ライフサイエンスコーパス: chemistry

1 n be profiled and imaged using bioorthogonal chemistry.

2 bioinformatic survey to classify known YcaO chemistry.

3 el positive and graphite negative electrodes chemistry.

4 online measurements of the in-cylinder soot chemistry.

5 has considerable potential in supramolecular chemistry.

6 main true regardless of the stationary phase chemistry.

7 fundamental tool for nonequilibrium systems chemistry.

8 g, field-effect transistors, and recognition chemistry.

9 of ovary gene expression with surface water chemistry.

10 adical (HO2) is a key species to atmospheric chemistry.

11 l enzymes is a long-standing goal in protein chemistry.

12 mode of reactivity for late-transition-metal chemistry.

13 well as the parallels with synthetic organic chemistry.

14 videnced by examples in the realm of peptide chemistry.

15 s properties, many of which can be tuned via chemistry.

16 s represent a demanding challenge in aerosol chemistry.

17 lasses of isomerization reactions in organic chemistry.

18 sis of squalene, a key species in indoor air chemistry.

19 rticles where they can promote heterogeneous chemistry.

20 in optoelectronics, photovoltaics and green chemistry.

21 nd selective biocatalysts for organosiloxane chemistry.

22 rotons, also showed interesting coordination chemistry.

23 rating peptide, using bioorthogonal ligation chemistry.

24 arch in fields such as mechanistic synthetic chemistry.

25 the Meisenheimer complex and its subsequent chemistry.

26 idely considered the birth of supramolecular chemistry.

27 ighlighting the inherent versatility of this chemistry.

28 access to motifs commonly used in medicinal chemistry.

29 ich is a topic of high interest in medicinal chemistry.

30 y using the familiar tools of organometallic chemistry.

31 of the foremost challenges in supramolecular chemistry.

32 uch functionality available for use in click chemistry.

33 the linchpin of drug discovery and medicinal chemistry.

34 of the archetypal transformations of organic chemistry.

35 to sorb metal(loid)s is affected by solution chemistry.

36 of action studies, and eventually medicinal chemistry.

37 state of open-source research in analytical chemistry.

38 tiators via the phosphate-Zr(4+)-carboxylate chemistry.

39 the V1-V3 region using Illumina's 2 x 300 bp chemistry.

40 obilized SAv by choosing appropriate surface chemistry.

41 ns with a non-canonical amino-acid and click chemistry.

42 es to the Birch reduction known from organic chemistry.

43 cience and nanoscale regio-selective surface chemistry.

44 pathways, as well as atmospheric sources and chemistry.

45 ntum theoretical calculations using G4 model chemistry.

46 ains one of the most difficult challenges in chemistry.

47 d the precursor were produced by solid-phase chemistry.

48 g to wide variability in terpene content and chemistry.

49 sembled in a combinatorial fashion via click chemistry.

50 reactions without any prior knowledge of the chemistry.

51 the transferability of functional groups in chemistry.

52 tional metal ion chelate or prosthetic group chemistries.

53 rely on mutations or inefficient conjugation chemistries.

54 wo unrelated cyclase enzymes using different chemistries.

55 rsions spanning carbon, nitrogen, and oxygen chemistries.

56 d reactions for all but the very simplest of chemistries.

57 ation kinetics in different aqueous solution chemistries.

58 tion (AMMM) and N-heterocyclic carbene (NHC) chemistry, a novel C-N bond activation and ring-opening

59 tudy, we demonstrate that novel coordination chemistry accessible to ceCblC-bound cobalamin supports

60 emistry and critically discusses recent flow chemistry accounts.

61 ) nanoparticles presenting different surface chemistries, after administration by convection-enhanced

62 Systems chemistry aims to emulate the functional behavior observ

63 Relative to many other areas in chemistry, analytical chemistry appears singularly laggi

64 s with a range of membrane textures, surface chemistries and optical properties.

65 ign other quasicrystal-forming self-assembly chemistries and processes.Probing the growth pathways of

66 tive nets are of prime importance in crystal chemistry and are regarded as ideal blueprints for the r

67 ive was to compare fruit morphology, physico-chemistry and bioactive compounds content of the edible

68 Afforestation significantly affects soil chemistry and biota, but its effects on the potentially

69 nce in disciplines as diverse as atmospheric chemistry and cell biology.

70 he basic principles and fundamentals of flow chemistry and critically discusses recent flow chemistry

71 Clinopyroxenes in the xenolith had the same chemistry and crystallographic orientation as those for

72 ghlight the complex interplay between defect chemistry and defect dynamics in determining nanoparticl

73 tion and optimization to solving problems in chemistry and engineering.

74 t the independent roles tree mortality, soil chemistry and geographical distance play in regulating t

75 a framework that incorporates both solution chemistry and geometric constraints on the calcite solid

76 escent probes for applications in analytical chemistry and imaging.

77 ses the emergence of new states of matter in chemistry and material science.

78 stablished concepts in the fields of quantum chemistry and material sciences have to be adapted when

79 sition metal chemistry, catalysis, medicinal chemistry and materials science.

80 lishment of causal relationships between the chemistry and microbial composition of the rhizosphere.

81 eight GOALs characterized by different GOAL chemistry and morphology and indicates that GOAL nanocha

82 GO chemistry and morphology were controlled with easy-to-im

83 Such spatially resolved correlations between chemistry and nanomechanics during deconstruction not on

84 ed expansion of the fields of macromolecular chemistry and nanoscience has motivated the development

85 also interesting targets for supramolecular chemistry and nanotechnology.

86 ines have wide applications in bioorthogonal chemistry and natural product synthesis.

87 ed for fundamental insights into the surface chemistry and photochemistry of numerous probe molecules

88 methods of their synthesis and discuss their chemistry and properties.

89 t the interplay between reversible disulfide chemistry and self-assembly can give rise either to mole

90 ultaneously leveraging synthetically enabled chemistry and structure-based drug design has resulted i

91 H2O2 and investigated the changes in surface chemistry and the adsorption behavior of ammonium and ph

92 Although they share general reaction chemistry and the capacity to govern DNA topology and re

93 and evolve to enable the control of reaction chemistry and the design and realization of a range of a

94 f drug ring combinations in modern medicinal chemistry and to identify areas of under-represented, bu

95 enge due to its nontrivial dependence on the chemistry and topography of biomolecular surfaces.

96 ficant and novel emerging area for medicinal chemistry and we provide an overview of one of the key e

97 tegy could be of great importance in surface chemistry and widely applied to control on-surface react

98 ich are usually prepared by dynamic covalent chemistry) and for the synthesis of viologen-based mater

99 this method in organic synthesis, medicinal chemistry, and chemical biology.

100 e, Washington, including mineralogy, crystal chemistry, and Fe(II)/(III) content, indicates that ferr

101 ontrol the composition, size, shape, surface chemistry, and functionality of materials.

102 report, using molecular genetics, analytical chemistry, and mass spectrometry analysis, we demonstrat

103 NDs affected the microstructural evolution, chemistry, and mechanical properties of WC-Co.

104 ker discovery, drug discovery, environmental chemistry, and metabolomics.

105 Scaffolds are a core concept in medicinal chemistry, and they can be the focus of multiple indepen

106 to many other areas in chemistry, analytical chemistry appears singularly lagging behind in India des

107 demonstrates the capabilities for analytical chemistry applications by comparing electronically reson

108 This study reports a novel green chemistry approach to assemble copper-nanowires/reduced-

109 Here, starting with a medicinal chemistry approach, Baker et al. generate an imidazopyri

110 operties can be tuned using the isoreticular chemistry approach.

111 didate that was identified using a medicinal chemistry approach.

112 transformations include Type II Anion Relay Chemistry (ARC) to construct the polyol chain, a Ti-cata

113 s as the initial nucleophile for anion relay chemistry (ARC).

114 These climatic effects on water chemistry are especially strong in catchments where frag

115 tion-metal-based catalysts; this and related chemistry are the subject of this review.

116 a key role in astrophysical and ionospheric chemistry, as well as the detonation chemistry of high-e

117 Michael chemistry to predominantly disulfide chemistry, as well as to any intermediate state.

118 We refer to this concept as chemistry at a point and illustrate it by tracking indiv

119 Breslow, Samuel Latham Mitchill Professor of Chemistry at Columbia University, passed away on October

120 taLg) to caffeic acid (CA) using crosslinker chemistry at different pH conditions (pH 2.5, 6.0, and 8

121 form exhibits reversible, two-electron redox chemistry at mild potentials and reacts with O2, CO2, an

122 or clean fuel production, but uncovering the chemistry at the electrode surface remains a challenge.

123 ating feedback loops and pushing replication chemistry away from equilibrium.

124 We recently reported a click-chemistry based method for generating RNAseq libraries c

125 This live cell chemistry-based approach should be valuable for investig

126 a robust, high-throughput compatible, click chemistry-based approach to identify small molecules tha

127 ay enable investigators to avoid confounding chemistry-based associations and reporting biases in FAE

128 Herein, we report a coordination chemistry-based strategy for the surface functionalizati

129 nal structures in nature and in the world of chemistry because interactions between molecules of the

130 assess the effects of floods on streamwater chemistry because of challenges collecting samples and t

131 Fundamental physics and chemistry behind these novel transport phenomena on the

132 s in many fields such as mining, solid state chemistry, biochemistry and medical research.

133 sed inhibitors (MBIs) are widely employed in chemistry, biology, and medicine because of their exquis

134 omics", studies of ions in liquids in modern chemistry, biology, and medicine.

135 experiments and for the modeling of glyoxal chemistry both at the interface of water clouds and at a

136 a tool not only in relation to cucurbituril chemistry, but also for the design of novel supramolecul

137 esents evidence that classical d-block redox chemistry can be performed reversibly by f-block metals,

138 ganometallic main group and transition metal chemistry, catalysis, medicinal chemistry and materials

139 io of SOA components, and we used the global chemistry climate model EMAC with the organic aerosol mo

140 studying how the principles of mechanics and chemistry combine to drive morphogenetic pattern formati

141 available to the computational and medicinal chemistry communities.

142 ies show that adjusting the dispersing fluid chemistry could have significant impact on material surv

143 In fundamental physical chemistry, Criegee intermediates have unique and interes

144 The chemistry described in this report provides a platform f

145 (MSP) is a unique enzyme that exhibits dual chemistry determined solely by the identity of the dival

146 mples to decouple the electronic and surface chemistry effects on catalytic performance.

147 onal amino acid using copper-catalyzed click chemistry, either before or after the silk fibers are se

148 lize mechanical failure through colorimetric chemistries embedded in the assembled (bulk) protein mat

149 Frustrated Lewis pair (FLP) chemistry enables a rare example of alkyne 1,2-hydrocarb

150 nstrate that application of this conjugation chemistry enables facile labeling of bacteria.

151 Dynamic covalent chemistry enables self-assembly of reactive building blo

152 as a promising precursor, the new synthetic chemistry enables the creation of well-dispersed atomic

153 current end-point of an extensive medicinal chemistry endeavor that spans almost three decades.

154 toxidation is now competing with bimolecular chemistry even in the most polluted North American citie

155 se robots can support a range of science and chemistry experiments for education and even research.

156 Through medicinal chemistry exploration, we established a robust structure

157 ) has been designed, employing dynamic imine chemistry followed by imine bond reduction.

158 of host tree mortality from changes in soil chemistry following tree death.

159 This work greatly expands doping chemistry for tailoring the structures of nanoclusters a

160 Ignoring secondary chemistry from diesel exhaust would lead to underestimat

161 interactions but are incapable of acid-base chemistry, had little effect on either phosphoryl transf

162 n optics, biology, and energy, their surface chemistry has become a topic of intensive research inter

163 Although bromine chemistry has been shown to initiate ozone depletion eve

164 omponent parts, and therefore supramolecular chemistry has developed a highly important role in this

165 Systems chemistry has played a pivotal role in the attempts to u

166 approaches to structural design in materials chemistry have exploited strong directional bonds, whose

167 in algal genetic resources and environmental chemistry have promoted a renewal of interest in the rol

168 Recent results in prebiotic chemistry implicate hydrogen cyanide (HCN) as the source

169 (SO2)O...H(H2O) may incur effects on the SO2 chemistry in atmospheric aerosols because the solvation

170 and the labeling of DNA-Pt by means of click chemistry in cells.

171 se results illustrate the power of synthetic chemistry in elucidating the fundamental mechanisms unde

172 ydrogen bond, herein we focus on the Li bond chemistry in Li-S batteries through sophisticated quantu

173 ides an overview of the use of Computational Chemistry in MAOS to provide a theoretical understanding

174 or expansion of uranium-ligand multiple bond chemistry in recent years, analogous complexes involving

175 cells represents a challenge for analytical chemistry in the context of current biomedical research.

176 ry since the beginnings of chlorin synthetic chemistry in the early 20th century through 2015.

177 o capable of catalyzing metal-dependent dual chemistry in vitro.

178 plexity by exploiting the power of synthetic chemistry, in conjunction with the molecular recognition

179 ches to establishing mechanisms for the dual chemistry, insights into the mechanism based on comparis

180 luding seawater pH, pCO2, temperature, redox chemistry, irradiance and nutrient availability.

181 Optimum surface chemistry is a key consideration to modulate the formati

182 tive oxidant used by CmlI to facilitate this chemistry is a peroxo-diferric intermediate (CmlI(P)).

183 sion, the LepNP85 with optimized conjugation chemistry is a promising candidate for treatment of obes

184 of nanobody-based reagents in bioanalytical chemistry is demonstrated.

185 chain transfer (RAFT)-based dynamic covalent chemistry is incorporated into liquid crystalline networ

186 r actinides, yet the origin of this shift in chemistry is not understood.

187 e host for unveiling the challenging surface chemistry issue in Li-S batteries.

188 ysis has become an important tool in organic chemistry, its combination with supramolecular host syst

189 start new Np-capable air-sensitive inorganic chemistry laboratories, the importance of radioactivity,

190 re-based drug design, and parallel medicinal chemistry led to the identification of pyridine 12.

191 tinued extraction of data from the medicinal chemistry literature, new sources of bioactivity data ha

192 ployed to date in Microwave-Assisted Organic Chemistry (MAOS) are characterized by the importance of

193 It is currently a grand challenge of chemistry, materials science, and engineering to underst

194 unds include organic synthesis, bioinorganic chemistry, materials science, and industrial catalysis.

195 nd it has long been hypothesized that iodine chemistry may contribute, no previous measurements of mo

196 electrostatic assumptions within the surface chemistry model and provide a strong constraint on furth

197 Using a fully coupled meteorology-chemistry model, we find that increased aerosol loading

198 combined with molecular dynamics and quantum chemistry models were used to directly quantify DMSO/wat

199 here we demonstrate the Leidenfrost dynamic chemistry occurring in an underwater overheated confined

200 th investigations of the kinetics of aqueous chemistry occurring in microdroplet environments require

201 ayer combinations are limited by the crystal chemistries of the available anions.

202 ere performed to investigate the atmospheric chemistry of (CF3)2CFCN, a proposed replacement compound

203 Here, the chemistry of 9 mechanistically distinct methods for radi

204 better understand boundary phase growth, the chemistry of a single boundary and its associated second

205 an electron-withdrawing group on the organic chemistry of an eta(2)-bound benzene ring are explored u

206 The dual chemistry of ARD was originally discovered in the bacter

207 rmediates, specifically the physical organic chemistry of carbenes and carbocations.

208 rojected to bring about sharp changes in the chemistry of coastal upwelling ecosystems.

209 ss toward controlling the shapes and surface chemistry of colloidal nanoparticles, spatial control of

210 spheric chemistry, as well as the detonation chemistry of high-energy density materials.

211 s of porous graphitic carbons with the redox chemistry of iodine to produce iodine-carbon batteries w

212 The redox chemistry of magnesium and its application in rechargeab

213 In this review we concentrate on the chemistry of MOFs.

214 findings expand the biological coordination chemistry of Ni(II)-chelating proteins in nature and pro

215 By harnessing the one-electron chemistry of photoredox catalysis in tandem with low-val

216 In the physical chemistry of polar liquids, systems that evade mean fiel

217 A brief summary of the chemistry of polydopamine, particularly as it may pertai

218 The chemistry of sapphyrins has been well-established in rec

219 d have yielded fundamental insights into the chemistry of the Archean environment and evolutionary or

220 ver, one area yet to be explored is the base chemistry of the associated RNA molecules.

221 Simulating the volcano-induced dynamic chemistry of the deep ocean, here we demonstrate the Lei

222 Inspired by the remarkable chemistry of the family of Rieske oxygenase enzymes, non

223 By controlling the surface chemistry of the substrate, we produce large area two-di

224 reaction conditions could enable the systems chemistry of the three classes of (pre)biologically rele

225 tive elimination/oxidation addition reaction chemistry of transition metal catalysts.

226 and rivers modulating the influence of leaf chemistry on breakdown.

227 his discovery paved the way for carrying out chemistry on frameworks without losing their porosity or

228 Further medicinal chemistry on the compounds' basic scaffold could enhance

229 ful approach to guide this type of medicinal chemistry optimization once it has been validated for th

230 Medicinal chemistry optimization resulted in 83, an orally bioavai

231 plications in the area of host-guest organic chemistry, or to spectroscopically evaluate in-depth the

232 The blood chemistry panel and the comprehensive blood analysis sho

233 We demonstrate high-performance assay chemistry performed at microfluidic volumes on Au pads d

234 working in different research fields such as chemistry, physics, or materials science, to mention a f

235 tabolites can represent innovative medicinal chemistry possibilities toward the identification of nov

236 The material chemistry, presentation, environmental conditions and te

237 Here we describe a medicinal chemistry program starting from amicarbalide that led to

238 CB2R), raised the interest of many medicinal chemistry programs for its therapeutic relevance in seve

239 Chemistry quickly moves from a molecular science to a sy

240 meters for enzyme conformational changes and chemistry (rate constants and activation enthalpy).

241 ecular oxygen, and thereby generating Fenton chemistry reagents.

242 les, spatial control of nanoparticle surface chemistry remains a major challenge.

243 This chemistry remains speculative due to a lack of detailed

244 Most next-generation Li ion battery chemistries require a functioning lithium metal (Li) ano

245 Judicious selection of mixers based on the chemistry requirement and real-time monitoring of the pr

246 ons in advancing manufacturing, biology, and chemistry research at the microscale.

247 Computational chemistry research into reaction intermediates and pathw

248 ology (PAT) enabled stable and scalable flow chemistry runs.

249 the analysis and design of complex synthetic chemistry schemes.

250 The dynamic underwater chemistry seen in nature is inspiring for the next gener

251 tep, with that of transition-metal-catalyzed chemistry (selective beta-hydrogen elimination step).

252 nd does not result from iron-mediated Fenton chemistry, since cells remain sensitive to Mn during ana

253 w that prior to ligation, differences in end chemistry strongly modulate the bridging of broken ends

254 Furthermore, a post-chemistry structure of hPolbeta in the open conformation

255 rature as well as biological and atmospheric chemistry studies.

256 rystallise, and so candidate network-forming chemistries such as amide that are irreversible under co

257 ing between internal energy and dissociation chemistry, such non-Boltzmann effects can influence the

258 As a complement to the chemistry surrounding the loading, extension, and offloa

259 New convenient wet-chemistry synthetic routes have made it possible to expl

260 We employ standard quantum chemistry techniques to describe kinetic and mechanistic

261 of RNA splicing, transcription, and protein chemistry techniques, we show that these molecules direc

262 lenges remain in this area, however, and new chemistries that will facilitate fast, simple nucleic ac

263 Here, we present an overview of the unique chemistry that cyanobacteria have been co-opted to perfo

264 This report describes chemistry that is broadly applicable to cysteine-rich pe

265 onditions was caused by changes in gas-phase chemistry that led to the formation of organonitrate com

266 In this work, a distinct battery chemistry that prevails in water-contaminated aprotic li

267 Here we report a battery chemistry that utilizes magnesium monochloride cations i

268 With the advent of reversible covalent chemistry the study of the interplay between covalent bo

269 cannot be synthesized via classical organic chemistry the triplet non-aromatic 2,4,6-cyclooctatriene

270 re multistep and generally based on the SNAr-chemistry; their applicability is significantly limited

271 kit pioneered by the field of supramolecular chemistry, thereby permitting the bottom-up engineering

272 latin a metallodrug based on Pt coordination chemistry, these species may help to overcome the proble

273 Taking the case of organocerium(iv) chemistry, this Tutorial Review also tries to exemplaril

274 Olefin chemistry, through pericyclic reactions, polymerizations

275 ivity and extend this aryl functionalization chemistry to a selected set of heteroaromatic systems co

276 articular of the excited states that connect chemistry to biological function.

277 accharide monooxygenases (LPMO10s) use redox chemistry to cleave glycosidic bonds in the two foremost

278 Here, we describe the use of side-group chemistry to control the properties of a single-molecule

279 e absorption spectroscopy as well as quantum chemistry to determine molecular and electronic structur

280 ification of PG can be extended to use click chemistry to fluorescently label the mature PG in whole

281 lization through perfluoroaryl-cysteine SNAr chemistry to improve the ability of peptides to cross th

282 bly switched from predominantly thio-Michael chemistry to predominantly disulfide chemistry, as well

283 We expand the photoactivatable chemistry toolbox here with a second reagent, sulfo-SBP

284 of biosensing, bioprocessing, and analytical chemistry tools.

285 mer extension could illuminate how prebiotic chemistry transitioned to biology.

286 scaffolds was synthesized by means of click-chemistry under non-conventional microwave heating and e

287 The diDO-IPTL labeling chemistry uses only high-purity, relatively inexpensive

288 The change in local surface chemistry via formation of surface oxygen related defect

289 Reductive amination chemistry was used to synthesize all possible 3-mer sequ

290 tructure and dynamics through tuning surface chemistry, we found that as the conformational and trans

291 the main effects of metamorphosis on insect chemistry were large declines in zinc concentrations cou

292 rticipation of graphene in electron transfer chemistry, where an electron is transferred between grap

293 the Ray-Dutt twist of classical coordination chemistry, which we call the pterin twist hypothesis.

294 ign opportunities afforded by supramolecular chemistry will play a vital role in the future of the dr

295 ological functions such as expanding protein chemistries with noncanonical amino acids (ncAAs) and ge

296 er with text mining applications for linking chemistry with biological information are also presented

297 Here we couple records of ocean redox chemistry with nitrogen isotope ((15)N/(14)N) values fro

298 entized residuals are standard in analytical chemistry with spectroscopic data.

299 Combining bioorthogonal chemistry with the use of proteins engineered with adhes

300 ric method to understand the in situ battery chemistry without any further sample processing, which c