ライフサイエンスコーパス: biopolymer

1 eviously adsorbed onto the high surface area biopolymer.

2 volatile compounds by a mixture with another biopolymer.

3 uted to peptidoglycan, a highly cross-linked biopolymer.

4 abstracting a single hydrogen atom from the biopolymer.

5 ures that allowed RNA to emerge as the first biopolymer.

6 persion of C-trim in water is a hydrocolloid biopolymer.

7 anohole arrays directly on a functional silk biopolymer.

8 cular level detail in this large and complex biopolymer.

9 the corresponding salting-in behavior of the biopolymer.

10 hallenged by the complexity of this aromatic biopolymer.

11 ely manipulates primary monomer sequences in biopolymers.

12 h are one notable exception of thermoplastic biopolymers.

13 ethod to probe the topology of DNA and other biopolymers.

14 for the rapid synthesis of sequence-defined biopolymers.

15 influenced by its interactions with anionic biopolymers.

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

17 llular environment affects the properties of biopolymers.

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

19 y structure and nano-scale features of these biopolymers.

20 san and alginate, both high molecular weight biopolymers.

21 viscoelasticity, a salient characteristic of biopolymers.

22 damers is provided to probe as biocompatible biopolymers.

23 ing module to prepare functionally important biopolymers.

24 vesicles, bacteria, synthetic polymers, and biopolymers.

25 aimed at probing the spontaneous knotting of biopolymers.

26 are very versatile and promising functional biopolymers.

27 rily shown here for spider silk and collagen biopolymers.

28 etween concentrations of seemingly unrelated biopolymers.

29 determining the tridimensional structure of biopolymers.

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

31 most poorly utilised of the lignocellulosic biopolymers.

32 tive, to produce them instead from renewable biopolymers.

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

34 s than in emulsions containing either of the biopolymer alone.

35 The versatility of MS in biopolymer analysis and its ability to reach beyond sequ

36 Cellulose is the most abundant biopolymer and a major reservoir of fixed carbon on eart

37 Lignin is one of the most abundant aromatic biopolymers and a major component of plant cell walls.

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

39 es for the stereochemical analysis of chiral biopolymers and fine chemicals.

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

41 nd nanotechnology to study molecular motors, biopolymers and nanostructures, its application to study

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

43 uded volume interactions between overlapping biopolymers and the resulting criticality of the system

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

45 ications that include biofuels, antibiotics, biopolymers, and aroma chemicals.

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

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

48 agreement with observations of cytoskeletal biopolymers, and were recently observed for the dynamics

49 As biopolymers are a chemical resource, much current effort

50 Biopolymers are an attractive alternative to store and c

51 re covering alternative value chains whereby biopolymers are converted in one or few steps to functio

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

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

54 Minireview uses recent examples to show how biopolymers are providing new directions in the synthesi

55 y of biological and technological processes, biopolymers are simultaneously subject to both confineme

56 Many of these biological polymers (biopolymers) are highly evolved for specific functions t

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

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

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

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

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

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

63 Polypeptide-type dynamic biopolymers (biodynamers) have been generated by polycon

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

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

66 crospheres containing glycosaminoglycan-like biopolymers (BPs), was examined.

67 cisely orchestrated hierarchical assembly of biopolymer building blocks.

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

69 NA double helix is among the stiffest of all biopolymers, but neither theory nor experiment has provi

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

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

72 imetry and the interaction between water and biopolymers by means of time domain nuclear magnetic res

73 The mechanical properties of biopolymers can be determined from a statistical analysi

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

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

76 ELPs are biopolymers capable of thermally-triggered in situ depot

77 tions to preserve charge storage capacity in biopolymer cathodes for more than 500 cycles.

78 se, has additional bottlenecks of individual biopolymer chain decrystallization from the substrate in

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

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

81 Biopolymer-coated liposomes demonstrated more sustained

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

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

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

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

86 However, to what degree these natural biopolymers comprise functionally privileged chemical sc

87 Images of mixtures taken at various biopolymer concentrations revealed phase separated domai

88 mages showed depletion flocculation at lower biopolymer concentrations, and thus led to an increase i

89 This high-molecular mass biopolymer consists mainly of poly(cis-1,4-isoprene) and

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

91 nd spectral data analysis that is based on a biopolymer contour representation expressed in a spectra

92 is showed that MBF-12, dominated by 270 kDa biopolymers, contributed the bioflocculation mechanisms

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

94 fusion coefficient for intrachain motions in biopolymers, D, sets the timescale for structural dynami

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

96 Biopolymer derivatives are linked together by selective

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

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

99 However there is growing interest in using biopolymers directly to create functional materials.

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

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

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

103 sized that aggregated U1-70K itself or other biopolymers (e.g. proteins or nucleic acids) interact wi

104 nslation of DNA sequences into corresponding biopolymers enables the production, function and evoluti

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

106 Unfortunately, biopolymers exhibiting thermoplastic behaviour and which

107 As a result, small biopolymers experience a viscous cytoplasm, while the mo

108 ng the assembly kinetics of the cytoskeletal biopolymer F-actin are known to impact the architecture

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

110 eling of thermodynamic competitivity between biopolymer folding and misfolding under such conditions,

111 may intervene with cooperativity and govern biopolymer folding dynamics under conditions permitting

112 Cooperativity is a hallmark of spontaneous biopolymer folding.

113 ttempt to review the literature on zein as a biopolymer for drug/vaccine/gene delivery and its applic

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

115 his universal behaviour arises because these biopolymers form a hydrogen bonded network, where water

116 ) is one of the most complex and informative biopolymers found on the cell surface or in the extracel

117 ent interactions between small molecules and biopolymer fragments are central to processes ranging fr

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

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

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

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

122 Lipid droplets coated by a double-layer of biopolymers (gelatin-pectin) were prepared by electrosta

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

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

125 nent of wood, grain and forage, this natural biopolymer has far-reaching impacts on human life.

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

127 lagen at the micro- and nanoscale with novel biopolymers has the potential to lead to improved biomat

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

129 ydrates--nature's other information carrying biopolymer--have been largely ignored as building blocks

130 new opportunities for the processing of this biopolymer, however, many fundamental and practical ques

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

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

133 metabolic products and single cell oil) and biopolymers (i.e., polyhydroxyalkanoates and bacterial c

134 in some cases, they align the fibers of the biopolymers; (ii) the aligned fibers can enhance invasio

135 ides enough evidence to exploit this neutral biopolymer in food and pharmaceutical industry.

136 Lignin, a rigid biopolymer in plant cell walls, is derived from the oxid

137 ular/atomic level deformation of the organic biopolymer in the design of high-performance hybrid mate

138 Cellulose is the most abundant biopolymer in the world, the main load-bearing element i

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

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

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

142 ll walls, represent one of the most abundant biopolymers in nature.

143 The production of novel biopolymers in plants has the potential to provide renew

144 Nanopores can probe the structure of biopolymers in solution; however, diffusion makes it dif

145 ic localization of black insoluble eumelanin biopolymers in sun exposed areas of the body.

146 found between proton mobilities of water and biopolymers in the crumb gel network and crumb firmness.

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

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

149 ic engineering will enable new uses for this biopolymer, including low-cost carbon fibers, engineered

150 o the synthesis of some of the most abundant biopolymers, including chitin and cellulose.

151 Many biopolymers, including polysaccharides, must be transloc

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

153 Elastin-like polypeptides (ELPs) are biopolymers inspired by human elastin.

154 d either alone or in combination to modulate biopolymer interactions in the plant cell wall.

155 d at the level of crack deflection along the biopolymer interface between aragonite platelets.

156 neral platelets that transfer load through a biopolymer interface in nanocomposites.

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

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

159 ined by depolymerisation and fermentation of biopolymers is presently the most widely envisioned appr

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

161 lp physicists gain a better understanding of biopolymers, it will be a valuable tool for biomedical r

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

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

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

165 The ECM is a network of biopolymers, mainly polysaccharides, proteins, and nucle

166 nments has been difficult in frequently used biopolymer matrices.

167 hese approaches to be useful in the study of biopolymer mechanics and the effects of associated regul

168 ormation of reversible and fast self-rolling biopolymer microstructures from sandwiched active-passiv

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

170 Investigation on the phase behaviour of a biopolymer mixture has been performed using 7.5% (w/w) g

171 ials listed above are primarily minerals and biopolymers, mostly in combination; the first weak in te

172 Lignocellulose is composed of three major biopolymers, namely cellulose, hemicellulose and lignin.

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

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

175 In our work, the multifunctional biopolymer nanoplatform based on ultrasmall (<10 nm) wat

176 ions with the tissue, in particular with the biopolymer network that makes up the extracellular matri

177 can accurately extract the centerlines of 3D biopolymer networks and identify network junctions using

178 The pore size of biopolymer networks governs their mechanical properties

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

180 Filamentous biopolymer networks in cells and tissues are routinely i

181 temperature, resulting in better plasticized biopolymer networks in crumb.

182 etwork glasses, randomly packed spheres, and biopolymer networks is strongly influenced by a nearby i

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

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

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

186 encies are observed in the rheology of other biopolymer networks whose structure exhibits rigidity pe

187 Biopolymer networks, such as those constituting the cyto

188 ucture and mechanics in diverse semiflexible biopolymer networks.

189 neration microscopy are widely used to image biopolymer networks; however, both techniques fail to re

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

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

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

193 Microtubules are hollow biopolymers of 25-nm diameter and are key constituents o

194 lts provide insight into how the fundamental biopolymers of life would behave if their chiral centers

195 defense, and it is the second most abundant biopolymer on Earth after cellulose.

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

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

198 nts synthesizes cellulose, the most abundant biopolymer on Earth.

199 Cellulose is the most abundant biopolymer on Earth.

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

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

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

203 theories equally holds for other hydrophilic biopolymers one finds in food.

204 o groups are easy to install and maintain in biopolymers or their ligands, this new mode of azide rea

205 The air/biopolymer partition coefficient (K) and percentage of r

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

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

208 m that the GHG profiles of the wheat-derived biopolymer products are sensitive to how the agricultura

209 reenhouse gas (GHG) profiles for wheat-based biopolymer products.

210 Here we report the first demonstration of a biopolymer protonic field-effect transistor with proton-

211 of the most recalcitrant biomacromolecules (biopolymers), providing protection against a range of ab

212 The characterization of the biopolymer recovered after the accumulation step, showed

213 ed synthesis and membrane translocation of a biopolymer represents a novel membrane translocation mec

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

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

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

217 and biomolecules (covalently) attached in a biopolymer sensor coating layer.

218 Biopolymers serve as one-dimensional tracks on which mot

219 We determine biopolymer shape and stiffness using global fitting rout

220 Sustainable production of chemicals and biopolymers should be dependent entirely on renewable ca

221 ation of the transport properties at growing biopolymer sizes.

222 eter-sized pore in a membrane changes when a biopolymer slides through it, making nanopores sensitive

223 The biopolymer sporopollenin present in the spore/pollen wal

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

225 with a variety of 3D structures forming from biopolymer structures that have identical morphology and

226 The lipid biopolymer suberin plays a major role as a barrier both

227 small molecules are moved across membranes, biopolymer substrates are segregated between cells or mo

228 ique that monitors the effective length of a biopolymer such as DNA.

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

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

231 We discuss how alignment occurs in biopolymers such as collagen-I (a major component of the

232 cule level and to analyse the composition of biopolymers such as DNA, RNA or proteins.

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

234 he emergence of early life, the formation of biopolymers such as RNA is essential.

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

236 synthesizing high complexity microarrays of biopolymers, such as nucleic acids and peptides, for hig

237 Natural biopolymers, such as peptide motif sequences, can be use

238 of complex mixtures derived from many other biopolymers, such as proteins and DNA, has not been impl

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

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

241 e in this context; we therefore examined the biopolymer-supported delivery of circulating angiogenic

242 chemical interactions of the solute with the biopolymer surface exposed or buried in the process.

243 combines both techniques to allow for ideal biopolymer syntheses.

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

245 This covalently cross-linked alginate biopolymer system is stable in a wide variety of physiol

246 n, H-bonding is already maximized in natural biopolymer systems such as nucleic acids, where Watson-C

247 to tailor the functional properties of mixed biopolymer systems that find application in dairy food p

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

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

250 morphology and performance of these complex biopolymer systems.

251 Lignin is a heterogeneous aromatic biopolymer that accounts for nearly 30% of the organic c

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

253 color is determined primarily by melanin, a biopolymer that is synthesized within epidermal melanocy

254 Starch is a water-insoluble, Glc-based biopolymer that is used for energy storage and is synthe

255 e utilized a biocompatible and biodegradable biopolymer that underwent a facile aqueous layer-by-laye

256 fects observed in the mechanical strength of biopolymers that are organized in microstructures such a

257 Based on emerging evidence for coiled-coil biopolymers that are tension-stabilized against degradat

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

259 OERCA also enabled us to discover 'smart' biopolymers that exhibit fully reversible thermally resp

260 ized nature of the monomers constituting the biopolymers that likely dominate the organic nitrogen pr

261 defined in vitro assays, we found that mucin biopolymers, the main functional constituents of mucus,

262 In contrast to rubber-like biopolymers, the retractive elastic force in these bioma

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

264 Derived from the must abundant and renewable biopolymer, they are drawing a tremendous level of atten

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

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

267 protein ligand, was conjugated to a soluble biopolymer to yield multivalent nanoscale conjugates tha

268 for the conversion of refractory aryl ether biopolymers to hydrocarbons.

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

270 e aromatic domains of insoluble indole-based biopolymers, to rationalize their distinctive physical c

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

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

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

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

275 tivities for the production of chemicals and biopolymers via microbial bioconversion.

276 hat fermentative production of chemicals and biopolymers via refining of waste and by-product streams

277 Lipase activity in the presence of biopolymers was assessed by enzymatic assay using natura

278 Using nanopores to sequence biopolymers was proposed more than a decade ago.

279 ological properties of dispersions of C-trim biopolymers were investigated.

280 Marine-gel biopolymers were recently visualized at the molecular le

281 Natural biopolymers, whey protein isolate (WPI) and gum arabic (

282 motors often move and transmit forces along biopolymers, which in general can be treated as semiflex

283 hat the cations are hydrogen bonding to this biopolymer, while others suggest they are not.

284 Double-stranded DNA is among the stiffest biopolymers, whose bending propensity crucially influenc

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

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

287 Polylysine is a cationic biopolymer with a strong antimicrobial activity against

288 Microbial levan is an important biopolymer with considerable potential in food and medic

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

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

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

292 simulated images generated using a simulated biopolymer with known stiffness and subjected to various

293 The ability to reproducibly pattern silk biopolymers with arbitrarily complex plasmonic arrays is

294 cytoplasm where it binds DNA and actin--two biopolymers with fundamental roles in almost all biologi

295 Transdermal photo-cross-linking of acrylated biopolymers with photoinitiators and lights offers a mil

296 - and peptide-based thermoplastic structural biopolymers with potential biomedical and 3D printing ap

297 Biopolymers with repeating modules composed of either fo

298 IF proteins assemble into nanoscale biopolymers with unique strain-hardening properties that

299 ing of small molecules to proteins and other biopolymers, with particular interest in drug binding to

300 ic active matter (shaken grains, mixtures of biopolymers), yet a unified description of the formation