ライフサイエンスコーパス: crystallization

1 be used as model colloidal ions, primed for crystallization.

2 rangoni effect and results in localized salt crystallization.

3 elices as intermediates during the course of crystallization.

4 reaking is typically thought to occur during crystallization.

5 ng temperature (175 degrees C) and inhibited crystallization.

6 ate unsaturated lead sites during perovskite crystallization.

7 ers, and a thiol-containing version promoted crystallization.

8 lipocalin-like protein, PV5, to control heme crystallization.

9 ce the trial-and-error settings required for crystallization.

10 hts the prevalent role of defects in zeolite crystallization.

11 allbladder bile and accelerating cholesterol crystallization.

12 molecules but also enhanced the rate of fat crystallization.

13 d with high thermodynamic driving forces for crystallization.

14 l conductivity variations with the degree of crystallization.

15 strategy for the rationalization of protein crystallization.

16 ase of local structures that somehow prevent crystallization.

17 teady-state configuration before appreciable crystallization.

18 omplex with the remaining heme deprived from crystallization.

19 mille) can occur during magmatic plagioclase crystallization.

20 rate a mixture of benzene and thiophene upon crystallization.

21 oteins that are recalcitrant to conventional crystallization.

22 ges of lunar magma ocean (LMO) or later melt crystallization.

23 were the most effective at delaying sucrose crystallization.

24 in bulk liquids, completely arresting their crystallization.

25 ali or alkaline-earth cations present during crystallization.

26 res 2D layers and markedly slows the rate of crystallization.

27 in solute dimers extant in solution prior to crystallization.

28 on and locally favored structures inhibiting crystallization.

29 ner proteins pose a unique new generation of crystallization additives where the 3D arrangement of mi

30 flow above the carpet that enables complete crystallization after a few seconds of propulsion.

31 croscopy was used to image active ingredient crystallization after solution-phase deposition directly

32 n conjunction with DNA-mediated nanoparticle crystallization, allow for control over individual Wulff

33 lesterol (Fig. 1) serves as a new matrix for crystallization and a crystal delivery medium in the ser

34 wing us to produce sufficient quantities for crystallization and biological assays.

35 a simple means to regulate and sustain batch crystallization and could facilitate the self-assembly o

36 We have previously used two-dimensional (2D) crystallization and electron microscopy to study the int

37 eneous interactions across molecules promote crystallization and favor the spontaneous resolution of

38 show that these adducts inhibit beta-hematin crystallization and heme detoxification, a pathway which

39 a new description of in-membrane cholesterol crystallization and may pave for a screening tool for id

40 ificant asymmetry between the mobilities for crystallization and melting.

41 The impact of confectioner's sugar on the crystallization and rheology of palm oil (PO) and mid-fr

42 ntibodies (bNAbs) PGT124 and 35O22 to aid in crystallization and that are not specific for binding to

43 cooling rate resulted in an earlier onset of crystallization and ultrasonic treatment narrowed the me

44 t was extremely effective at inhibiting drug crystallization, and a less effective, but more hydrophi

45 zation, suggesting that volatile exsolution, crystallization, and cavity generation occur together.

46 tion, templating, pharmaceuticals, colloidal crystallization, and geochemistry.

47 n from epitaxial growth strategies in atomic crystallization, and patterned substrates are prepared t

48 on the enzymatic activity of silicatein, its crystallization, and the emergence of a functional three

49 luding atmosphere loss to space, magma ocean crystallization, and volcanic outgassing).

50 e screening, rational strategies for protein crystallization are crucial.

51 Building blocks of concern to the field of crystallization are the impurities, foreign ingredients

52 The PIZSA potentials can also distinguish crystallization artifacts from biological interactions.

53 erstanding could lead to improved control of crystallization, as well as insight into polymorph selec

54 nd release the energy by optically triggered crystallization at -30 degrees C for the first time.

55 Its microdoleritic texture indicates crystallization at an increasing cooling rate, such as w

56 r, highly unusual for glass-forming systems, crystallization at conventional heating rates is observe

57 he rigor-like conformation with a citrate of crystallization at the nucleotide binding site and exhib

58 as been informed by nonclassical pathways to crystallization, based on biological processes, about th

59 ad a greater affinity for inhibiting CaCO(3) crystallization because it retained the carbonatation cl

60 Our simulations reproduce the experimental crystallization behavior of real chiral molecules, inclu

61 Polymer aggregation and crystallization behavior play a crucial role in the perf

62 llization process and the competition of the crystallization between 3D-like and layered perovskites.

63 f stone formation could be largely due to co-crystallization between melamine and CaP/CaOx and pronou

64 nomalous scattering elements integral to the crystallization buffer (extrinsic cobalt and intrinsic p

65 not only accurately yield the age of zircon crystallization, but also the time of nanosphere formati

66 Rate enhancement of protein crystallization by a discrete nucleation domain may enab

67 sis for 12 weeks inhibited calcium phosphate crystallization by nearly 70%.

68 cle response dynamics governs the process of crystallization by oriented attachment (OA), yet a quant

69 Crystallization by particle attachment (CPA) of amorphou

70 Polyphenol addition delayed sucrose crystallization by up to 6.4x compared to the control.

71 d our understanding of available pathways to crystallization, by showing that size-dependent thermody

72 However, this can be extremely challenging: crystallization can be influenced by subtle changes in e

73 Seeding and ultrasound-assisted pre-crystallization can be used as alternatives to conventio

74 es that self-assemble through the process of crystallization can unravel new molecular ordering with

75 eptides may be useful in challenging protein crystallization cases.

76 betaPro-AMP and Phe-AMP bound to RNase A as crystallization chaperone showed how well the carboxylat

77 Whereas they are known as crystallization chaperones for membrane proteins or as s

78 ranging from diagnostics and therapeutics to crystallization chaperones meant to study protein struct

79 Additionally profound differences in crystallization characteristics are discovered between I

80 We propose that under crystallization conditions a minor population of specifi

81 By exploiting the crystallization conditions for a peripherally extended t

82 nts in different functional forms, different crystallization conditions or as a result of mutations.

83 lt of the LLPS occurring concomitantly under crystallization conditions.

84 polyhedral microcrystals obtained under bulk crystallization conditions.

85 Al(IV)-2 sites result either from framework crystallization defects or from incomplete postsynthetic

86 twork which predicted the stability of honey crystallization depending on Fructose:Glucose and Glucos

87 ic Ocean, where the lithosphere is thickest, crystallization depths of magmas that feed eruptions are

88 The C-terminal crystallization domain forms the physiological 2-dimensi

89 namics with respect to rigid lattice-forming crystallization domains.

90 (PEG) block copolymers capable of undergoing crystallization driven self-assembly via stereocomplex f

91 "Living" crystallization-driven self-assembly (CDSA) is a seeded

92 "Living" crystallization-driven self-assembly (CDSA) is a seeded

93 t on the ring opening polymerization-induced crystallization-driven self-assembly (ROPI-CDSA) of poly

94 d dimensions using the seeded growth "living crystallization-driven self-assembly" method followed by

95 luding polymerization-induced self-assembly, crystallization-driven self-assembly, and bottlebrush po

96 he nanofibres were controlled through living crystallization-driven self-assembly.

97 Crystallization efforts consistently yielded microcrysta

98 such as gel permeation chromatography (GPC), crystallization elution fractionation (CEF), high temper

99 temperatures, the precursor undergoes only a crystallization event to form an intermediate (SnSe(2))(

100 Co-crystallization experiments led to a structure where sub

101 he increase of the water activity of lactose crystallization for camel and bovine whey powders.

102 ublithospheric inclusions results from their crystallization from melts of carbonate-rich subducted o

103 processes in nature and the industry exploit crystallization from multicomponent environments(1-5); h

104 self-nucleation that competes with epitaxial crystallization from seed termini.

105 Elucidating the early stages of crystallization from supersaturated solutions is of crit

106 Structural superposition and co-crystallization further show that TgDelta185 shares a co

107 A dynamic kinetic resolution by crystallization gives high yields of a N-(phenylsulfonyl

108 embrane media follows nonclassical multistep crystallization governed by the heuristic "Ostwald's rul

109 This crystallization has been ascribed to high concentrations

110 hermodynamic and kinetic aspects of acceptor crystallization have received limited attention.

111 During early magma ocean crystallization, high-molecular-weight species usually d

112 that the microorganisms can extract water of crystallization (i.e., structurally ordered) from the ro

113 enable this phenomenon to be used to control crystallization in applications including nanomaterial s

114 ndicate strategies to understand and control crystallization in both natural and engineered systems,

115 They efficiently enable PHD2 crystallization in different forms, both with/without su

116 Most research on ice nucleation (and crystallization in general) has focused on understanding

117 These include crystallization in inverse bicontinuous cubic phases for

118 pens up new opportunities for the control of crystallization in network solids more generally.

119 of organic and inorganic SDAs during zeolite crystallization in order to more efficiently use organic

120 tion between inhibition of calcium phosphate crystallization in plasma and inhibition of CVC both in

121 thers, suggesting a possible role of lactose crystallization in preferential migration of triglycerid

122 an 0.6, but this can vary with the amount of crystallization in solution.

123 miniaturized high-pressure container for the crystallization in solution.

124 nward-facing state, which was obtained after crystallization in the presence of native lipids.

125 systems, the inherent complexity of eutectic crystallization in the presence of trace, often metallic

126 The mechanism of crystallization in this spark plasma sintered iron based

127 molecular mechanisms governing rapid protein crystallization in vivo or in vitro are largely unknown.

128 tein of SARS-CoV-2 (engineered to facilitate crystallization) in complex with ACE2.

129 urface hydroxylation in CSP does not inhibit crystallization; in contrast, by creating a surface comp

130 gnificant chain alignment and strain-induced crystallization indeed occur in this material upon stret

131 and increase polymorphic diversity, based on crystallization induced by suitably designed mixed-cryst

132 ddition, this approach can be coupled with a crystallization-induced diastereoselective transformatio

133 rystals of gold nanoclusters, we investigate crystallization-induced photoluminescence weakening and

134 Crystallization-induced photoluminescence weakening was

135 d the ASD prepared with the highly effective crystallization inhibitor in terms of the amount and rat

136 The ASD formulated with the less effective crystallization inhibitor outperformed the ASD prepared

137 and a less effective, but more hydrophilic, crystallization inhibitor, that might afford better rele

138 ast crystallizing drug, without the use of a crystallization inhibitor.

139 of a series of inositol phosphate analogs as crystallization inhibitors, among which 4,6-di-O-(methox

140 Solution crystallization is a common technique to grow advanced,

141 Crystallization is a ubiquitous means of self-assembly t

142 Pre-crystallization is an important step in the production o

143 Crystallization is fundamental to materials science and

144 ectures, our analysis shows that the ease of crystallization is largely determined by the number of c

145 Yet crystallization is notoriously difficult to control beca

146 The process of crystallization is often understood in terms of the fund

147 Crystallization is the bottleneck in macromolecular crys

148 The key to crystallization is the use of a neutral polymer to keep

149 One of the fundamental laws in crystallization is translational symmetry, which account

150 ences in halogenation can drastically change crystallization kinetics and device stability.

151 ginate (0.5%, w/w) induced water gelation on crystallization kinetics and water and fat proton relaxa

152 Controlling crystallization kinetics is key to overcome the temperat

153 Measurements of crystallization kinetics of Ge(2) Sb(2) Te(5) with heati

154 d's rule of stages", which predicts that the crystallization kinetics proceed down the free energy la

155 the interplay between fluid instability and crystallization kinetics that determines the achievable

156 ces the mobility of atoms and slows down the crystallization kinetics.

157 Inter-relationship between lactose crystallization (LC), the amount and composition of surf

158 Furthermore, heating before crystallization leads to fewer nucleations and faster re

159 Lactose crystallization measured by X-ray diffraction ranged bet

160 In this paper, the crystallization mechanism in spark plasma sintered Fe(48

161 synthesis conditions, we postulate that the crystallization mechanism is governed by the formation o

162 nce of in situ measurements in understanding crystallization mechanisms, where a segmented flow cryst

163 cal and biological phenomena that range from crystallization, melting and evaporation to the formatio

164 A solvent-evaporation-induced crystallization method providing access to large (millim

165 the present review focused on different pre-crystallization methods and factors affecting the proces

166 techniques allowed speculating that the two crystallization methods led to crystals of different siz

167 techniques with a wide range of experimental crystallization methods to understand and explore crysta

168 d the diverse applications of pharmaceutical crystallization, microbatch chemical reactions, and biol

169 we report an effective approach to tune the crystallization, microstructure and charge transport of

170 molecular viewpoint on cooperativity between crystallization modifiers provides guidance on the pairi

171 efficacy of polyphenols in delaying sucrose crystallization, more than T(g) or hygroscopicity.

172 es associated with structural relaxation and crystallization near the glass transition are a major ex

173 eposition of lithium from the stage of metal crystallization nucleation is of vital importance to ach

174 his work studied water state of honey during crystallization, obtained statically and dynamically, by

175 this striking variation in kinetics involves crystallization occurring either from the glassy or from

176 en 20 nanoseconds to 3 microseconds, whereas crystallization occurs on time scales of 3 to 50 microse

177 Upon heating, localized cold crystallization occurs, leading to burst nucleation of m

178 om methylammonium to benzylamine and enables crystallization of 2D perovskite without destroying the

179 We use optical microscopy to investigate the crystallization of a binary colloidal mixture with singl

180 r dynamics computer simulations to study the crystallization of a family of coarse-grained models of

181 3-dimethylpyrazine (2,3-Me(2)pyz) results in crystallization of a new organic antiferroelectric (AFE)

182 The crystallization of a plutonium chain side product provid

183 e structures were an unexpected outcome from crystallization of a racemic peptide corresponding to th

184 The crystallization of amorphous sucrose in food products ca

185 vestigated the effects of polyphenols on the crystallization of amorphous sucrose lyophiles.

186 macrocyclic Abeta-derived peptides promotes crystallization of an Abeta-derived peptide containing t

187 The crystallization of Anti-CD20, a full-length monoclonal a

188 Crystallization of both chimeric and full-length native

189 many marine organisms, biomineralization-the crystallization of calcium-based ionic lattices-demonstr

190 Predicting the crystallization of chiral molecules from solution is a m

191 We find that the three-dimensional (3D) crystallization of cholesterol from an unstable two-dime

192 the effects of emulsifiers on the isothermal crystallization of cocoa butter can be muted in the pres

193 on is one of the prime prerequisites for the crystallization of COFs.

194 pressurization of volatiles exsolved through crystallization of cooling magma stalled beneath the cru

195 ort leads to intralysosomal accumulation and crystallization of cystine.

196 a-gal, respectively) attributed to selective crystallization of disodium hydrogen phosphate as a dode

197 s was evaluated for their ability to inhibit crystallization of enzalutamide, a poorly soluble compou

198 loyed by pairs of inhibitors in blocking the crystallization of haematin, which is a model organic co

199 al bonds and entropic bonds in the colloidal crystallization of hard hexagonal nanoplates.

200 nhance the build-in field (BIF), improve the crystallization of MAPbI(3) , and regulate the nonradiat

201 In meso crystallization of membrane proteins relies on the use o

202 Crystallization of membrane-embedded components within p

203 Control over polymorph formation in the crystallization of organic molecules remains a huge scie

204 ecular hydrogen bonding and facile tuning of crystallization of polymer chains.

205 Iron(II)-catalyzed crystallization of poorly ordered FeOx was negligible, l

206 ever, laboratory efforts have focused on the crystallization of pure solutes(6,7) and the effects of

207 To mitigate the problems of crystallization of raisins during shipping, it is recomm

208 ating the assembly process as entropy-driven crystallization of rigid spherical particles.

209 Here, we present templated crystallization of structural proteins to nanofabricate

210 an that of the wild-type protein, permitting crystallization of the complex.

211 was resolved on a large scale by fractional crystallization of the corresponding (1S)-camphanic este

212 e formed under thermodynamic control by cold crystallization of the hydrazones in the amorphous silox

213 ible light irradiation induced the selective crystallization of the liquid phase via Z-to-E isomeriza

214 s during white-dwarf cooling, leading to the crystallization of the non-degenerate carbon and oxygen

215 Co-crystallization of the parental rabbit mAb in complex wi

216 nted flow crystallizer was used to study the crystallization of the pharmaceuticals urea: barbituric

217 The crystallization of the planar phase is ascribed to the n

218 ement and orientation of AAO channels on the crystallization of the polymer, the polymer nanowire arr

219 The binding mode was confirmed by co-crystallization of the potent azaphenothiazine inhibitor

220 Crystallization of the R2 subunit under such conditions

221 Here, we report crystallizations of Au(22)(SAdm)(16) and Au(22)Cd(1)(SAd

222 lications associated with salt precipitation/crystallization on the scanning (minutes to hours) time

223 A strong dependency of active ingredient crystallization on the substrate was found, with an incr

224 ttice, which we assign to generalized Wigner crystallization on the underlying lattice(6-11).

225 The complete melting temperature, crystallization onset temperature and solid fat index at

226 udied for many applications, such as protein crystallization or drug delivery of proteins for food an

227 unit), and no evidence of either buffer salt crystallization or protein aggregation was observed.

228 ifferent solid forms to prevent uncontrolled crystallization or solid-solid transformation during sto

229 h the nucleation, rotation and amorphization-crystallization oscillations of the Au clusters.

230 We find that this number and, hence, crystallization outcomes depend on molecular interaction

231 d design rules have been devised to engineer crystallization outcomes.

232 ules and experimental conditions for desired crystallization outcomes.

233 dox potential can redirect a non-equilibrium crystallization pathway through different metastable int

234 Complex crystallization pathways are common in protein crystalli

235 investigating the role of magnesium ions in crystallization pathways of amorphous calcium carbonate,

236 article, we observe, characterize, and model crystallization pathways using DNA-coated colloids.

237 n and melting peaks of OSA-starch and a cold-crystallization peak corresponding to the encapsulated n

238 sis for 52 weeks inhibited calcium phosphate crystallization (placebo: 15%; 300 mg: 61%; 600 mg: 75%)

239 Zeolite crystallization predominantly occurs by nonclassical pat

240 trusion of gypsum into membrane pores to the crystallization pressure as a result of rapid, oriented

241 The protein, by inhibiting buffer crystallization, prevented the pH shift and then the buf

242 Control in their crystallization process and growth has been limited to s

243 ration is explained by the surface initiated crystallization process and the competition of the cryst

244 The pre-crystallization process has a great impact on the qualit

245 rough a successive dissolution-precipitation/crystallization process in the presence of magnesium.

246 bimolecular monomer buffering reaction to a crystallization process leads to reliable growth of larg

247 The effect of ultrasound on the crystallization process of cocoa butter was also studied

248 For the development of a robust crystallization process or down-line handling of this co

249 However, the underlying crystallization process, which needs multiple time-consu

250 c reaction rates for better control over the crystallization process.

251 will not only provide superior insight into crystallization processes in many real-world environment

252 Here, the influence of confinement on crystallization processes is described, drawing together

253 nd understanding the mechanisms that harness crystallization processes is of utmost importance in con

254 Many crystallization processes of great importance, including

255 Confinement is also shown to influence crystallization processes over length scales ranging fro

256 ing this rapid initial formation, the entire crystallization processes proceed on considerably longer

257 that exist in crystals and that form during crystallization processes.

258 dictors that can accurately estimate protein crystallization propensities would be highly beneficial

259 In order to understand the Anti-CD20 crystallization propensity in the solvent system of diff

260 he most important features for the predicted crystallization propensity of an individual protein usin

261 sful and failed experiments for studying the crystallization propensity of metal-organic nanocapsules

262 ed neural networks, which is able to predict crystallization propensity with high accuracy.

263 droplet size did not show major influence on crystallization properties.

264 re explainable as artifacts from promiscuous crystallization reagents.

265 the prenucleation phases found in multistep crystallization remain unclear, and models are needed fo

266 ered in a series of seeded and unseeded flow crystallization runs, despite atypical habit expression.

267 elf-assembly" method followed by a secondary crystallization step.

268 This co-crystallization strategy holds considerable promise for

269 iarolitic cavities are shown to exist during crystallization, suggesting that volatile exsolution, cr

270 nfirmed by correlating crystalsome size with crystallization temperature and mBB's side chain graftin

271 y the density of the amorphous matrix at the crystallization temperature T (x) as well as by nanocrys

272 region (between the glass transition and the crystallization temperature) is narrow, resulting in ver

273 n the substrate was found, with an increased crystallization tendency observed on leaves vs on glass

274 ystallization pathways are common in protein crystallization, tetrahedrally coordinated systems, and

275 ttributed to the formation of defects during crystallization that results in uncoordinated hydroxamat

276 o followed in real-time, with differences in crystallization time observed for different application

277 examination of the results demonstrates that crystallization times are significantly affected both by

278 control over such a nonclassical pathway to crystallization to design mineral structures that could

279 RE elements, which has evolved from tedious crystallization to highly engineered solvent extraction

280 ent here reveals the potential of in cellulo crystallization to identify genuine allosteric co-factor

281 However, almost all previous crystallization trials have used monoacylglycerols, with

282 s and conditions that would be scaled up for crystallization trials.

283 unusual range of experiments, including melt crystallization under pressure, to work around solvate f

284 hanism of heme-ART adduct inhibition of heme crystallization, unique among antimalarials and common c

285 decrease in Kissinger activation energy for crystallization upon the glass transition.

286 Observing crystallization using a time course of electron cryo-mic

287 Living cells control crystallization using chemical reaction networks that of

288 ation inhibitor, on plasma calcium phosphate crystallization using spectrometric measurements, and it

289 Crystallization was also followed in real-time, with dif

290 DSC showed that the dynamic crystallization was faster than the static one, the latt

291 cinamic acid derivatives readily enable PHD2 crystallization, we explored methods to induce crystalli

292 a, we propose a general description of p-MOF crystallization which is best characterized by particle

293 dose-dependently inhibited calcium phosphate crystallization, which correlated with inhibition of CVC

294 (eHDA) and VHDA reach the same state before crystallization, which we infer to be the contested high

295 f condensed atomic clusters during Pd and Au crystallizations, which is named a "cluster-cloud." It i

296 a specific methane cage type is crucial for crystallization, while irrelevant for amorphous solids.

297 acile integration of the bottom-up templated crystallization with emerging top-down techniques enable

298 these observations indicate that cholesterol crystallization within the membrane media follows noncla

299 ogical evolution and dynamics of cholesterol crystallization within the membrane media.

300 ystallization, we explored methods to induce crystallization without active site binding.