ライフサイエンスコーパス: agrochemical

1 gically active products (drugs, flavors, and agrochemicals).

2 inability of this valuable once-in-a-century agrochemical.

3 are in high demand to replace the synthetic agrochemicals.

4 ased role in the area of pharmaceuticals and agrochemicals.

5 re efficient preparation of therapeutics and agrochemicals.

6 application of nanocontaining biosolids and agrochemicals.

7 lower toxicological risks than conventional agrochemicals.

8 anic soybean batches contained none of these agrochemicals.

9 nform the sustainable design of nano-enabled agrochemicals.

10 anism is a desirable attribute for new safer agrochemicals.

11 s are relevant motifs in pharmaceuticals and agrochemicals.

12 ounds including valuable pharmaceuticals and agrochemicals.

13 e trifluoromethylthiolation of medicines and agrochemicals.

14 n, nutrient pollution and the application of agrochemicals.

15 the synthesis of pharmaceuticals, dyes, and agrochemicals.

16 rged as important alternatives to the use of agrochemicals.

17 ots can accurately identify and characterize agrochemicals.

18 cycles in small-molecule pharmaceuticals and agrochemicals.

19 egy to synthesize various drug molecules and agrochemicals.

20 ter for the synthesis of pharmaceuticals and agrochemicals.

21 crop productivity and increasing reliance on agrochemicals.

22 future demands for medicines, materials, and agrochemicals.

23 onal group found in both pharmaceuticals and agrochemicals.

24 at are commonly found in pharmaceuticals and agrochemicals.

25 ly in the development of novel therapies and agrochemicals.

26 l impact as pharmaceuticals, mycotoxins, and agrochemicals.

27 moiety characterization of 14 singly charged agrochemicals.

28 at controlling the release of water-soluble agrochemicals.

29 uctures are prevalent in pharmaceuticals and agrochemicals.

30 marked by an imperative to reduce the use of agrochemicals.

31 ely in bioactive natural products, drugs and agrochemicals.

32 noids offer potential as pharmaceuticals and agrochemicals.

33 DMS to analyze the mixture of singly charged agrochemicals.

34 e in different products, including foods and agrochemicals.

35 activated dissociation (CAD) on a series of agrochemicals.

36 r applications in the discovery of drugs and agrochemicals.

37 h are commonly found in medicinal agents and agrochemicals.

38 evaluating the fate of this class of "inert" agrochemicals.

39 ed when evaluating the environmental fate of agrochemicals.

40 that provides access to bioactive drugs and agrochemicals.

41 of bioactive compounds, pharmaceuticals, and agrochemicals.

42 s, biologically active compounds, drugs, and agrochemicals.

43 ous in natural products, pharmaceuticals and agrochemicals.

44 cal control agent (BCA) to reduce the use of agrochemicals.

45 bility to induce adaptive responses to novel agrochemicals?

46 eomers are ubiquitous in pharmaceuticals and agrochemicals(1), yet their preparation often relies on

47 rings are ubiquitous in pharmaceuticals and agrochemicals(1).

48 overy and manufacture of pharmaceuticals and agrochemicals(1,2).

49 mined half-lives for 52 structurally diverse agrochemical active ingredients in batch reactors with t

50 lds for the design of new pharmaceutical and agrochemical active ingredients.

51 n of the parameter space of organophosphorus agrochemical adsorption in zirconium-based MOFs.

52 ion of how the properties of nanocarriers of agrochemicals affect their uptake and translocation in p

53 f tertiary alkylamines in pharmaceutical and agrochemical agents, natural products and small-molecule

54 s for the construction of pharmaceutical and agrochemical agents.

55 roductivity, optimize and automate water and agrochemical allocation, and enable high-throughput plan

56 -Oxoglutarate (2OG) oxygenases are validated agrochemical and human drug targets.

57 as saturated bioisosteres in pharmaceutical, agrochemical and materials chemistry.

58 of unsymmetrical biaryls of pharmaceutical, agrochemical and optoelectronic importance with green sc

59 Fluorine is a key element present in ~35% of agrochemicals and 25% of marketed pharmaceutical drugs.

60 and industrial sectors to synthesize drugs, agrochemicals and biologically active and advanced mater

61 resent in a large number of pharmaceuticals, agrochemicals and biomolecules, and play vital roles in

62 thesis of amines as well as pharmaceuticals, agrochemicals and biomolecules.

63 s offer the opportunity to precisely deliver agrochemicals and continuously monitor plant health, wit

64 with applications spanning pharmaceuticals, agrochemicals and functional materials.

65 esterases hydrolyze many pharmaceuticals and agrochemicals and have broad substrate selectivity, requ

66 with applications that span pharmaceuticals, agrochemicals and high-tech materials.

67 tance, with applications in pharmaceuticals, agrochemicals and materials products.

68 s important applications in pharmaceuticals, agrochemicals and materials, but all these applications

69 nd due to their presence in pharmaceuticals, agrochemicals and materials.

70 earance of these functional groups in drugs, agrochemicals and natural products justifies a separate

71 common functional groups in pharmaceuticals, agrochemicals and natural products.

72 mpounds are widely found in pharmaceuticals, agrochemicals and organic materials.

73 Screening agrochemicals and pharmaceuticals for potential liver to

74 able interest in incorporating fluorine into agrochemicals and pharmaceuticals to improve their biolo

75 ding refrigeration, electric transportation, agrochemicals and pharmaceuticals, are prepared from flu

76 des a flexible approach for the synthesis of agrochemicals and pharmaceuticals, as demonstrated by a

77 used in the production of polymers, paints, agrochemicals and pharmaceuticals.

78 egically important in the development of new agrochemicals and pharmaceuticals.

79 nage commodities, high-value fine chemicals, agrochemicals and pharmaceuticals: but oxidations are of

80 ause of their prevalence in pharmaceuticals, agrochemicals and synthetic building blocks.

81 selectivity was evaluated using a variety of agrochemicals and the main trifloxystrobin metabolite.

82 the structure of active ingredients, such as agrochemicals and their associated metabolites, is a cru

83 ention should be paid to Ar-CF(3) containing agrochemicals and their TPs.

84 thylsulfinyl moiety that is unique among the agrochemicals and therefore presumably important in its

85 240 hour (10 day) exposures to examine seven agrochemicals and trace environmental pollutant toxiciti

86 organofluorine compounds in pharmaceutical, agrochemical, and material chemistry, the development of

87 playing an emerging role in pharmaceutical, agrochemical, and materials chemistry.

88 ompounds of interest for the pharmaceutical, agrochemical, and materials industries.

89 tructing value-added molecules of medicinal, agrochemical, and materials interest.

90 entific endeavors, including pharmaceutical, agrochemical, and materials research.

91 yl groups are of interest in pharmaceutical, agrochemical, and materials science research, due to the

92 roducing thioethers used in pharmaceuticals, agrochemicals, and advanced materials, remains significa

93 elevant to the synthesis of pharmaceuticals, agrochemicals, and advanced materials.

94 tal in natural products, pharmaceuticals and agrochemicals, and as key building blocks for various ap

95 acophoric scaffolds found in marketed drugs, agrochemicals, and biologically active molecules.

96 Ring systems in pharmaceuticals, agrochemicals, and dyes are ubiquitous chemical motifs.

97 l in various fields such as pharmaceuticals, agrochemicals, and environmental science.

98 re key functional groups in pharmaceuticals, agrochemicals, and functional materials, as well as in b

99 e increasingly prevalent in pharmaceuticals, agrochemicals, and functional materials.

100 broad range of advanced materials, polymers, agrochemicals, and increasingly for pharmaceuticals.

101 cause of its application to pharmaceuticals, agrochemicals, and late-stage functionalization reaction

102 ing blocks for synthesizing pharmaceuticals, agrochemicals, and ligands for metal complexes, but stra

103 enoid rings, which occur in pharmaceuticals, agrochemicals, and liquid crystals.

104 in the synthesis of C(sp(3))-rich medicines, agrochemicals, and material chemistry.

105 with useful applications in pharmaceuticals, agrochemicals, and materials chemistry.

106 ion has direct applications in pharmacology, agrochemicals, and materials science, demonstrating its

107 erocycles that are widely used in medicines, agrochemicals, and materials science.

108 s in various fields such as pharmaceuticals, agrochemicals, and materials science.

109 istry, with applications in pharmaceuticals, agrochemicals, and materials science.

110 bility-that are valuable in pharmaceuticals, agrochemicals, and materials science.

111 ues to drive innovations in pharmaceuticals, agrochemicals, and materials science.

112 es are ubiquitous motifs in pharmaceuticals, agrochemicals, and materials, yet direct access to regio

113 at are used in pharmaceuticals, diagnostics, agrochemicals, and materials.

114 terocycles are prevalent in pharmaceuticals, agrochemicals, and materials.

115 more structurally elaborate pharmaceuticals, agrochemicals, and materials.

116 rtance of aryl fluorides in pharmaceuticals, agrochemicals, and materials.

117 omatics are key elements of pharmaceuticals, agrochemicals, and materials.

118 role in materials science, pharmaceuticals, agrochemicals, and medical imaging.

119 enes feature prominently in pharmaceuticals, agrochemicals, and natural products.

120 ructural motifs in numerous pharmaceuticals, agrochemicals, and natural products.

121 lony failure, including pests and pathogens, agrochemicals, and nutritional stressors.

122 Ar(2)) are common motifs in pharmaceuticals, agrochemicals, and organic materials.

123 e common building blocks in pharmaceuticals, agrochemicals, and organic materials.

124 e core structure of many therapeutic agents, agrochemicals, and organic materials.

125 streamline the synthesis of pharmaceuticals, agrochemicals, and other complex organic molecules.

126 formation products of dyes, pharmaceuticals, agrochemicals, and other compound classes.

127 cts have applications as biopharmaceuticals, agrochemicals, and other high-value chemicals.

128 s which have application in pharmaceuticals, agrochemicals, and other important fields.

129 tive natural products, functional materials, agrochemicals, and pharmaceutically active compounds.

130 tial skeleton ubiquitously found in ligands, agrochemicals, and pharmaceuticals.

131 including the production of pharmaceuticals, agrochemicals, and plasticizers.

132 rganic molecules, including pharmaceuticals, agrochemicals, and polymer precursors.

133 e material sciences, and as pharmaceuticals, agrochemicals, and sensors.

134 bees are chronically exposed to cocktails of agrochemicals, and they are simultaneously exposed to no

135 id the development of new pharmaceutical and agrochemical antifungals.

136 odel used to determine biomass growth rates, agrochemical application rates, and other key parameters

137 with modern agriculture practices including agrochemicals application.

138 ctive small molecules for pharmaceutical and agrochemical applications have also arrived at a similar

139 rticular those related to pharmaceutical and agrochemical applications, the knowledge of potential de

140 molecules with important pharmaceutical and agrochemical applications.

141 l synthon for pharmaceutical, materials, and agrochemical applications.

142 er, the environmental effects of these novel agrochemicals are not fully characterized, and more rese

143 at conversion, climate change, or the use of agrochemicals, are changing the world bees inhabit, and

144 In the course of our research in the agrochemical area, we have concluded that in many cases

145 owing uses and applications in medicinal and agrochemical arenas prompt the researchers for further s

146 ide application in pharmaceutical as well as agrochemical arenas.

147 d to the modification of pharmaceuticals and agrochemicals as well as the one-pot diversified synthes

148 as active ingredients of pharmaceuticals and agrochemicals, as catalysts, and in materials sciences.

149 ysis of the drugs cocaine and oxycodone, the agrochemicals atrazine and azoxystrobin, and the explosi

150 ly common substituent in pharmaceuticals and agrochemicals because it improves the bioavailability an

151 N-Cyano amides are pivotal in agrochemicals, biologically active compounds, and nitrog

152 important as materials, pharmaceuticals, and agrochemicals, but their synthesis by simple, mild, labo

153 xamide, which demonstrates that an important agrochemical can be synthesized directly from N(2) and C

154 e the physicochemical properties of drug and agrochemical candidates, are limited.

155 ns (microbial products, allelochemicals, and agrochemicals), cell survival is contingent on mechanism

156 In the pursuit of new pharmaceuticals and agrochemicals, chemists in the life science industry req

157 In contrast, agrochemical companies argue that neonicotinoids do not

158 ons with past and present pharmaceutical and agrochemical companies.

159 rage (7900 kg ha(-1)), with 25% to 99% lower agrochemical contamination risk and similar nitrogen use

160 ility to improve uptake and translocation of agrochemicals, control release, or target specific tissu

161 eceptor that can be activated by an existing agrochemical could achieve this goal.

162 organic synthesis, pharmaceutical discovery agrochemical crop protection and materials chemistry, ne

163 ganic and organic NDVs have been studied for agrochemical delivery in the literature, but research on

164 es, enabling the tentative identification of agrochemical derivatives and other unknowns in the envir

165 he binding site can be exploited in rational agrochemical design.

166 ethyl (CF(2)H) groups, and the same trend in agrochemical development shows that the effect of fluoro

167 oisotopes are integral to pharmaceutical and agrochemical development.

168 n pharmaceutical research, biocatalysis, and agrochemical development.

169 he active ingredients in pharmaceuticals and agrochemicals directly from simple feedstocks.

170 o their applications in medicinal chemistry, agrochemical discovery, and academic research.

171 sought-after moieties in pharmaceutical and agrochemical discovery.

172 from hives in agricultural sites had greater agrochemical diversity and in general higher pesticide h

173 sential building blocks for the synthesis of agrochemicals, drugs, and organic materials, yet their s

174 -free Arctic, and intensified application of agrochemicals due to higher crop production and poleward

175 ermediates for synthesizing pharmaceuticals, agrochemicals, dyes, and explosives, which necessitates

176 e products that are used as pharmaceuticals, agrochemicals, dyes, polymers and other fine chemicals.

177 o be promising through the use of registered agrochemicals (e.g. RH5992) as inducers.

178 sful with compounds including those in inks, agrochemicals, explosives, and animal tissues.

179 that assume additive effects of the risk of agrochemical exposure may underestimate the interactive

180 Given the interest in the sensory impacts of agrochemical exposure on wild insect behavior and physio

181 ble pesticide tolerance, buffering them from agrochemical exposure.

182 t-centered, eco-conscious pharmaceutical and agrochemical facilities of the future.

183 posed to a complex mixture of many different agrochemicals, few studies have surveyed toxic effects o

184 Here we evaluated the use of ToF-SIMS in the agrochemical field, which remains a largely unexplored a

185 Thus, we have successfully repurposed an agrochemical for a new application using receptor engine

186 ll as both naturally occurring and synthetic agrochemicals (for example, permethrin 2)(5,6).

187 are briefly evaluated as a dispersant for an agrochemical formulation based on a broad-spectrum fungi

188 s, epicuticular waxes, and the deposition of agrochemical formulations onto the leaf surface.

189 ing pharmaceutical agents, natural products, agrochemicals, fragrances and petroleum products-the phy

190 Agrochemicals frequently undergo various chemical and me

191 Misuse of agrochemicals has a long-lasting negative impact on aqua

192 in the environment, due to their wide use as agrochemicals, has become a serious environmental proble

193 for a considerable proportion of wildly used agrochemicals; however, whether and how their enantiomer

194 the detection and confirmation of traces of agrochemicals in actual market-purchased samples.

195 Analysis of agrochemicals in an environmental matrix is challenging

196 ith MS/MS detection for fast quantitation of agrochemicals in food and water samples was demonstrated

197 ve and quantitative (ultra)trace analysis of agrochemicals in foodstuffs.

198 ination of atrazine and phosphate--principal agrochemicals in global corn and sorghum production--acc

199 research has reported increased tolerance to agrochemicals in target and nontarget organisms followin

200 The use of agrochemicals in vegetable production could influence th

201 ta supported a causal mechanism whereby both agrochemicals increase exposure and susceptibility to la

202 ls science as well as the pharmaceutical and agrochemical industries and yet are often difficult to a

203 are pervasive within the pharmaceutical and agrochemical industries due to the range of structural a

204 complex molecules in the pharmaceutical and agrochemical industries requires precise control over ea

205 r-increasing demands on the agricultural and agrochemical industries to increase agricultural yields.

206 ely used processes in the pharmaceutical and agrochemical industries(1-4), allowing convergent assemb

207 igh demand, both from the pharmaceutical and agrochemical industries, for the preparation of bulk dru

208 of their broad use in the pharmaceutical and agrochemical industries.

209 tal toxicology through to pharmaceutical and agrochemical industries.

210 pounds, especially in the pharmaceutical and agrochemical industries.

211 reasing importance in the pharmaceutical and agrochemical industries.

212 at are used widely in the pharmaceutical and agrochemical industries.

213 of high interest for the pharmaceutical and agrochemical industries.

214 of significant interest to the medicinal and agrochemical industries.

215 n to discovery efforts in pharmaceutical and agrochemical industries.

216 In chronic feeding assays, the common agrochemical inert formulant N-methyl-2-pyrrolidone (NMP

217 s challenges their classification as "inert" agrochemical ingredients.

218 s where ecosystem services are maximised and agrochemical inputs can be reduced.

219 wheat cultivars combined with high levels of agrochemical inputs during the green revolution resulted

220 es plant response in a way that can minimize agrochemical inputs to the environment and therefore cou

221 reen revolution trebled grain yields through agrochemical intensification of monocultures.

222 motifs in many products of pharmaceutical or agrochemical interest.

223 s enables the concise synthesis of important agrochemical intermediates which were previously prepare

224 feedyard particulate matter (PM) transports agrochemicals into the surrounding environs.

225 stainless steel (SS) for precise delivery of agrochemicals into vascular bundles of plant tissue.

226 Nanoformulation of agrochemicals is an attractive approach to enable the se

227 e, materials science, consumer products, and agrochemicals is driving efforts to engineer new biosynt

228 hesis of fine chemicals, pharmaceuticals and agrochemicals is often overlooked due to its oxophilic,

229 A promising alternative to agrochemicals is the use of plant growth-promoting rhizo

230 nt and selective inhibitors of plant HPPD as agrochemical leads.

231 r than uptake of conventional foliar applied agrochemicals (<5%).

232 amines are ubiquitous in pharmaceuticals and agrochemicals, making their efficient and selective synt

233 Here, we present the use of the agrochemical mandipropamid (Mandi) as a highly efficient

234 that possesses nanomolar sensitivity to the agrochemical mandipropamid and demonstrate its efficacy

235 st time, SHG microscopy was used for imaging agrochemical materials directly on the surface of common

236 m still enabled a variety of measurements of agrochemical materials.

237 In the field, such disruption by agrochemicals may negatively impact bees.

238 man population growth, soil degradation, and agrochemical misuse are significant challenges that agri

239 An incomplete understanding of how agrochemical nanocarrier properties affect their uptake

240 op a route towards a pharmaceutical reagent, agrochemical, natural product, etc.

241 n which bees were exposed to combinations of agrochemicals, nutritional stressors and/or parasites.

242 n be used to monitor spatial distribution of agrochemicals on leaf samples after pesticide applicatio

243 Improved retention and distribution of agrochemicals on plant surfaces is an important attribut

244 Although retention of agrochemicals on plants after spray application can be q

245 ly, a high proportion of pharmaceuticals and agrochemicals on the market today possess halogens.

246 luding LC or GC, the spatial distribution of agrochemicals on the plants surfaces has received little

247 sing their applicability as pharmaceuticals, agrochemicals, or building blocks for organic materials.

248 trated by the modification of several drugs, agrochemicals, peptides, chiral catalysts, polymers and

249 ty genes, thereby benefiting nestmates, many agrochemical pesticides adversely affect bee health even

250 Fluorinated compounds are used for agrochemical, pharmaceutical, and numerous industrial ap

251 hich are key intermediates for manufacturing agrochemicals, pharmaceuticals and dyes.

252 of applications, including the synthesis of agrochemicals, pharmaceuticals, and materials.

253 The product ions of one of the agrochemicals, pirimiphos-methyl, present in the sample

254 Agrochemicals play an important role in maximizing agric

255 Once in the soil, the mobility of these agrochemicals plays an important role in their fate and

256 d use in the preparation of pharmaceuticals, agrochemicals, polymers, and other functional materials.

257 urce of novel compounds with therapeutic and agrochemical potential.

258 pects for the transition to more sustainable agrochemical practices.

259 use in foods, cosmetics, pharmaceuticals and agrochemicals preparations.

260 The antibiotic jinggangmycin (JGM) is an agrochemical product widely used in China for controllin

261 ions were calculated based on pre-farm (e.g. agrochemical production, storage, and transportation), a

262 re key components of many pharmaceutical and agrochemical products(6).

263 tively, and that have important medicinal or agrochemical properties.

264 Boscalid is an agrochemical recently developed for crop protection and

265 onalized azines of direct pharmaceutical and agrochemical relevance.

266 he SRS spectroscopy may find applications in agrochemical research and development or in studies of w

267 hieved by investing in fundamental plant and agrochemical research and in the development of improved

268 (such as chlorophyll), the plant science and agrochemical research communities have not been able to

269 Agrochemical research over the last two decades has resu

270 Cyprodinil is among the most common agrochemical residues found in highly perishable fruits,

271 ironmental pressures, the pharmaceutical and agrochemical sectors must revisit core aspects of proces

272 amides are key motifs in pharmaceuticals and agrochemicals, spurring the continuous development of no

273 r approach to ask how multiple stressors, an agrochemical (sulfoxaflor, a relatively new insecticide)

274 nds, an essential bond in pharmaceutical and agrochemical synthesis, simplifying traditional methods

275 Modern crop production calls for agrochemicals that prime plants for enhanced defense.

276 e male sterility in plants by using existing agrochemicals that would reduce the expense of seed prod

277 clic aromatic hydrocarbon fluoranthene), and agrochemical (the herbicide atrazine).

278 nging because these samples contain multiple agrochemicals, their metabolites, degradation products,

279 Maximizing crop yields relies on the use of agrochemicals to control insect pests.

280 information on the potential contribution of agrochemicals to insecticide resistance in Anopheles mos

281 r challenge and heavily relies on the use of agrochemicals to maximize crop yield.

282 tions in industries ranging from textiles to agrochemicals to pharmaceuticals.

283 o lived in an agricultural area with intense agrochemical usage and who consumed groundwater.

284 eclines have raised concerns over widespread agrochemical usage.

285 Our findings provide a platform to refine agrochemical use and development, conferring future econ

286 t consequences for the spread of crop pests, agrochemical use, and climate change.

287 those from more pristine locations, far from agrochemical use.

288 ions, farm-level diversification and reduced agrochemical use.

289 (NP(EO)n and OP(EO)n) are major toxicants in agrochemicals used around beehives.

290 from Houeyiho and Seme to determine the main agrochemicals used in vegetable production, and the conc

291 ts are approved for clinical, veterinary, or agrochemical uses.

292 In southern California, extensive dumping of agrochemical waste, particularly chlorinated hydrocarbon

293 ides are often used concomitantly with other agrochemicals, we also tested for interactive effects be

294 system relies on higher inputs of synthetic agrochemicals, which may reduce the abundance, diversity

295 en interactions was to find alternatives for agrochemicals, which was triggered after reading the boo

296 e can be applied to the systemic delivery of agrochemicals while conserving the loss of the agrochemi

297 rochemicals while conserving the loss of the agrochemical with increased application efficiency.

298 s spectrometer that can analyze a mixture of agrochemicals without using chromatography or quadrupole

299 to be dominant motifs in pharmaceuticals and agrochemicals, yet they are rare in both nature and comm

300 namides are pervasive in pharmaceuticals and agrochemicals, yet they are typically considered as term