ライフサイエンスコーパス: polymeric material

1 properties (for example, medicinal agents or polymeric materials).

2 ated in the presence and absence of the wine polymeric material.

3 , all anthocyanins were retained by the wine polymeric material.

4 roducing a uniquely robust and antibody-like polymeric material.

5 desirable chemical/physical properties as a polymeric material.

6 eological properties of this class of unique polymeric material.

7 e successfully maintained in the solid-state polymeric material.

8 on of the polyalkenamer into the synthesized polymeric material.

9 azide-containing monomer into a shape memory polymeric material.

10 ncentration of the analyte of interest using polymeric materials.

11 that enables primary loop quantification in polymeric materials.

12 lead to new design strategies for engineered polymeric materials.

13 es (or other nanoporous molecular sieves) in polymeric materials.

14 ld the highly thermosensitive supramolecular polymeric materials.

15 copper into cotton fibers, latex, and other polymeric materials.

16 osity eta, and other transport properties of polymeric materials.

17 an be extended to other kinds of photoactive polymeric materials.

18 id crystal elastomers (LCEs) are anisotropic polymeric materials.

19 specific molecules attached to biodegradable polymeric materials.

20 refore crucial to enhance electric fields in polymeric materials.

21 case the first force-induced NIR chromism in polymeric materials.

22 merization will afford similar robustness in polymeric materials.

23 nding of the metal center to the amphiphilic polymeric materials.

24 inspiration to the design of optoelectronic polymeric materials.

25 d alternatives to existing petroleum-derived polymeric materials.

26 e functionality of compositionally identical polymeric materials.

27 rials unique among the wider class of porous polymeric materials.

28 ising energy-efficient approach to fabricate polymeric materials.

29 ntier to enhance the properties of these new polymeric materials.

30 ign of diverse autonomous functionalities in polymeric materials.

31 ly(a-hydroxy acids) as ductile and resilient polymeric materials.

32 cyanine generation is also achieved in solid polymeric materials.

33 has recently been on utilizing these DCBs in polymeric materials.

34 d facilitates the production of a variety of polymeric materials.

35 lecular systems, such as diarylethenes, into polymeric materials.

36 he accessible architecture-property space of polymeric materials.

37 e high-performance stereoregular crystalline polymeric materials.

38 and customizing the mechanical properties of polymeric materials.

39 ysical properties of compositionally similar polymeric materials.

40 f inter alia natural products and recyclable polymeric materials.

41 design of solution-processable silicon-based polymeric materials.

42 ned molecular architectures into solid-state polymeric materials.

43 d applications of contact charging involving polymeric materials.

44 venues for fabricating fully recyclable (bio)polymeric materials.

45 such as those with two ionizable lipids and polymeric materials.

46 y and advances the development of recyclable polymeric materials.

47 which will open a new avenue for sustainable polymeric materials.

48 ing candidates for lightweight and strong 2D polymeric materials.

49 s, activation, and fibrotic encapsulation of polymeric materials.

50 w small molecule heterocycles and functional polymeric materials.

51 ture-property relationships of sophisticated polymeric materials.

52 on and programmed obsolescence in structural polymeric materials.

53 used for the synthesis of dimer, triad, and polymeric materials.

54 into proteins and other sequence-programmed polymeric materials.

55 consequences for the physical properties of polymeric materials.

56 l for initiating proton-catalyzed changes in polymeric materials.

57 animals, feeding on chemically diverse plant polymeric materials.

58 cavity, PA-based nanomaterials, and PA-based polymeric materials.

59 erizing in the context of rigid, solid-state polymeric materials.

60 ponsive behavior in mechanochemically active polymeric materials.

61 lecular entities, such as pharmaceuticals or polymeric materials.

62 mance comparable to that of other dielectric polymeric materials.

63 l groups in new classes of stress-responsive polymeric materials.

64 icroscopy was utilized to demonstrate that a polymeric material accumulated at one side of the divisi

65 rocapsules can benefit from the diversity of polymeric materials, allowing for fine control over the

66 ractions that can occur between the red wine polymeric material and anthocyanins were studied.

67 ning structurally coloured, thermoresponsive polymeric materials and advances the rational engineerin

68 possible to control the interactions between polymeric materials and biological systems.

69 However, these technologies involve polymeric materials and can tolerate neither the high-te

70 Photomechanical effects in polymeric materials and composites transduce light into

71 hesion and have inspired countless synthetic polymeric materials and devices.

72 chanical energy for constructive purposes in polymeric materials and for controlled polymerizations f

73 rovide key insights into the SF mechanism in polymeric materials and highlight the role of oligomer l

74 or their ability to enhance the mechanics of polymeric materials and impart biological function.

75 ip can be effectively reduced by using fully polymeric materials and multilayer-detecting structures.

76 n from small molecule organic synthesis into polymeric materials and nanotechnology which led to rece

77 may pave the way for the rational design of polymeric materials and processing routes to enhance dev

78 approach for achieving a performance leap in polymeric materials and provides a complementary approac

79 es to design and fabricate both self-healing polymeric materials and soft actuators with remarkable p

80 150 degrees C, superior to state-of-the-art polymeric materials and surpassing Robeson's upper bound

81 able rapid synthesis and characterization of polymeric materials and the coupling of these processes

82 mation and properties of many biological and polymeric materials, and is typically initiated by aqueo

83 Host polymeric materials, and particularly polymer nanofibers

84 wt% of halloysite increases the strength of polymeric materials, and the possibility of the tube's o

85 Polymeric materials are also challenging owing to the st

86 Such polymeric materials are critical to the development of m

87 Solubility and functionality of polymeric materials are essential properties determining

88 f dehydrogenation, B-N-containing oligomeric/polymeric materials are formed.

89 The ensuing polymeric materials are highly esterified, amorphous, an

90 Synthetic polymeric materials are rapidly replacing more tradition

91 The polymeric materials are soluble and have been characteri

92 Polymeric materials are typically of semi-crystalline na

93 and sustain multiple T(g) values in the same polymeric material as a function of the hydrazone switch

94 the opportunity to impart new properties to polymeric materials as a consequence of using elemental

95 braries of environmentally aged and pristine polymeric materials, as well as unknown environmental pl

96 egy for introducing catecholic moieties into polymeric materials based on a readily available precurs

97 the recent progress in developing different polymeric materials (based on natural polymers and synth

98 Polymeric materials bearing Frustrated Lewis Pair (FLP)

99 ransient nanostructures, e.g., reticular and polymeric materials, being explored by fine-tuning the n

100 erties that qualify them as high-performance polymeric materials, but they still suffer from mechanic

101 the chemical and physical characteristics of polymeric materials by an enzymatic reaction opens the w

102 gies to control the solid-state structure of polymeric materials by appropriate design of the macromo

103 patterning of three-dimensional macroscopic polymeric materials by selective laser sintering.

104 cages, by embedding protein cages into bulk polymeric materials, by forming two- and three-dimension

105 Both microcrystalline and thin films of the polymeric material can be prepared readily and have been

106 Unfortunately, the surfaces of many polymeric materials can adsorb biological samples.

107 Impressively, these robust polymeric materials can be completely depolymerized in a

108 e monomeric building blocks from which novel polymeric materials can be constructed via metal-mediate

109 essary to modify their surfaces before these polymeric materials can be used for separation and analy

110 The intrinsic flexible character of polymeric materials causes remarkable strain deformation

111 of Li-selective ceramic and anion-selective polymeric materials, CMMs offered the unique advantage o

112 Tires are complex polymeric materials composed of rubber elastomers (both

113 We then utilize the polymeric material confined within the bubbles to modify

114 ved biological activity can be obtained from polymeric materials containing more than one type of mul

115 d computational studies of novel sustainable polymeric materials containing unchanged (pseudo)aromati

116 Mechanical properties of polymeric materials could be improved by forming crystal

117 ever-increasing demand for higher-performing polymeric materials counterbalanced by the need for sust

118 e networks (CANs) represent a novel class of polymeric materials crosslinked by dynamic covalent bond

119 Many polymeric materials crystallize when cooled below their

120 Renewable polymeric materials derived from biomass with built-in p

121 r, oxidation of the metal centers within the polymeric materials did not give rise to electrodepositi

122 ies on the reduction of C8H7NCO suggest that polymeric materials (e.g., polyisocyanates) made from th

123 Additive manufacturing (AM) of polymeric materials enables the manufacturing of complex

124 icient route to prepare a range of different polymeric materials, especially polymer-biohybrids.

125 In addition, the polymeric material exhibited exceptional stability in a

126 We describe a new class of inorganic polymeric materials featuring a main chain consisting of

127 tive and versatile fluorescence imaging in a polymeric material for in vivo detection of tumors.

128 are useful for developing stress-responsive polymeric materials for autonomous self-healing applicat

129 t optical screening of micro- and mesoporous polymeric materials for CCS in terms of their CO2 adsorp

130 cal circuitry) demonstrates the potential of polymeric materials for next generation telecommunicatio

131 research opens up the potential of wearable polymeric materials for non-invasive NIR vision, assisti

132 substrates/supports relying on eco-friendly polymeric materials for the fabrication of cost-effectiv

133 engineering principles for the selection of polymeric materials for the manufacturing of dynamic nan

134 nded to different antigen/antibody assay and polymeric materials for the realization of high performa

135 one-step synthesis of recyclable crosslinked polymeric materials from any monomers or polymers that c

136 m for expanding the availability of tailored polymeric materials from readily available monomers.

137 , affording two totally different classes of polymeric materials from this single monomer: polyester

138 Samples of polymeric materials generally have no intrinsic shape; r

139 the molecular level, their integration into polymeric materials has been limited to pendent group ar

140 r architecture on the physical properties of polymeric materials has been studied by comparing poly(b

141 chanically interlocked molecules (MIMs) into polymeric materials has led to the development of mechan

142 Traditionally the dispersion of particles in polymeric materials has proven difficult and frequently

143 everaging electrochemistry to degrade robust polymeric materials has the potential to impact society'

144 Enzyme-containing polymeric materials have been developed that have high a

145 Polymeric materials have been used in a range of pharmac

146 Polymeric materials have emerged as appealing alternativ

147 Supramolecular polymeric materials have exhibited attractive features s

148 Mechanically tough and self-healable polymeric materials have found widespread applications i

149 of molecules, though solitonic analogues of polymeric materials have not been considered yet.

150 ancillary ligands gave a linear, conjugated polymeric material in DMSO solution.

151 It is possible, therefore, that additional polymeric material in the interstitium, such as glycopro

152 Yellow passion fruit albedo flour as a polymeric material in the production of carotenoid nanod

153 of selected bacterial species to hundreds of polymeric materials in a high-throughput microarray form

154 methods to evaluate the biodegradability of polymeric materials in alignment with international stan

155 ts for mechanophore use in far more types of polymeric materials in applications ranging from molecul

156 rption is a central challenge for the use of polymeric materials in biological media.

157 e limited due to the challenges of detecting polymeric materials in complex biological samples.

158 aluable starting point for the use of porous polymeric materials in noninvasive diagnostic applicatio

159 tterns has focused on pulsatile release from polymeric materials in response to specific stimuli, suc

160 ain-dependent covalent chemical responses in polymeric materials, including stress strengthening, str

161 Structural polymeric materials incorporating a microencapsulated li

162 nvironmentally benign processing methods for polymeric materials independent of shape or size has bec

163 t developments in the field of biodegradable polymeric materials intended to replace non-degradable c

164 s from polymers, engineering the assembly of polymeric materials into framework structures remains an

165 The classical division of polymeric materials into thermoplastics and thermosets b

166 A key advantage of this polymeric material is that the surface can be easily mod

167 olecular structure of amorphous cross-linked polymeric materials is a longstanding challenge.

168 opyran into a colored merocyanine species in polymeric materials is achieved using mechanical force.

169 Fabrication of microfluidic systems from polymeric materials is attractive because of simplicity

170 these fields through the rational design of polymeric materials is not prevalent.

171 Stimuli-responsive polymeric materials is one of the fastest growing fields

172 A major challenge in developing recyclable polymeric materials is the inherent conflict between the

173 For rational design of advanced polymeric materials, it is critical to establish a clear

174 AFT in particular, to prepare their required polymeric materials, it is pertinent to discuss the impo

175 ing of simple parallel channel networks in a polymeric material layer, permeable to water, to study t

176 pportunities to program dynamic behaviors of polymeric materials, leading to scalable synthesis of "s

177 The versatility of nanofibrous polymeric materials makes them attractive for developing

178 industries, comprising about 20 per cent of polymeric materials manufactured today, with a worldwide

179 's suitability for handling micrometer-sized polymeric materials (microplastics).

180 apid diversification and production of ionic polymeric materials, namely anion exchange membranes (AE

181 ation only in the surface relief of a single polymeric material, nanoscale 3D printing of customised

182 l lineage fates across a series of synthetic polymeric materials of diverse physicochemical propertie

183 erein a unique means to periodically pattern polymeric materials on individual carbon nanotubes (CNTs

184 ers, fullerenes, dendrimeric nanocomposites, polymeric materials (organic and/or inorganic), inorgani

185 Many natural polymeric materials (particularly structural proteins) d

186 tissue regeneration, we developed an elastic polymeric material poly(xylitol dodecanedioic acid) (PXD

187 The flexible polymeric materials, poly (p-xylylene) (Parylene) and po

188 demonstrate proof-of-concept, two nanoporous polymeric materials, poly(dimethylsiloxane) (PDMS) and P

189 -glucosidase is immobilized within nanoscale polymeric materials (polyurethane, latex and silicone),

190 Polymeric materials possessing both high refractive indi

191 Polymeric materials produced from fossil fuels have been

192 Growth of long chain polymeric materials provides numerous sites for subseque

193 Growth of long chain polymeric materials provides numerous sites for subseque

194 rging applications for DASA photoswitches in polymeric materials, ranging from light-responsive drug

195 cessing of most thermoplastics and thermoset polymeric materials rely on energy-inefficient and envir

196 nsors, the intrinsic viscoelasticity of soft polymeric materials remains a long-standing challenge re

197 Precisely controlling structural colours in polymeric materials remains a major challenge, with curr

198 rect microbial synthesis of high-performance polymeric materials remains a major challenge.

199 phase-separation behavior of multicomponent polymeric materials remains largely unexplored.

200 bility with a wide range of nanoparticle and polymeric materials, renders SCPINS (soft-confinement pa

201 s by enzymes differed, and the amount of the polymeric materials resistant to further degradation and

202 ation is an excellent tool to make precision polymeric materials, reversal of the process to retrieve

203 Like all polymeric materials, SCPNs are heterogeneous in their na

204 preserving the quality of thermal-sensitive polymeric materials specifically proteins during a therm

205 The resulting polymeric materials, stabilized by combination of donor-

206 However, the studies of "slow" dynamics in polymeric materials still remain in question due to the

207 Polymeric materials such as alginate, collagen, chitosan

208 composites with many graphene, inorganic and polymeric materials such as polymer/GR, activated carbon

209 ); (3) the microscale and macroscale levels (polymeric materials, such as cellulose, starch, glycogen

210 ally and industrially important cross-linked polymeric materials, such as resins and gels.

211 ganic materials, such as metals, and natural polymeric materials, such as wood.

212 ion in markedly different materials, i.e., a polymeric material, Sylgard-184 and a ceramic aluminosil

213 age is achieved through a microcapsule-based polymeric material system.

214 en by the development of novel molecular and polymeric material systems.

215 We have developed a transparent organic polymeric material that can repeatedly mend or "re-mend"

216 : What are the molecular-scale features of a polymeric material that determine the extent of mechanop

217 ation that results in a covalently bonded 2D polymeric material that is chemically stable and highly

218 a microbe-encapsulated cross-linked fibrous polymeric material that is insoluble.

219 examples of a broader class of dynamic bulk polymeric materials that (self-) assemble via the transp

220 Thermosets-polymeric materials that adopt a permanent shape upon cu

221 e design of three-dimensionally cross-linked polymeric materials that are able to adapt and transform

222 e materials used for embolization as well as polymeric materials that are under investigation.

223 tems call for high-energy-density dielectric polymeric materials that can operate efficiently under e

224 In contrast to synthetic polymeric materials that can pose serious negative envir

225 objects (usually spheres) made of different polymeric materials that charge with opposite electrical

226 nd bacterial cellulose (BC) are both natural polymeric materials that have the potential to replace t

227 Polymeric materials that intrinsically heal at damage si

228 e recent advances in adhesive supramolecular polymeric materials that rely primarily on macrocycle-ba

229 Vitrimers are a new class of polymeric materials that simultaneously offer the desire

230 pportive) and 3D-printable (self-supportive) polymeric materials that utilize noncovalent interaction

231 An unmet challenge is the construction of polymeric materials that, like nature's tubulin, are sim

232 lastic deformation, indicating that in these polymeric materials the transduction of mechanical force

233 application, once cracks have formed within polymeric materials, the integrity of the structure is s

234 Due to the rigid architecture of these novel polymeric materials, they rapidly self-assemble through

235 since then, as has the number of reports on polymeric materials, though previous reviews did not sep

236 The detection of mechanical stress in polymeric materials through optical variations has attra

237 to prepare chemically stable and processable polymeric materials through the direct copolymerization

238 (e.g., tetraphenylborate derivative) to the polymeric material to buffer the activity of protons wit

239 cal tablets are often coated with a layer of polymeric material to protect the drug from environmenta

240 pand the access and availability of tailored polymeric materials to all researchers.

241 The concept of using crack propagation in polymeric materials to control drug release and its firs

242 We highlight strategies to engineer polymeric materials to increase peptide delivery efficie

243 ly, and (4) can be incorporated readily into polymeric materials to regulate their mechanical propert

244 ds the discovery and realization of tailored polymeric materials to satisfy the specific requirements

245 by extending the principles of bioresponsive polymeric materials to sequential enzyme cascades.

246 nding is an effective strategy for tailoring polymeric materials to specific application requirements

247 The polymeric materials undergo electrodeposition following

248 polyamide-12 (PA-12) represents ~95% of the polymeric materials used in LS.

249 evices, fabricated on double-sided tapes and polymeric materials using a laser cutting approach.

250 ility distribution of free volume regions in polymeric materials using ultrafast infrared (IR) polari

251 toward force-induced remodeling of stressed polymeric materials utilizing acid-catalyzed cross-linki

252 eries of water-based physically cross-linked polymeric materials utilizing cucurbit[8]uril (CB[8]) te

253 Hydrogels are versatile polymeric materials valued for their crosslinked structu

254 approach to generate stiffness gradients in polymeric materials via incorporation of dynamic monoden

255 cing the precise surface characterization of polymeric materials via ToF-SIMS.

256 mass spectrometry (EGA-MS) revealed that the polymeric material was relatively more abundant in the n

257 On serological testing, the polymeric material was shown to correspond to the O-anti

258 ne protozoan parasite, Giardia lamblia, with polymeric materials was investigated by microarray scree

259 Complete decomposition of the polymeric materials was observed with recovery of the mo

260 Polymeric materials were absent in procedural blank and

261 omote the formation of robust supramolecular polymeric materials, which restrains their applications.

262 ction offers potential for stress-responsive polymeric materials whose properties can be switched via

263 d from a novel two-staged stimuli-responsive polymeric material with an optimal ratio of an enzyme-cl

264 Here we report a structural polymeric material with the ability to autonomically hea

265 achieves the ease and cost of fabrication of polymeric material with the functionality of biological

266 wo unique molecular templates for generating polymeric materials with a cyclic molecular architecture

267 nctional two-dimensional (2D) porous organic polymeric materials with a high accessible surface, dive

268 protocols for the design and preparation of polymeric materials with a high degree of precision over

269 new mechanophore building blocks that impart polymeric materials with desirable functionalities rangi

270 efficient strategy to obtain supramolecular polymeric materials with desirable functionality.

271 arbonate is an efficient method of obtaining polymeric materials with enhanced optical properties wit

272 Our discovery opens an avenue for developing polymeric materials with extraordinary mechanical proper

273 e strategy could be used to produce advanced polymeric materials with fine control of the crystalline

274 ndent of the dynamics and therefore apply to polymeric materials with hierarchical interactions on al

275 great challenge to construct supramolecular polymeric materials with high robustness.

276 ternative feedstock for development of novel polymeric materials with high sulfur content.

277 ents a novel hydrogen bond unit for creating polymeric materials with improved mechanical properties

278 ng films prepared by doping these NO release polymeric materials with oxygen indicators (pyrene/peryl

279 The synthesis of novel polymeric materials with porphyrinoid compounds as key c

280 class of crystalline, porous, and conjugated polymeric materials with potential applications in organ

281 and accurate approach to the construction of polymeric materials with precise architectures and integ

282 tunity to develop interesting nanostructured polymeric materials with precise control over both the d

283 approach provides a method for manufacturing polymeric materials with promising applications in soft

284 The ability to fabricate polymeric materials with spatially controlled physical p

285 may be valuable assets in the development of polymeric materials with sustainable properties.

286 historical development of liquid crystalline polymeric materials, with emphasis on the thermally and

287 The formation of the oligomeric/polymeric materials within the wood following this react

288 rs can be used to remanufacture cross-linked polymeric materials without losing their original mechan

289 Wine polymeric material (WPM), which includes polysaccharides