ライフサイエンスコーパス: biopolymer

1 bonding, metal-ligand coordination, grafted biopolymers).

2 d physiological relevance of this intriguing biopolymer.

3 roups to a specific binding site of a target biopolymer.

4 hallenged by the complexity of this aromatic biopolymer.

5 ndles at specific sites and sequences of the biopolymer.

6 s that bacteria also catabolize this complex biopolymer.

7 nditions to generate mixtures of prospective biopolymers.

8 formed by the spherification of hydrogels of biopolymers.

9 NF), which is one of the most earth-abundant biopolymers.

10 most versatile and most promising functional biopolymers.

11 ns-of-life research center on the history of biopolymers.

12 t were crucial for the chemical emergence of biopolymers.

13 ely manipulates primary monomer sequences in biopolymers.

14 re and the charge density profile of the two biopolymers.

15 determining the tridimensional structure of biopolymers.

16 chain-length- and possibly sequence-specific biopolymers.

17 re quickly than DNA-binding proteins on both biopolymers.

18 aimed at probing the spontaneous knotting of biopolymers.

19 are very versatile and promising functional biopolymers.

20 rily shown here for spider silk and collagen biopolymers.

21 etween concentrations of seemingly unrelated biopolymers.

22 r composition of life's carbohydrate-related biopolymers.

23 e of the promising solutions is the usage of biopolymers.

24 most poorly utilised of the lignocellulosic biopolymers.

25 tive, to produce them instead from renewable biopolymers.

26 h are one notable exception of thermoplastic biopolymers.

27 properties of the diffusing proteins and the biopolymers.

28 oding the cellular synthesis of noncanonical biopolymers.

29 rm plants that nevertheless do contain these biopolymers.

30 )-alginate beads synthesized with sugars and biopolymers.

31 the diffusion of both protein types on both biopolymers.

32 h is demonstrated by employing two different biopolymers (alginate and hyaluronic acid) and mouse bon

33 The use of biopolymers allows additional degrees of freedom in phot

34 nanopores has traditionally been applied to biopolymer analysis, but more recently, interest has gro

35 pheres with sizes below 3 mm and composed by biopolymers and activated carbon or graphene oxide remov

36 Salicornia is a source of biopolymers and antioxidants potentially useful for food

37 First, the fundamentals of biopolymers and chemical conjugation methods to introduc

38 entally benign viscoelastic fluid comprising biopolymers and colloidal silica to enhance adherence an

39 These results extend catalysis beyond biopolymers and establish technologies for the discovery

40 ancient 'biomass' composed of putative early biopolymers and fatty acids.

41 ne of the most resilient naturally occurring biopolymers and forms the structural scaffold of blood c

42 vely charged proteins and negatively charged biopolymers and have similar characteristic diffusion co

43 roaches and physical properties of organized biopolymers and highlight the advantages of biopolymers

44 Mucin biopolymers and long-chain polysaccharides within the gl

45 le in the solution-based characterization of biopolymers and macromolecular assemblies.

46 ignificantly higher than those for the other biopolymers and non-Fe systems.

47 ransient and reversible interactions between biopolymers and NPs enable flow under applied shear stre

48 lymers, the unique molecular features of the biopolymers and of their natural substrates are essentia

49 netically encoded synthesis of non-canonical biopolymers and provide a platform for transforming the

50 ication with biocompatible materials such as biopolymers and synthetic polymers for in vivo administr

51 Studies of how individual semi-flexible biopolymers and their network assemblies change over tim

52 D(3), and FTIR confirmed the presence of the biopolymers and VD(3) in the capsules.

53 active with one another, but unreactive with biopolymers and water, is challenging.

54 the water-accessible surface of cytoplasmic biopolymers) and why KGlu is a strong stabilizer of fold

55 conductor nanoparticles, synthetic polymers, biopolymers, and other chromophores absorbing in the UV.

56 iven by the water chemically exchanging with biopolymers, and the changes in the degree of syneresis.

57 ability to generate high-density brushes of biopolymers, and the potential for regeneration.

58 Biopolymers are an attractive alternative to store and c

59 rometer-sized structured materials made from biopolymers are at the origin of most of the light-trans

60 d animals to produce photonic materials from biopolymers are discussed.

61 yotic and eukaryotic filaments indicate that biopolymers are inherently very sensitive to the couplin

62 Biopolymers are natural polymers sourced from plants and

63 These structurally diverse biopolymers are omnipresent constituents of the Gram-pos

64 Because mucin and hyaluronic biopolymers are proposed to extend and rigidify dependin

65 ranslate it into amino acid code, the extant biopolymers are restricted to encoding amino acid or nuc

66 Moreover because of this stability such biopolymers are the target of commercial and medical use

67 Glycans, the most diverse biopolymer, are shaped by evolutionary pressures stemmin

68 biopolymers and highlight the advantages of biopolymers as building blocks for realizing unique bioe

69 ge messenger RNA metabolism, cell signaling, biopolymer assembly, biochemical reactions and stress gr

70 d either as a standalone descriptor of other biopolymers' assembly or as a component in more complete

71 Other factors, such as biopolymer attachment, or salt precipitation, are theref

72 These biopolymer-based active packaging materials may therefor

73 The most promising applications of biopolymer-based materials are discussed subsequently.

74 nd the design of, intelligent and responsive biopolymer-based materials in nanofiltration and artific

75 trategy is based on the use of water-soluble biopolymer-based opal structures that can be reformed wi

76 achieved, making it attractive for flexible, biopolymer-based optical devices.

77 In this study, a biopolymer-based packaging material was prepared using a

78 ate the effect of Pickering stabilization by biopolymer-based particles (bioparticles), consisting of

79 This yields a biopolymer-based reversible, multiresponsive, dynamic wr

80 The fabrication of biopolymer-based, hierarchical 3D photonic crystals thro

81 This study investigates water mobility and biopolymer behavior during bran-rich bread making and st

82 thetic chemistry allows molecular editing of biopolymers beyond nature's capability.

83 Depending on the type of biopolymer blend and dry-heating time, TOTOX values of S

84 Biopolymer blends (GE-GA [1:1, w/w] or GE-GA-MD [2:2:1,

85 cisely orchestrated hierarchical assembly of biopolymer building blocks.

86 olled synthetic polymers that mimic nature's biopolymers, but a practical synthetic route that enable

87 e can precisely control monomer sequences in biopolymers, but this is somewhat problematic in the for

88 Moreover, the resulting biopolymer by-products can be used to boost the fish imm

89 Reliable and rapid access to defined biopolymers by automated DNA and peptide synthesis has f

90 isting of a dense suspension of semiflexible biopolymers can be manipulated over a relatively wide ra

91 rogram the genetic code so that noncanonical biopolymers can be synthesized and evolved, and to test

92 le modifications can be applied to recover a biopolymer carrying distinct types/degrees of modificati

93 biomedical applications, with an emphasis on biopolymer chemical modifications and cross-linking meth

94 icles (SPIONs), VNIR dye Nile Blue (NB), and biopolymer chitosan (Chi) was used to formulate the AgIO

95 cial self-assembly of copolymer molecules on biopolymer coacervate microdroplets.

96 Biopolymer-coated liposomes demonstrated more sustained

97 m +3.9mV in uncoated liposomes to +45.5mV in biopolymer-coated liposomes.

98 d against C. albicans cells immobilized onto biopolymer-coated substrates.

99 of omega-3 PUFAs concentrates from fish oil, biopolymer coating based on chitosan (CH) and gelatin (G

100 hanotrophs can generate single-cell protein, biopolymers, components for nanotechnology applications

101 Eumelanins are extended heterogeneous biopolymers composed of molecular subunits with ambiguou

102 ength tends to increase with the increase of biopolymer concentration and with the curing time.

103 does not considerably change after a certain biopolymer concentration level and curing time.

104 d galactomannan mixtures and controlling the biopolymers' concentration and molecular weight, improve

105 neral complex and strongly dependent on both biopolymers' concentration and molecular weight.

106 All tests were performed with different biopolymer concentrations and curing periods.

107 ferent RNA:tau mass ratios, depending on the biopolymer constituents involved.

108 acids and their properties, and those of the biopolymers constructed from them are extremely interest

109 be generalized to other natural products and biopolymers containing Dha residues.

110 sis showed that MBF-12, dominated by 270 kDa biopolymers, contributed the bioflocculation mechanisms

111 Living cells contain diverse biopolymers, creating a heterogeneous crowding environme

112 Many modern biopolymers degrade abiotically preferentially via proce

113 t was to create hydrogels, a type of soluble biopolymer delivery system to encapsulate flavored nanoe

114 In agriculture, search for biopolymer derived materials are in high demand to repla

115 ch can subsequently be translated to improve biopolymer-derived carbons in an economical way.

116 Here, we have tested implantable biopolymer devices that deliver CAR T cells directly to

117 ved monitoring the thermal behavior of these biopolymers during controlled heating from 25 up to 95 d

118 Early analysis of biopolymer dynamics relied on a variety of motional mode

119 Such multi-phase biopolymer dynamics reveal pathways for the emergence, s

120 Prebiotic chemists often study how modern biopolymers, e.g., peptides and nucleic acids, could hav

121 d on visible-light-driven heterojunction and biopolymer-enhanced strategy.

122 he specific environments in which functional biopolymers evolve when evaluating their potential roles

123 Unfortunately, biopolymers exhibiting thermoplastic behaviour and which

124 ergy process to produce mechanically tunable biopolymer fibers drawn from aqueous solutions.

125 l crystal imperfections at the atomic scale; biopolymer fibril reconfiguration/deformation and biomin

126 Biopolymer filaments, cross-linking proteins, and enzyma

127 proteins, we create droplets of cross-linked biopolymer filaments.

128 incorporating important physical effects of biopolymer flexibility, excluded volume, counterion mobi

129 The helix, turn, and beta-strand motifs of biopolymer folded structures have been found to prevail

130 agents maltodextrin was found to be the best biopolymer for obtaining high-quality fruit powder and a

131 ifying and stabilizing capacities of natural biopolymers for forming food-grade vitamin-enriched deli

132 acid (PLA) is one of the most commonly used biopolymers for manufacturing food packaging; its contro

133 nd in nature, the selection of corresponding biopolymers for synthetic photonic structures, the fabri

134 Lignin is a complex phenolic biopolymer found mainly in the secondary cell walls of v

135 Melanins are a family of heterogeneous biopolymers found ubiquitously across plant, animal, bac

136 e nanocomponents into organized hierarchical biopolymer frameworks for added optical functionalities,

137 te rot fungi were used to produce functional biopolymers from Kraft lignin.

138 in the clasts and those of bacteria-derived biopolymers from other serpentinizing systems hint at th

139 ration of functional materials using various biopolymers from trees.

140 llogenesis provides fundamental insight into biopolymer gel properties and promises enhanced control

141 ided tape (DST) made from a combination of a biopolymer (gelatin or chitosan) and crosslinked poly(ac

142 Lipid droplets coated by a single-layer of biopolymers (gelatin) were prepared by high pressure hom

143 hase transitions, glasses, jammed solids and biopolymer gels have coordination numbers placing them a

144 rt that, as strain is increased, not only do biopolymer gels stiffen but they also exhibit faster str

145 muscle fibers embedded in three-dimensional biopolymer gels under auxotonic loading conditions.

146 icability with an example inspired by active biopolymer gels.

147 ter (W/O/W) double emulsions stabilized with biopolymers: gum arabic, sodium alginate (Alg) and chito

148 Each biopolymer has independent functions, but when needed, t

149 The functionality of natural biopolymers has inspired significant effort to develop s

150 lloidal systems such as carbon nanotubes and biopolymers have micron-sized lengths, so continuum desc

151 ed overview of the design and development of biopolymer hydrogels for biomedical applications, with a

152 t advances in the use of chemically modified biopolymer hydrogels for the biofabrication of tissue sc

153 Injectable biopolymer hydrogels have gained attention for use as sc

154 as the formation of interpenetrating network biopolymer hydrogels, are highlighted.

155 pproach, based on printing of shape-morphing biopolymer hydrogels, is developed for the fabrication o

156 nformers as well as the natural nucleic acid biopolymers (i.e., DNA and RNA).

157 Mucins, the dominant biopolymer in mucus, organize into complex polymeric net

158 ural materials, cellulose, the most abundant biopolymer in the world with key properties, such as bio

159 ave the way for the effective use of keratin biopolymer in wearable or edible electronics where confo

160 s study, the molecular mobility of water and biopolymers in coarse, ground, and pericarp-enriched (PE

161 vanced applications of wood and wood-derived biopolymers in different fields, such as energy, electro

162 adapted to modify other polysaccharides and biopolymers in general.

163 l chemistries have been widely used to probe biopolymers in living systems.

164 le of the structural conformation of natural biopolymers in metal bond strength.

165 e of the most abundant and cheaply available biopolymers in Nature.

166 on correlated with the presence of different biopolymers in the biofilm matrix, including extracellul

167 ulose (28%) and lignin (45.1%) were the main biopolymers in the final residue, which showed low water

168 Molecular motion of biopolymers in vivo is known to be strongly influenced b

169 The molecular mobility of water and biopolymers in wheat dough and the influence of xylanase

170 a-L-HNA represents a versatile informational biopolymer, in view of its capability to cross-communica

171 as the direct sequencing of other important biopolymers including RNA, polysaccharides, and polypept

172 with neurodegenerative diseases contain many biopolymers including the polyanions glycosaminoglycans

173 technique capable of detecting the shape of biopolymers, including DNA knots.

174 verproduction of large, flexible or rod-like biopolymers, including hyaluronic acid and mucins, in th

175 Many biopolymers, including polysaccharides, must be transloc

176 accurate storage and processing of nature's biopolymer information.

177 he accumulation of the universally conserved biopolymer inorganic polyphosphate.

178 can produce extracellular enzymes to degrade biopolymers into bio-available smaller solutes, while ol

179 The inclusion of biopolymers into biomedical hydrogels is of great intere

180 lting from liquid-liquid phase separation of biopolymers into intracellular condensates control essen

181 The regeneration of structural biopolymers into micelles or nanoparticles suspended in

182 nsitive, and selective detection of specific biopolymers is critical in a broad range of biomedical a

183 on of lipophilic bioactive compounds in food biopolymers is important to functional beverages, but pr

184 hosphate (polyP), a several billion-year-old biopolymer, is produced in every cell, tissue, and organ

185 red, arrangement of these lamellea, bound by biopolymer layers only [Formula: see text]25 nm thick, o

186 s composed of DOTAP and DOPE with anionic HA biopolymer led to efficient ionic complexation and forma

187 ising strategy for valorization of the plant biopolymer lignin.

188 f a random network comprised of cross-linked biopolymer-like fibers to substantiate the notion that t

189 opamine (PDA) is an emerging nature-inspired biopolymer material that possesses many interesting prop

190 nments has been difficult in frequently used biopolymer matrices.

191 s, may prompt materials scientists to pursue biopolymer mimics of silk with high performance yet ligh

192 he maximum amount of coacervates formed at a biopolymer-mixing ratio of 8:1, 8:1, 10:1 and 15:1 for P

193 omplex formation was found to be optimal for biopolymer-mixing ratios of 8:1, 8:1, 25:1 and 25:1 for

194 Gelatin-graphene conductive biopolymer nanocomposites (CPCs) with ultralow percolati

195 Information about the design of biopolymer nanoparticles (BNPs) for polyunsaturated fatt

196 o estimate the limits of mechanosensing in a biopolymer network, a sensory process involved in cellul

197 y consist of cells embedded within a fibrous biopolymer network.

198 Cross-linking methods to form biopolymer networks are then discussed in detail, includ

199 Automatic tracking of biopolymer networks from fluorescence microscopy time-la

200 rheological experiments on various in vitro biopolymer networks have shown similar strain-stiffening

201 and local correspondence algorithm to track biopolymer networks in 2D and 3D, using stretching open

202 Filamentous biopolymer networks in cells and tissues are routinely i

203 echanics that cannot be reproduced by either biopolymer networks or colloidal particle systems alone.

204 dity and connectivity of filaments in active biopolymer networks regulates the anisotropy and the len

205 forces in highly nonlinear three-dimensional biopolymer networks that mimic the physiological situati

206 We quantify several different types of biopolymer networks to demonstrate SOAX's potential to h

207 Whereas cell-free reconstituted biopolymer networks typically soften under applied uniax

208 lycans are known as the third major class of biopolymers, next to DNA and proteins.

209 refore, topological characterization of such biopolymers, not only provides explanation of their ther

210 erials; this strategy is not translatable to biopolymers observed in nature.

211 Vs) modified with glucidex, a dextrin, and a biopolymer obtained from Chimaera monstrosa.

212 Chitin, a biopolymer of N-acetylglucosamine, is abundant in invert

213 biosynthesis of cellulose, the most abundant biopolymer of plant cell walls.

214 As anionic biopolymers, oligonucleotides can have biological functi

215 Nature has three biopolymers: oligonucleotides, polypeptides, and oligosa

216 Cellulose is the most abundant biopolymer on Earth, and certain organisms from bacteria

217 As the most abundant biopolymer on Earth, cellulose is a key structural compo

218 Cellulose, the most abundant biopolymer on earth, is a versatile, energy rich materia

219 l component and represents the most abundant biopolymer on Earth.

220 erial derived from chitin, the most abundant biopolymer on the planet.

221 Polysaccharides are the most abundant biopolymers on earth that serve various structural and m

222 Lignin, one of the most abundant biopolymers on Earth, derives from the plant phenolic me

223 molecular imaging of glycans-the predominant biopolymers on Earth, with a plethora of structural and

224 The conformational impact of environmental biopolymers on metal sorption was studied through Cu sor

225 The best mass ratio for the biopolymers (OVA:AL) was 4:1 at pH 3.8, and the complex

226 Multivalent biopolymers phase separate into membrane-less organelles

227 jective of this study is to develop a simple biopolymer platform of mucoadhesive wafers that enables

228 d extracellular matrix (ECM) is comprised of biopolymers, primarily collagen I, that are created and

229 surfaces buried in protein folding and other biopolymer processes and transition states can be determ

230 order is emerging as an important feature of biopolymers, regulating a vast array of cellular functio

231 nd the encoded biosynthesis of non-canonical biopolymers, requires the discovery of multiple orthogon

232 The ability of the biopolymers RNA and DNA to store and transfer informatio

233 This affinity is attributed to the biopolymer's ability to form covalent C-O-Fe bonds throu

234 rmation, to give complete information on the biopolymer's composition.

235 w, it is still a challenge to transcribe the biopolymer's deformation attributes into a stronger subs

236 o considered as the possible first Darwinian biopolymer(s).

237 nanoscale immunoconjugates (NICs) on natural biopolymer scaffold, poly(beta-L-malic acid), with coval

238 , we found that CAR T cells can migrate from biopolymer scaffolds and eradicate tumors more effective

239 Biopolymers serve as one-dimensional tracks on which mot

240 Electrosprayed capsules with dextran as main biopolymer showed a significantly faster broadening (Del

241 On the biopolymer side, microtubules possess intrinsically diso

242 molecules, opening new perspectives for this biopolymer, so far not considered, and encouraging furth

243 r the identification and efficient design of biopolymer stabilized soil systems.

244 the bioavailability of VEGF, we developed a biopolymer-stabilized elastin-like polypeptide (ELP)-VEG

245 ive layer, while the figures of merit of the biopolymer such as the ionic conductivity and relaxation

246 the complex mechanical properties of diverse biopolymers such as collagen gels, fibrin gels and Matri

247 Gels formed from ECM protein biopolymers such as collagen or fibrin are commonly used

248 lly produced carbons are typically made from biopolymers such as lignin while many of the catalytic c

249 loping automation systems to prepare natural biopolymers such as peptides and oligonucleotides.

250 have similar force-extension behavior as in biopolymers such as proteins and DNA.

251 ify the mechanism of biosynthesis of complex biopolymers (such as glycans) that is not template-drive

252 diversity of intracellular and extracellular biopolymers, such as polysaccharides, polyamides, polyes

253 Structural self-assembly in biopolymers, such as proteins and nucleic acids, involve

254 psilon-PL) is a broad-spectrum antimicrobial biopolymer, suitable for use in foods; however, some stu

255 nuclease digestion, makes TNA an attractive biopolymer system for diagnostic and therapeutic applica

256 ance of maximizing H-bonding in higher order biopolymer systems using minimally perturbing alternativ

257 The phase behavior of biopolymer systems was discussed at different Prot:HMP r

258 morphology and performance of these complex biopolymer systems.

259 as a function of the total concentration of biopolymers (TC%) and the core-to-wall ratio, and the gr

260 erties establish bilingual PNA as a powerful biopolymer that combines two information systems to harn

261 Fibrin is a biopolymer that gives thrombi the mechanical strength to

262 -responsive assembly behavior of a bilingual biopolymer that integrates both amino acid and nucleobas

263 Lignin is a complex aromatic biopolymer that strengthens and waterproofs plant second

264 plasm comprises a concentrated collection of biopolymers that are predominantly polyanionic (e.g., DN

265 They are evolutionarily old biopolymers that are present from bacteria to man.

266 and polynucleotides are natural programmable biopolymers that can self-assemble into complex tertiary

267 on activation, fibrinogen forms large fibrin biopolymers that coalesce into clots which assist in wou

268 Microtubules are biopolymers that perform diverse cellular functions.

269 cleic acids and proteins are the fundamental biopolymers that support all life on Earth.

270 oteins can diffuse on the negatively charged biopolymers, the unique molecular features of the biopol

271 ue are surrounded by a disordered network of biopolymers, their in vivo mechanical environment can be

272 is currently thought to have been the first biopolymer to support Darwinian natural selection on Ear

273 some form on early Earth to become the first biopolymer to support Darwinism here.

274 set of targets, ranging from the three major biopolymers to small molecules.

275 t biomass (microbial cells and extracellular biopolymers) to cover crystal and amorphous calcium phos

276 Furthermore, it has been observed that the biopolymer-treated specimens showed better resistance to

277 ibility to natural elements, plain soil, and biopolymer-treated specimens were exposed to real atmosp

278 macromolecules that can be heterogeneous in biopolymer type, sequence, and chain count, accurately r

279 icated that stability is dependent on pH and biopolymer type.

280 Five biopolymer types were investigated in this study: Xantha

281 rolled radical generation for degradation of biopolymers under physiologically relevant temperatures

282 a biodegradable, antibacterial, and nontoxic biopolymer used in a wide range of applications includin

283 r (cis-1,4-polyisoprene) is an indispensable biopolymer used to manufacture diverse consumer products

284 Biopolymers used for food contact materials must be eval

285 Genetic biopolymers utilize defined sequences and monomer-specif

286 ing to nucleic acids and, more generally, to biopolymers, very often requires at a minimum the presen

287 tion, enabling facile diffusion despite high biopolymer volume fraction.

288 nt large-scale macromolecular motions of the biopolymer von Willebrand Factor (vWF) immersed in flow.

289 que TERS signals of monomeric units of other biopolymers, we anticipate that this technique can be ex

290 omplexes to coordinate the role of different biopolymers, we dovetail protein amino acids and nucleob

291 Five different biopolymers were tested against Fe(2)O(3): locust bean g

292 The same biopolymers when produced by pathogenic bacteria functio

293 hierarchical organization of lignocellulosic biopolymers will be a key enabling technology in the eme

294 Lignin is an abundant biopolymer with a high carbon content and high aromatici

295 ed dextran (Ac-DEX) is a tunable acid-labile biopolymer with facile synthesis, aptly designed for the

296 e use of melanin is first reported, and this biopolymer with good biocompatibility and biodegradabili

297 the judicious placement of a unique organic biopolymer with intelligent deformation features.

298 wn to produce a wide range of glycoconjugate biopolymers with apparent benefits to health; therefore,

299 his creates the possibility of designing new biopolymers with desired properties.

300 They appear in proteins, peptides and other biopolymers with disulfide bonds or ions interactions gi