ライフサイエンスコーパス: polyelectrolyte

1 k contacted by the paper crown soaked in the polyelectrolyte.

2 in its active center with negatively charged polyelectrolyte.

3 describing the chaperone as an unstructured polyelectrolyte.

4 e to unintended free wrapping agents such as polyelectrolytes.

5 r deposition of positive or negative charged polyelectrolytes.

6 ontacts via the self-assembly of these doped polyelectrolytes.

7 fabricated using layer-by-layer assembly of polyelectrolytes.

8 stems including nanoparticles, colloids, and polyelectrolytes.

9 rol cell membrane structures with conductive polyelectrolytes.

10 e relationship holds across a broad range of polyelectrolytes.

11 under antifouling phosphorylcholine-grafted polyelectrolytes.

12 environments is competitive with many organo-polyelectrolytes.

13 olymers depends on (inter)diffusion of these polyelectrolytes.

14 Dialysis experiments show that, for a 15 kDa polyelectrolyte, a 50 kDa dialysis membrane is not suffi

15 ricated from two types of optically quenched polyelectrolytes, a life indicator and a death indicator

16 rbing cellulosic fibers, functionalized with polyelectrolytes according to the layer-by-layer method,

17 sensors by inkjet printing the LbL layers of polyelectrolyte and enzyme on paper is demonstrated.

18 n the progress of using conducting polymers, polyelectrolyte and its composites (co-polymer, carbonac

19 Swelling behavior of polyelectrolyte and polyzwitterion brushes derived from

20 ction layers combining pH-neutral conjugated polyelectrolytes and a thin film of ZnO nanoparticles by

21 icrodroplets prepared from cationic peptides/polyelectrolytes and adenosine triphosphate or oligo/pol

22 hrough a layer-by-layer assembly of cationic polyelectrolytes and amplicons.

23 on of polyferrocenylsilane diblock copolymer polyelectrolytes and AOT-based surfactants, is described

24 assembly of metal-containing block-copolymer polyelectrolytes and azobenzene chromophores is exploite

25 by layer-by-layer deposition of proteins and polyelectrolytes and by encapsulating polymers into prot

26 e adverse effects of the deposited polymers, polyelectrolytes and nanoparticles on the cell surface.

27 lecules, mixed cationic-anionic surfactants, polyelectrolytes and other polymers, micropatterned self

28 be feasible in other biosensors based on the polyelectrolytes and sandwiched enzymes providing that a

29 id carriers based on assembled biodegradable polyelectrolytes and sol-gel coating possess several adv

30 ories of the electrostatics of surface-bound polyelectrolytes and the entropy of surface-bound polyme

31 amental insight into the dynamics of charged polyelectrolytes and the solvating water molecules.

32 ectronvolts), by charge-doping of conjugated polyelectrolytes and then internal ion-exchange to give

33 ion polarization (CP) that is induced by the polyelectrolyte, and observed as voltage polarity-depend

34 atechol functionalization of polymers and/or polyelectrolytes, and solution processing of many comple

35 Conjugated polyelectrolyte-antibody hybrid materials promise to enh

36 n is achieved by using a stimulus-responsive polyelectrolyte-aptamer thin film to control the rate of

37 Threose nucleic acid (TNA) and other polyelectrolytes are also considered as the possible fir

38 lt on a silicone sheet and where RGD-grafted polyelectrolytes are embedded under antifouling phosphor

39 hat while nanoparticles prepared with longer polyelectrolytes are more stable under simulated physiol

40 engineering based mainly on the assembly of polyelectrolytes are reviewed.

41 m weak polyelectrolytes shows that when both polyelectrolytes are substantially charged in solution (

42 Polyelectrolytes are used to electrostatically assemble

43 Because excess polyelectrolytes are usually employed in the surface mod

44 By introducing an amphiphilic conjugated polyelectrolyte as an interfacial compatibilizer, fabric

45 -temperature solution-processable conjugated polyelectrolyte as the hole transport layer (instead of

46 are further integrated to construct metallo-polyelectrolytes as anion-exchange membranes in solid-st

47 ating strongly electron-accepting conjugated polyelectrolytes, as demonstrated through the synthesis

48 ess the glass transition temperature (Tg) of polyelectrolyte assemblies at solid-electrolyte interfac

49 ng ratiometric indicators and layer-by-layer polyelectrolyte assembly, the local pH was measured and

50 ombic interactions which support theories of polyelectrolyte association rooted in continuum electros

51 ed by the complexation of oppositely charged polyelectrolytes at the immiscible interface.

52 illustrate that weak bonding interactions in polyelectrolyte-azobenzene surfactant mesophases can be

53 erential capacitance, strongly depend on the polyelectrolyte backbone flexibility and the solvent qua

54 to support Darwinian evolution, including a polyelectrolyte backbone, predictable thermodynamic stab

55 the development of a new class of functional polyelectrolytes based on the aromatic cyclopropenium io

56 of benzyl methacrylate in alcohol using weak polyelectrolyte-based chain transfer agents allows the f

57 an efficient way to produce well-controlled polyelectrolyte-based nanoparticles suitable for colloid

58 nd consider how this may be applied to other polyelectrolyte-based systems as a general method for su

59 ich are ubiquitous in biological systems and polyelectrolyte-based technologies.

60 To date, most cationic polyelectrolytes bear charge formally localized on heter

61 4; 2) high-anionic-content Nanodiscs exhibit polyelectrolyte behavior; 3) 3 mM Ca(2+) neutralizes a c

62 vel underpinnings that distinguish an active polyelectrolyte binder designed for lithium-sulfur batte

63 In this work, a polyelectrolyte binder, SiO2 nanoparticles, and a fluoro

64 Polyelectrolyte binder, SiO2 nanoparticles, and silane o

65 (Rct) of a redox probe diffusing through the polyelectrolyte brush was measured, and the temperature

66 hick fuzzy coat that resembles a two-layered polyelectrolyte brush, which is formed by the unstructur

67 e the glass transition temperature of planar polyelectrolyte brushes at solid-liquid interfaces.

68 significantly better than covalently grafted polyelectrolyte brushes in the presence of multivalent i

69 Unlike polyelectrolyte brushes, the lubrication properties of w

70 charge repulsion is found in weak or strong polyelectrolyte brushes.

71 tforward proposal that counterions bind to a polyelectrolyte by distributing themselves randomly into

72 E, molar mass distribution of evenly charged polyelectrolytes by CGE, and charge density distribution

73 ge density distribution of variously charged polyelectrolytes by free solution CE.

74 We found that a polycationic polyelectrolyte can penetrate through the Au overlayer t

75 These triblock polyelectrolytes can also be used as interfacial layers

76 Further, sulfonium PEG polyelectrolytes can be obtained via alkylation or alkox

77 ow the optomechanical response of conjugated polyelectrolytes can be used to detect their encapsulati

78 The presence of excess polyelectrolyte capping agents in the supernatant of pol

79 lectrokinetics of soft particles: a layer of polyelectrolyte (cationic on one electrode, anionic on t

80 Other nanoparticle polyelectrolyte cations may be anticipated.

81 c conjugated oligo- (2QA-CCOE, 4QA-CCOE) and polyelectrolytes (CCPE), and systematically explored the

82 sing the coupling between the relaxations of polyelectrolyte chains, counterions from the polymer and

83 on-diffusion ranges of positive and negative polyelectrolyte charge lead to a blanket of glassy, stoi

84 ed of SN-AZU, carbon nanotubes, and cationic polyelectrolyte chitosan.

85 ce chemical gradient created by differential polyelectrolyte coating of the paper.

86 this adaptive release system, we applied the polyelectrolyte coating on a well-studied biodegradable

87 sorption of four test proteins on five-layer polyelectrolyte coatings and bare fused silica capillary

88 functionalized with antibody and nanopitted polyelectrolyte coatings to facilitate bacterial adhesio

89 wn in anodized aluminum oxide membranes with polyelectrolyte coatings to modify the surface charge.

90 Living cells interfaced with a range of polyelectrolyte coatings, magnetic and noble metal nanop

91 ygenase was immobilised in the form of solid polyelectrolyte complex gel membrane made of cellulose s

92 The crosslinked matrix is a polyelectrolyte complex made of alginate and polylysine.

93 Polyelectrolyte complex microcapsules are prepared using

94 -HPA) hydrogels and dextran sulfate/chitosan polyelectrolyte complex nanoparticles (PCNs) that delive

95 balanced by counterions-within thin films of polyelectrolyte complex, PEC, using sensitive isotopic l

96 Polyelectrolyte complexation is critical to the formatio

97 -contact microporous adhesive resulting from polyelectrolyte complexation triggered by solvent exchan

98 phase of individual micelles is prevented in polyelectrolyte complexation-driven assembly of triblock

99 tool for manipulating material properties in polyelectrolyte complexation.

100 Polyelectrolyte complexes (PEC) are formed by mixing the

101 Polyelectrolyte complexes are examples of a broader clas

102 ations show how the extreme disorder in such polyelectrolyte complexes facilitates (i) diffusion-limi

103 fewer kinetic limitations on the assembly of polyelectrolyte complexes in all of their forms.

104 Polyelectrolyte complexes present new opportunities for

105 tripolyphosphate (TPP) to produce nano-sized polyelectrolyte complexes with dsRNA.

106 trate that chirality determines the state of polyelectrolyte complexes, formed from mixing dilute sol

107 nalysis was used for the characterization of polyelectrolyte complexes.

108 ermore, we report the finding that synthetic polyelectrolytes composed of an aromatic sulfonic acid b

109 siveness to environmental stimuli by varying polyelectrolyte composition.

110 s were converted into nanosized complexes by polyelectrolyte condensation to manipulate their physico

111 ometry and the hydrodynamic radii of the two polyelectrolyte constituents were determined in a fully

112 ssociation and electrophoretic separation of polyelectrolyte constituents.

113 In addition, this polyelectrolyte could serve successfully as reaction med

114 onstrated for the first time that conjugated polyelectrolytes could be used for G. sulfurreducens bio

115 It is shown that the conjugated polyelectrolyte CPE-K functions as a conductive matrix t

116 y)propyl)piperazin-1-ium bromide] conjugated polyelectrolyte (CPE).

117 chamber BES reactors, by adding a conjugated polyelectrolyte (CPE-K) in the growth medium to co-form

118 Conjugated polyelectrolytes (CPEs) are promising alternatives becau

119 Conjugated polyelectrolytes (CPEs) are versatile materials used in

120 nionic narrow-band-gap self-doped conjugated polyelectrolytes (CPEs) with pi-conjugated cyclopenta-[2

121 their polymer analogues, namely, conjugated polyelectrolytes (CPEs), into synthetic systems with bio

122 esis of ionic small molecules and conjugated polyelectrolytes (CPEs).

123 on of bacteria in the presence of conjugated polyelectrolytes (CPEs).

124 The adsorbed polyelectrolytes create a positive charge on the fiber s

125 l junction) consisting of bilayer conjugated polyelectrolyte, demonstrating an unprecedented PCE of 1

126 ied out to investigate the local dynamics of polyelectrolyte dendrimers dissolved in deuterium oxide

127 d by electrostatic self-assembly of cationic polyelectrolyte dendrimers of different generations and

128 of oppositely charged polyelectrolytes into polyelectrolyte dense (coacervate) and polyelectrolyte d

129 into polyelectrolyte dense (coacervate) and polyelectrolyte dilute (supernatant) phases.

130 ostatic attraction is solely responsible for polyelectrolyte-directed intrafibrillar mineralization.

131 y to establish Gibbs-Donnan equilibrium in a polyelectrolyte-directed mineralization system establish

132 electrostatic potential across the adsorbed polyelectrolyte double layer at the confining surface is

133 lations show the impact is driven by an anti-polyelectrolyte effect from zwitterionic polymers.

134 In paiCDI, the filled polyelectrolyte effectively turns the macropores into a

135 ovide a framework for understanding flexible polyelectrolyte elasticity across a broad range of relat

136 p that connects side chain structure (polar, polyelectrolyte, etc., number of ionic groups per repeat

137 tion is also demonstrated with the developed polyelectrolyte-filled mesopores, which enable a power o

138 a transconductance of 4 mS, in which a thin polyelectrolyte film with mobile sodium ions replaces th

139 nalize the temperature-dependent behavior of polyelectrolyte films in a wide range of settings.

140 mposites formed via impregnation of hydrated polyelectrolyte films with binary water/alcohol solution

141 re crucial components in emerging functional polyelectrolytes for a myriad of applications.

142 rolytes makes these films tend toward weaker polyelectrolyte free volume characteristics.

143 In the case of polyelectrolytes, free-solution capillary electrophoresi

144 Aquivion, a polyelectrolyte from the same family as Nafion, is used

145 imentally guided, multi-phase, multi-species polyelectrolyte gel model to make qualitative prediction

146 RNA to be covalently attached to a swellable polyelectrolyte gel synthesized throughout a biological

147 d by embedding them in a densely crosslinked polyelectrolyte gel, anchoring key labels or biomolecule

148 ical conditions, those prepared with shorter polyelectrolytes have a higher antimicrobial activity.

149 Polyelectrolytes have proven their advantages as draw so

150 hrough the addition of either a like charged polyelectrolyte homopolymer or through careful control o

151 sponsive cryogels can be reproduced in other polyelectrolyte hydrogel systems to fabricate biomimetic

152 ary to the osmotic engine concept based on a polyelectrolyte hydrogel.

153 ronment found in cartilage is achieved using polyelectrolyte hydrogels based on polyvinyl alcohol and

154 prepared from strong polyelectrolytes, weak polyelectrolytes, hydrogen-bonding polymers, and blended

155 = 7.5), the chains pack similarly to strong polyelectrolytes (i.e., lower free volume concentration)

156 The modification of rGO FETs with a weak polyelectrolyte improved the pH response because of its

157 The results revealed that embedding the polyelectrolyte in a conical pore leads to rectification

158 lized to rationalize the complex behavior of polyelectrolytes in aqueous solution.

159 RNAs are one of the most charged polyelectrolytes in nature, and understanding their elec

160 on of the binding strength of surfactants to polyelectrolytes in salt-free mixtures as a function of

161 bottlebrush polymer melts and highly charged polyelectrolytes in solution exhibit correlation peaks i

162 conductive polyelectrolytes, which is termed polyelectrolyte-infiltrated CDI (pie-CDI or paiCDI).

163 lly coated capillary were found to avoid any polyelectrolyte interactions onto the capillary surface.

164 ative phase separation of oppositely charged polyelectrolytes into polyelectrolyte dense (coacervate)

165 The translocation dynamics of polyelectrolytes is of particular interest given potenti

166 tte modified in the tip region with cationic polyelectrolytes is presented with an unpurified PCR pro

167 PCPDTBT-SO(3) K (CPE-K), a conjugated polyelectrolyte, is presented as a mixed conductor mater

168 The binder, a cationic polyelectrolyte, is shown to both facilitate lithium-ion

169 widely employed pair of "linearly" assembled polyelectrolytes it was found that the accepted model of

170 with silver ions and coated with a cationic polyelectrolyte layer form a biodegradable and green alt

171 The first polyelectrolyte layer is inserted through the titania me

172 The polyelectrolyte layer promotes the adhesion of the parti

173 the low-bandgap material after using a thin polyelectrolyte layer to modify the electron-transport Z

174 e PCL fibrous substrate were established via polyelectrolyte layer-by-layer deposition, which was inv

175 nsion, experiments reveal that the number of polyelectrolyte layers, rather than surface wettability

176 sub-millimeter architectures with submicron polyelectrolyte layers.

177 1)) and carboxymethylcellulose (CMC, anionic polyelectrolyte, M.W. 700000 g mol(-1)) on TCE degradati

178 we report the high-resolution deposition of polyelectrolyte macroinitiators and subsequent polymer b

179 ion solutions for films prepared from strong polyelectrolytes makes these films tend toward weaker po

180 sis method, and the reaction affords a novel polyelectrolyte material.

181 y engineered Escherichia coli immobilised in polyelectrolyte membrane onto a miniaturised oxygen elec

182 y due to the unique swelling behavior of the polyelectrolyte membrane.

183 strated the feasibility of using regenerable polyelectrolyte membranes to ultimately control the irre

184 Nanoporous polyelectrolyte membranes with hierarchical and unique p

185 The all-polysaccharide based polyelectrolyte microcapsules combining copigmentation f

186 fluidic approach for one-step fabrication of polyelectrolyte microcapsules in aqueous conditions.

187 plets and use them as templates to fabricate polyelectrolyte microcapsules.

188 observed in cationic surfactant and anionic polyelectrolyte mixtures.

189 Consistent with predictions from polyelectrolyte models, we observed logarithmic dependen

190 antly extending the knowledge of how charged polyelectrolytes modulate ion transport on nano- and mes

191 A polyelectrolyte multilayer (PEM) approach using alginate

192 alation of surfactant self-assemblies in the polyelectrolyte multilayer (PEM) can lead to significant

193 stituted of a Love wave sensor coated with a polyelectrolyte multilayer (PEM).

194 so extended to a more practically applicable polyelectrolyte multilayer adsorbate system.

195 The effective pore size of the polyelectrolyte multilayer decreases with an increase in

196 s technique, we explore issues common to the polyelectrolyte multilayer field, such as the competitio

197 bricated by first generating a highly porous polyelectrolyte multilayer film of poly(acrylic acid) an

198 eory and the mechanism of charge transfer in polyelectrolyte multilayer films (PEM), as well as betwe

199 This mechanoresponsive surface is based on polyelectrolyte multilayer films built on a silicone she

200 Free-standing, stimuli-responsive polyelectrolyte multilayer films enabled by light-induce

201 d evolution of surface charge density during polyelectrolyte multilayer formation.

202 ve to negative polymer repeat units within a polyelectrolyte multilayer made from poly(diallyldimethy

203 oly(ether sulfone) (PES) membranes using the polyelectrolyte multilayer modification method with poly

204 An initial filtration test showed that polyelectrolyte multilayer modified cellulosic fibers ca

205 enhance the understanding of how to control polyelectrolyte multilayer structure, what chemical comp

206 tamide (MPA) of ampicillin was adsorbed into polyelectrolyte multilayer surface coatings composed of

207 These structures are compared with polyelectrolyte multilayers (PEM) thin films having arra

208 sely tuned by using layer-by-layer assembled polyelectrolyte multilayers as spacers.

209 We have employed polyelectrolyte multilayers fabricated using layer-by-la

210 ytes, hydrogen-bonding polymers, and blended polyelectrolyte multilayers have different chain packing

211 yer fabrication of biocompatible, nanoscale 'polyelectrolyte multilayers' (PEMs) on the luminal surfa

212 s, using microneedles coated with releasable polyelectrolyte multilayers.

213 y carbon electrodes, covered with an anionic polyelectrolyte Nafion, and their electrochemical proper

214 to the oppositely charged surface of a model polyelectrolyte, namely, DNA, was characterized by condu

215 ach for the in situ synthesis of metal oxide-polyelectrolyte nanocomposites formed via impregnation o

216 Synthesis of surfactant-polyelectrolyte nanoparticles was carried out in a micro

217 gly on the nature of the solute (small ions, polyelectrolyte, nanoparticles).

218 step-by-step adsorption of various species (polyelectrolytes, nanoparticles, proteins) when the laye

219 highlight the importance of considering the polyelectrolyte nature of the nucleosome and its impact

220 The essential polyelectrolyte nature offers the metallopolymer hydroge

221 ties of two novel narrow band gap conjugated polyelectrolytes (NBGCPEs) based on a poly[2,6-(4,4-bis-

222 l treating the humic particles as an elastic polyelectrolyte network.

223 class-2 mixed-valent triazolylbiferrocenium polyelectrolyte networks (observed inter alia by TEM and

224 ticles such as polymer-grafted nanocolloids, polyelectrolyte networks, cross-linked microgels as well

225 Self-assembling polyelectrolyte non-viral vectors can achieve both steri

226 lly reduces the subsequent adsorption of the polyelectrolytes of a similar charge.

227 plexes (IPECs) are typically formed when two polyelectrolytes of opposite charge are mixed together i

228 d that modifying the NP surface with anionic polyelectrolytes of varying lipophilicity can regulate t

229 and anionic poly(sodium 4-styrenesulfonate) polyelectrolytes on a hydrophobic polyvinylidene fluorid

230 igates the negative effects of free or bound polyelectrolytes on endothelial cell monolayers.

231 m a layer-by-layer self-assembly of the same polyelectrolytes on the same PDMS moulds.

232 deposition shows that the deposition of the polyelectrolyte onto the pore walls increases the net re

233 sequential deposition of alternately charged polyelectrolytes onto a colloidal template.

234 l materials through sequential deposition of polyelectrolytes onto charged nanoparticle cores.

235 y depositing layers of chitosan and alginate polyelectrolytes onto filter paper and physically entrap

236 hitectures of n layered electrolytes E and n polyelectrolytes PE.

237 pore with its surface modified by pH-tunable polyelectrolyte (PE) brushes connecting two large reserv

238 Polyelectrolyte (PE) wrapping of colloidal nanoparticles

239 A novel polyelectrolyte (PE)-modified nanopore, comprising a sol

240 work, a new phosphonium-containing cationic polyelectrolyte (PE1) has been rationally designed and d

241 Polyelectrolytes (PEs) are widely used in applications s

242 hat include anionic citrate and the cationic polyelectrolyte poly(allylamine hydrochloride).

243 (EIS) sensors modified with a cationic weak polyelectrolyte (poly(allylamine hydrochloride) (PAH)) f

244 d on paper in a "wafer"-like bilayer film of polyelectrolytes (Poly (allyl amine hydrochloride/poly(s

245 olecular characteristics that several common polyelectrolytes, poly(acrylic acid) and poly(methylacry

246 amer and a positively charged, water-soluble polyelectrolyte Polydiallyldimethylammonium chloride (PD

247 ct deposition of nanoparticles, coating with polyelectrolytes, polymer assisted assembly of nanomater

248 Polyelectrolyte-porphyrin nanoscale assemblies consistin

249 Calculations based on linear polyelectrolytes rather than base-paired NAs underpredic

250 olymer molecules and extrinsic sites-charged polyelectrolyte repeat units balanced by counterions-wit

251 fusion requires only local rearrangements of polyelectrolyte repeat units, placing far fewer kinetic

252 -lysine as negatively and positively charged polyelectrolytes, respectively.

253 urface occurs irrespective of the charges of polyelectrolytes, resulting in the experimentally verifi

254 ding strength increases as the square of the polyelectrolyte's linear charge density and in proportio

255 The voltammetric label is a hollow polyelectrolyte shell containing approx. 1.0x10(11) Au a

256 These hydrogel beads are surrounded with a polyelectrolyte shell that encloses an enzyme, its encod

257 anocapsules of low soluble anticancer drugs, polyelectrolyte shell thickness controls drug dissolutio

258 These polyelectrolytes show excellent thermal and alkaline sta

259 structures in the presence of extrafibrillar polyelectrolytes show that the outward movement of ions

260 t of solution pH on films prepared from weak polyelectrolytes shows that when both polyelectrolytes a

261 ly influence the double-layer structure of a polyelectrolyte solution confined between two charged su

262 th polymer concentration c (P) in semidilute polyelectrolyte solutions [Formula: see text] The bottle

263 lymers and nanoparticles by mixing them with polyelectrolyte solutions is demonstrated.

264 sent a theory for the collective dynamics of polyelectrolyte solutions with salt by addressing the co

265 a crucial role on the collective dynamics of polyelectrolyte solutions with salt, instead of just the

266 similar to increasing salt concentration in polyelectrolyte solutions.

267 s compartments formed by phase separation of polyelectrolyte solutions.

268 pplied both to characterise synthetic linear polyelectrolytes solutions and to study biomedical sampl

269 This polyelectrolyte structure decouples information content

270 ic solutions through layered electrolyte and polyelectrolyte structures are relevant in a large varie

271 arly natural colorant by copigmented complex-polyelectrolyte structures.

272 ade from bovine serum albumin (BSA) by using polyelectrolytes such as polyethyleneimine (PEI) and pol

273 g of the conformational ensemble of flexible polyelectrolytes, such as single-stranded nucleic acids

274 in the rational design of oppositely charged polyelectrolyte-surfactant formulations for consumer pro

275 hydrated particles of a hexagonally ordered polyelectrolyte-surfactant mesophase based on the electr

276 Oppositely charged polyelectrolyte-surfactant mixtures are ubiquitous in bi

277 bling the prediction of binding strengths in polyelectrolyte-surfactant mixtures based on mesoscale p

278 EIP devices based on a synthesized dendritic polyelectrolyte that enables electrophoretic transport o

279 ells and Human Embrionic Kidney cells on two polyelectrolytes that are widely used as adhesive factor

280 architectures, which are the first class of polyelectrolytes that bear a formal charge on carbon.

281 ope the semiconductor core of pai-conjugated polyelectrolytes that have low electron affinities, thro

282 y simultaneously spraying oppositely charged polyelectrolytes that induce surface precipitation when

283 n the conformational entropy of the confined polyelectrolytes, the Coulombic interaction between the

284 rs of magnitude faster than the diffusion of polyelectrolytes themselves.

285 Biological polyelectrolytes thus have the potential to keep regulat

286 (Wad >/= 2 J m(-2)) of complexed catecholic polyelectrolytes to all tested surfaces including plasti

287 nocrystals are assembled layer by layer with polyelectrolytes to form high-dielectric constant gate i

288 The groundbreaking use of polyelectrolytes to increase the efficiency of supramole

289 The device performance of these polyelectrolytes under highly basic and oxidative enviro

290 oscopy and dynamic light scattering, and the polyelectrolyte uptake determined by chromatographic sep

291 tion in Newtonian, neutral viscoelastic, and polyelectrolyte viscoelastic media to provide a comprehe

292 Polydiallyldimethylammonium chloride (PDDA) polyelectrolyte was complexed with a fluorosurfactant la

293 O3 K, an anionic, narrow-band-gap conjugated polyelectrolyte, was found to be doped after dialysis.

294 Films prepared from strong polyelectrolytes, weak polyelectrolytes, hydrogen-bondin

295 y filling the macropores with ion-conductive polyelectrolytes, which is termed polyelectrolyte-infilt

296 y mixing the solutions of oppositely charged polyelectrolytes, which were hitherto deemed "impossible

297 ins by pyridine affords amphiphilic triblock polyelectrolytes with neutral/charged/neutral or charged

298 Versatile polyelectrolytes with tunable physical properties have t

299 he electroactive bacteria and the conjugated polyelectrolyte work synergistically toward an effective

300 proper postsynthesis purification method for polyelectrolyte-wrapped NPs and reveal that apparent tox