopart

264 is establishes the viability of a functional nanomaterial to augment photosynthesis as a route to inc

265 electrodes, exploiting carbon black as smart nanomaterial to monitor changes in algae oxygen evolutio

266 films enabled us to selectively transfer the nanomaterial to the exposed EVA side of the substrate.

267 erials science in tailoring the synthesis of nanomaterials to achieve optical uniformity and to devel

268 pired rational design and engineering of new nanomaterials to incorporate desired enzymes into the pr

269 lysosomes, but the development of functional nanomaterials to promote phagolysosomal Mtb clearance re

270 large chemically accessible surface areas of nanomaterials to yield massive, finely-controlled, and s

271 y, tuning the selectivity of obtained carbon nanomaterials towards Fyn A and BTK kinases.

272 active role in selectively controlling where nanomaterial transfer occurred allowing us to design dif

273 rted mechanism of membrane repair to trigger nanomaterial uptake.

274 ve intracellular delivery, types of nonviral nanomaterials used as delivery vehicles, and the differe

275 he wire-grids, ordered surfaces, and aligned nanomaterials used to make polarized films cannot be eas

276 design and development of atomically precise nanomaterials via ligand tailoring and alloy engineering

277 ses indicated that non-lattice oxygen in the nanomaterials was chiefly responsible for this catalytic

278 Internalization of nanomaterials was confirmed by neutron activation analys

279 The prepared nanomaterials were characterized by XRD, FTIR dynamic li

280 These nanomaterials were coated in the pottery's that date bac

281 These nanomaterials were sequentially deposited on to the scre

282 e last stage of the life cycle of engineered nanomaterials, which are then incinerated or stabilized

283 The synergistic integration of nanomaterials with 3D printing technologies can enable t

284 ts the latest advances in the integration of nanomaterials with 3D printing, achieved by leveraging m

285 ated to be a powerful approach for preparing nanomaterials with a range of interesting optical and el

286 nanoscale platform that targets and delivers nanomaterials with biochemicals to plant photosynthetic

287 Targeted delivery of nanomaterials with chemical cargoes guided by biorecogni

288 ient conditions, and is applicable to fcc Pd nanomaterials with different capping ligands.

289 printing approach can seamlessly interweave nanomaterials with diverse classes of materials to impar

290 Nanomaterials with enzyme-like activities, coined nanozy

291 e the realization of devices based on carbon nanomaterials with exotic quantum properties.

292 The optimal synthesis of advanced nanomaterials with numerous reaction parameters, stages,

293 Optical nanomaterials with photo-encoded thermal properties migh

294 function of IDPs when encountering inorganic nanomaterials with the potential to control their behavi

295 Porous nanomaterials with uniform pore structures are ideal sup

296 Carbon nanoallotropes are important nanomaterials with unusual properties and promising appl

297 peutic modalities, biological interaction of nanomaterials with various body tissues may produce seve

298 when devising and synthesizing this class of nanomaterials, with a keen eye on the foreseeable techno

299 Nanomaterials, with their defined compositions, commonly

300 thiophene):polystyrene sulfonate (PEDOT:PSS) nanomaterials within poly(2-hydroxyethyl methacrylate-co