ライフサイエンスコーパス: cellulosic

1 chromophores occurring in all types of aged cellulosics.

2 f the sub-class members may encode other non-cellulosic (1-->4)beta-glycan synthases in plants.

3 ], whereby the overall solid content was 90% cellulosic, a lightly colored, transparent hydrogel was

4 While traditional cellulosic aerogel processing approaches lack the abilit

5 omoters selected to optimize growth on model cellulosic and hemicellulosic substrates.

6 structures of CvAA9A and of LsAA9A bound to cellulosic and non-cellulosic oligosaccharides provide i

7 The remaining cellulosic and non-cellulosic polysaccharides were much

8 - and POC-intensive biomass-fired boilers in cellulosic and sugarcane ethanol plants for steam and el

9 tspots underlying the divergent evolution of cellulosic and sweet sorghum.

10 Colocalization of a cell wall marker for cellulosic beta-(1-4)-D-glucans and anti-RYMV antibodies

11 Recent empirical findings show that cellulosic bioenergy concerns related to climate mitigat

12 (Panicum virgatum L.) are being evaluated as cellulosic bioenergy crops.

13 ble land-use changes from an expanded global cellulosic bioenergy program on greenhouse gas emissions

14 However, commercial production of cellulosic biofuel has been hampered by inefficient ferm

15 the application of laccases to the emerging cellulosic biofuel industry.

16 oximately 25 per cent of the 2022 target for cellulosic biofuel mandated by the US Energy Independenc

17 The recent upswing of interest in cellulosic biofuel production has become the new focus o

18 Implementing the mandate for cellulosic biofuel production in the Renewable Fuel Stan

19 nventional, 86.1% of biodiesel, and 54.8% of cellulosic biofuel production mandated by the renewable

20 locally available water, up to 7% of planned cellulosic biofuel production will be affected.

21 ith implications for improving feedstock for cellulosic biofuel production.

22 gnificantly improve yields of cellulases for cellulosic biofuel production.

23 t biomass may provide insights for improving cellulosic biofuel production.

24 s is a promising cofermentation strategy for cellulosic biofuel production.

25 on capture and storage (CCS) integrated with cellulosic biofuel production.

26 ty, paper manufacturing, and, more recently, cellulosic biofuel production.

27 l for improving the prospects of significant cellulosic biofuel production.

28 idium thermocellum, which is of interest for cellulosic biofuel production.

29 tover removal in designing supply chains for cellulosic biofuel production.

30 ach is recommended for the corn stover-based cellulosic biofuel system under the RFS program.

31 r example, the results show that meeting the cellulosic biofuel target in the RFS using Miscanthus x

32 cially permission to harvest CRP biomass for cellulosic biofuel would help to blunt the climate impac

33 n stover harvesting for rising production of cellulosic biofuel.

34 CS, CCS, or both can produce carbon-negative cellulosic biofuels (<=-22.2 gCO(2) MJ(-1)).

35 cal and economic barrier to overcome to make cellulosic biofuels a commercial reality.

36 Producing cellulosic biofuels and bio-based chemicals from woody b

37 Cellulosic biofuels are part of a portfolio of solutions

38 In the context of cellulosic biofuels development, cell wall composition v

39 m is a good candidate organism for producing cellulosic biofuels due to its native ability to ferment

40 tion of hemicellulose for bioconversion into cellulosic biofuels have resulted in the identification

41 e impact of substituting low-carbon advanced cellulosic biofuels in place of petroleum.

42 Policy support for cellulosic biofuels is contingent on their achieving muc

43 substituting conventional fossil fuels with cellulosic biofuels is growing in the face of increasing

44 is harvested which could be used to produce cellulosic biofuels mandated by the current Renewable Fu

45 Economically viable production of cellulosic biofuels requires operation at high solids lo

46 as high as $16-$30 billion by using them for cellulosic biofuels to displace gasoline and $35-$68 bil

47 d of at least 60% for biofuels classified as cellulosic biofuels under the Renewable Fuels Standard.

48 nsidered as a near-term feedstock option for cellulosic biofuels, its sustainability must be evaluate

49 greenhouse gas (GHG) reduction threshold for cellulosic biofuels, while the Low Carbon Fuel Standard

50 rides that can be utilized as precursors for cellulosic biofuels.

51 l Standard emissions reduction threshold for cellulosic biofuels.

52 l standard emissions reduction threshold for cellulosic biofuels.

53 making efficient use of carbon compounds in cellulosic biomass and present an innovative strategy fo

54 e cost of ethanol from either corn or future cellulosic biomass but not production incentives, projec

55 ss policies do not account for the fact that cellulosic biomass can equally be used for different, co

56 lum is recognized for its ability to ferment cellulosic biomass directly, but it cannot naturally gro

57 mprehensive picture of structural changes of cellulosic biomass during enzymatic hydrolysis is essent

58 ature as model organisms, ability to degrade cellulosic biomass either by free enzymes or by cellulos

59 it, best-use framework to optimally allocate cellulosic biomass feedstocks to energy demands in trans

60 is study addresses the question, "When using cellulosic biomass for vehicular transportation, which f

61 Electricity from cellulosic biomass had higher particulate matter (PM) em

62 Cellulosic biomass has the potential to contribute to me

63 Cellulosic biomass in particular is anticipated to be us

64 The conversion of recalcitrant plant-derived cellulosic biomass into biofuels is dependent on highly

65 ottleneck for industrial-scale conversion of cellulosic biomass into biofuels.

66 is a candidate microorganism for converting cellulosic biomass into ethanol through consolidated bio

67 Efficient enzymatic saccharification of cellulosic biomass into fermentable sugars can enable pr

68 This endeavor requires the conversion of cellulosic biomass into simple sugars, and the conversio

69 Cellulosic biomass is an abundant and underused substrat

70 Plant cellulosic biomass is an abundant, low-cost feedstock fo

71 he costs of advanced biofuel production from cellulosic biomass is to engineer a single microorganism

72 of biofuels from renewable resources such as cellulosic biomass provides a source of liquid transport

73 The most abundant carbohydrate product of cellulosic biomass pyrolysis is the anhydrosugar levoglu

74 ling cost-effective industrial conversion of cellulosic biomass to biofuels.

75 processes featuring microbial conversion of cellulosic biomass to ethanol (or other products) in the

76 a cellulases are able to efficiently degrade cellulosic biomass to fermentable sugars at large, comme

77 Clostridium thermocellum can ferment cellulosic biomass to formate and other end products, in

78 minant role in the biochemical conversion of cellulosic biomass to high-value biofuels.

79 ill be the enzymatic conversion of renewable cellulosic biomass to inexpensive fermentable sugars; ne

80 The conversion of readily available cellulosic biomass to valuable feedstocks and fuels is a

81 erformance parameters with corn fiber as the cellulosic biomass waste.

82 he full potential of biofuel production from cellulosic biomass will be obtainable in the next 10 to

83 of anaerobic biotechnological processing of cellulosic biomass without added saccharolytic enzymes.

84 Ethanol made biologically from cellulosic biomass, including agricultural and forestry

85 Conversion of cellulosic biomass, which is both abundant and renewable

86 Cellulosic biomass-based sustainable aviation fuels (SAF

87 id, which constitute substantial portions of cellulosic biomass.

88 nd its potential for enhanced degradation of cellulosic biomass.

89 , pulping efficiency, and sugar release from cellulosic biomass.

90 nomes participating in the deconstruction of cellulosic biomass.

91 at 80 C with ability to degrade and utilize cellulosic biomass.

92 advances to understand the structure of the cellulosic biomass.

93 In cellulosic biorefineries, coproduced biogas is assumed t

94 dard) have not spurred broad construction of cellulosic biorefineries.

95 e minimum ethanol selling price (MESP) for a cellulosic biorefinery (using corn stover as feedstock)

96 Cellulosic, both natural and semisynthetic particles, we

97 and aquatic niches where plant and/or algal cellulosic cell walls are present.

98 rsity of bacteria and fungi that do not have cellulosic cell walls.

99 While DHBQ is one of the three key cellulosic chromophores and its degradation by H2O2 is w

100 odel compound, kinetin, through a variety of cellulosic coacervate/sebum composite barriers prepared

101 -4-based transport of cargoes containing non-cellulosic components along cortical microtubules and ce

102 the extract and confirmed the removal of non-cellulosic components.

103 ities of MNPs are also released when plastic-cellulosic composite and biodegradable bags are steeped.

104 midazolium acetate ionic liquid to prepare a cellulosic continuous film.

105 e treated either with sNAG scaffolds, with a cellulosic control material, or were left untreated.

106 Cellulosic crops are projected to provide a large fracti

107 An alternative is to grow lignocellulosic (cellulosic) crops on 'marginal' lands.

108 Cellulosic derivatives and commodity polymers such as po

109 ture and storage (CCS) at ionic liquid-based cellulosic ethanol biorefineries using biomass sorghum.

110 Cellulosic ethanol can achieve estimated greenhouse gas

111 Because cellulosic ethanol can offer health benefits from PM(2.5

112 nd technology, but only $123-208 million for cellulosic ethanol depending on feedstock (prairie bioma

113 a requirements can be sources of concern for cellulosic ethanol derived directly from managed agricul

114 as (GHG) intensities and production costs of cellulosic ethanol derived from corn stover, switchgrass

115 Cellulosic ethanol derived from fast growing C4 grasses

116 s of their contribution in the life cycle of cellulosic ethanol derived from five different feedstock

117 average greenhouse gas (GHG) emissions from cellulosic ethanol derived from switchgrass were 94% low

118 , phasing out most corn ethanol and limiting cellulosic ethanol feedstocks to sustainably produced cr

119 ssessing the cost-effectiveness of utilizing cellulosic ethanol for mitigating GHG emissions and desi

120 ids, shale gas-to-liquids, corn ethanol, and cellulosic ethanol from switchgrass.

121 from GHG reduction, a shift from gasoline to cellulosic ethanol has greater advantages than previousl

122 ies directed toward commercial production of cellulosic ethanol have created the opportunity to drama

123 A nascent cellulosic ethanol industry is struggling to become cost

124 e enzymes that are of direct interest to the cellulosic ethanol industry.

125 rologous beta-glucosidase production for the cellulosic ethanol industry.

126 onsistently achieve industrial-scale titers (cellulosic ethanol of >100 grams per liter when toxified

127 ing resource intensive compared to gasoline, cellulosic ethanol offers the possibility of a reduction

128 Second generation biofuels based on cellulosic ethanol produced from terrestrial plants, has

129 a hypothetical future containing additional cellulosic ethanol produced from two near-commercial pat

130 excellent candidates for the biosynthesis of cellulosic ethanol producing strains because they can gr

131 ocesses relevant to biomass pretreatment for cellulosic ethanol production and general polymer coil-g

132 arget $2.50/gal biofuel selling price, using cellulosic ethanol production as a test case.

133 rs the potential to improve the economics of cellulosic ethanol production by reducing the costs asso

134 te that N2-utilizing Z. mobilis could save a cellulosic ethanol production facility more than $1 mill

135 ing appropriate policy incentives to support cellulosic ethanol production nationwide.

136 Furthermore, we suggest that development of cellulosic ethanol production processes that use a varie

137 osic biomass conversion process for low-cost cellulosic ethanol production that interferes with subse

138 (Populus nigra) is a potential feedstock for cellulosic ethanol production, although breeding for thi

139 potential to significantly lower the cost of cellulosic ethanol production, and support the feasibili

140 hicle (PHEV) adoption rates with scale-up of cellulosic ethanol production.

141 omass pretreated at elevated temperatures in cellulosic ethanol production.

142 engineering of mutant microbial strains for cellulosic ethanol production.

143 Fossil options and cellulosic ethanol require significantly less water and

144 y outcomes for a centralized biorefinery for cellulosic ethanol that does all processing versus a bio

145 For cellulosic ethanol to become a reality, biotechnological

146 ing land and ecosystem goods and services by cellulosic ethanol was estimated using the Eco-LCA frame

147 ion biofuels such as synfuel hydrocarbons or cellulosic ethanol, if produced from low-input biomass g

148 dicate competitiveness and sustainability of cellulosic ethanol, respectively, show that only ethanol

149 offsets per unit area of cropland than does cellulosic ethanol.

150 ) emissions from gasoline, corn ethanol, and cellulosic ethanol.

151 of polyhydroxyalkanoates as a co-product of cellulosic ethanol.

152 bon tax rate needed to induce consumption of cellulosic ethanol.

153 ping sustainable liquid fuel production from cellulosic feedstock is a major challenge and will requi

154 he direct use of existing CRP grasslands for cellulosic feedstock production would avoid C debt entir

155 ever, the availability of marginal lands for cellulosic feedstock production, and the resulting green

156 table feedstock species to augment near-term cellulosic feedstock production.

157 esults suggest that biomass sorghum produces cellulosic feedstock with similar emissions to corn grai

158 In a cellulosic feedstock-derived medium, Z. mobilis achieved

159 make up for the low nitrogen content of the cellulosic feedstock.

160 Cellulosic feedstocks can have positive environmental ou

161 These cellulosic feedstocks have also shown improved ecosystem

162 Although using cellulosic feedstocks to produce bioenergy has great pot

163 al and archaeal microbiomes of two perennial cellulosic feedstocks, switchgrass (Panicum virgatum L.)

164 n and simultaneous in situ detoxification of cellulosic feedstocks.

165 wed that polyelectrolyte multilayer modified cellulosic fibers can remove greater than 99% of bacteri

166 Freely dispersed bacteria adsorbing cellulosic fibers can remove greater than 99.9% of Esche

167 The bacteria adsorbing cellulosic fibers do not leach any biocides, and it is a

168 atory micron-scale particulates from friable cellulosic fibers in homemade cotton-fabric masks confou

169 A filtering approach using modified cellulosic fibers is desirable for purification of natur

170 Wood-derived cellulosic fibers prepared in different ways were succes

171 ial to purify water using bacteria adsorbing cellulosic fibers, functionalized with polyelectrolytes

172 crothin biofibers--including spider silk and cellulosic fibers--reveal characteristics of the fibers'

173 as sensors thus directly reveal chirality of cellulosic fibers.

174 20.7% PAC: 27.7%) and synthetic regenerated cellulosic fibres (SRCF; ATL: 63.2%: MED: 5.8% PAC: 68.9

175 r allowed the entrapment of antibody through cellulosic fibres, validating to be an alternative to 96

176 Overall, the value-added soyhull cellulosic films are advantageous in minimizing post-har

177 nfusions, where SCOBY was able to synthesise cellulosic films.

178 of the iron clay prevents degradation of the cellulosic fraction at pyrolysis temperatures of 250 deg

179 Within the cellulosic fraction, relatively disordered, amorphous re

180 -effective, at-scale biomass utilization for cellulosic fuel and nonfuel products alike.

181 ssociated with the large-scale production of cellulosic fuel.

182 for developing industrial strains to produce cellulosic fuels and chemicals.

183 w biomass, a field-to-tank yield of drop-in, cellulosic gasoline of >60 % is possible.

184 mg g(-1) AIS) and relatively high amounts of cellulosic glucose (118-214 mg g(-1) AIS).

185 Proteins, non-cellulosic glucose and total phenols contributed mainly

186 ectin-related sugars compared with potential cellulosic glucose suggests that the polysaccharides of

187 as evolved to become an intricate network of cellulosic, hemicellulosic, and pectic polysaccharides a

188 mocellum, which is thought of as primarily a cellulosic heterotroph but is shown here to be endowed w

189 plement activation (Biocompatible [BCM]) and cellulosic, high complement activation (Bioincompatible

190 oth G. oxydans and P. simplicissimum can use cellulosic hydrolysate instead of glucose, lowering subs

191 i growth in various media (rich, minimal and cellulosic hydrolysate) and in the presence of several g

192 the biolixiviant feedstock (e.g., glucose or cellulosic hydrolysate) needed to release one Mg(2+) ion

193 i onto growth in several model environments (cellulosic hydrolysate, low pH, and high acetate).

194 ylose, which are the most abundant sugars in cellulosic hydrolysates.

195 ntation experiments performed with simulated cellulosic hydrolyzates, suggesting this is a promising

196 that Bk2 functions in a patterning of lignin-cellulosic interactions that maintain organ flexibility

197 The mineralization mechanism by which cellulosic, keratinous, and silk tissues fossilize in th

198 o their suitability for detecting acetylated cellulosic key chromophores.

199 he SPGE-capture antibodies at the end of the cellulosic lateral flow strip.

200 seep preserved coprolites and their original cellulosic material for 50,000 years at RLB, yielding a

201 divided into four sections according to the cellulosic material that is graft-copolymerised; (i) cel

202 uce a composite biocatalyst, based on porous cellulosic material, produced after wood sawdust deligni

203 lenges for microbial biofuel production from cellulosic material.

204 protein machineries that efficiently degrade cellulosic material.

205 we investigate the applicability of biobased cellulosic materials and bioinspired 4D-printing for wea

206 Moreover, the biodegradability of the cellulosic materials containing APP increased owing to t

207 satile, chemo-enzymatic approach to activate cellulosic materials for CuAAC "click chemistry", to dev

208 Technologies surrounding utilization of cellulosic materials have been integral to human society

209 Three types of cellulosic materials have been modified and tested for t

210 -effective processes must exist to breakdown cellulosic materials into their primary components.

211 Its almost ubiquitous presence in cellulosic materials makes it a target molecule of the p

212 Bioinspired 4D-printing and biobased cellulosic materials offer a resource-efficient and ener

213 icated that the mechanical properties of the cellulosic materials were not significantly affected by

214 engineering of microorganisms for utilizing cellulosic materials with simultaneous conversion to fue

215 ll proteins that loosen plant cell walls and cellulosic materials without lytic activity.

216 erase in vitro with substrate preference for cellulosic materials.

217 of the key chromophores formed upon aging in cellulosic materials.

218 erium release high levels of cellobiose from cellulosic materials.

219 lays an ancillary role in the degradation of cellulosic materials.

220 actors that affect the properties of complex cellulosic materials.

221 one (DHNQ) is one of the key chromophores in cellulosic materials.

222 ntral to broadening the application space of cellulosic materials.

223 Embedded cellulosic membranes act as microvalves, permitting flow

224 and adsorb beta 2m more efficiently than the cellulosic membranes.

225 ould result from rupture or loosening of the cellulosic mesh of interconduit pit membranes during the

226 which are shaped by an intricate network of cellulosic microfibrils.

227 Oxygen encapsulated nanosize carboxymethyl cellulosic nanobubbles were developed for mitigating the

228 dynamics, and stabilities of different sized cellulosic oligomers need to be considered when designin

229 9A and of LsAA9A bound to cellulosic and non-cellulosic oligosaccharides provide insight into the mol

230 ialyzers evaluated contained either modified cellulosic or polysulfone membranes, whereas the germici

231 The study also presents chemically-modified cellulosic paper strips with the pyridoxal conjugated BS

232 capillary action in the hydrophilic pores of cellulosic paper.

233 ngle-walled carbon nanotube (CNT) bundles on cellulosics (paper and cloth) can detect aggressive oxid

234 es occurrence (MPs and natural and synthetic cellulosic particles), have been determined in 73 bevera

235 etyl-aryl ether peaks, coupled with enhanced cellulosic peaks.

236 inability of F. succinogenes to utilize non-cellulosic (pentose) sugars for growth.

237 contribute to industrial-scale breakdown of cellulosic plant biomass into simple sugars that can the

238 a (PD) allow direct communication across the cellulosic plant cell wall, facilitating the intercellul

239 rumen microbes specialize in degradation of cellulosic plant material, but most members of this comp

240 nalysis of the biofilm matrix shows that the cellulosic polymer is partially acetylated cellulose, wh

241 niche is largely due to overproduction of a cellulosic polymer, the product of the wss operon.

242 ransferases involved in the synthesis of non-cellulosic polymers with (1-->4)beta-linked backbones, i

243 tic domain was shown to hydrolyze artificial cellulosic polymers, cellulose oligosaccharides, and a v

244 tabolic systems, including the hydrolysis of cellulosic polymers.

245 Xylan, the most prevalent non-cellulosic polysaccharide, binds to cellulose microfibri

246 ferences in the linkage structure of the non-cellulosic polysaccharides could be traced to the defect

247 ial studies showed that among all of the non-cellulosic polysaccharides examined, only the hemicellul

248 aphy showed that the molecular weight of non-cellulosic polysaccharides in the triple mutants, mainly

249 The remaining cellulosic and non-cellulosic polysaccharides were much more readily extrac

250 es, degradation and loss of crystallinity of cellulosic polysaccharides, and silicification.

251 ose microfibrils embedded in a matrix of non-cellulosic polysaccharides, interlaced with structural p

252 in order to determine cellulose, lignin, non-cellulosic polysaccharides, protein, total polyphenols i

253 BC-based films contained up to 26.7 % of non-cellulosic polysaccharides.

254 age formation, resulting in the synthesis of cellulosic polysaccharides.

255 ainable biomaterials, which not only possess cellulosic properties but also have the important hallma

256 Perturbation in cellulosic ray formation has systematically been associa

257 lds control mucilage architecture along with cellulosic rays and show that Arabidopsis SCE cells repr

258 in crystalline cellulose deposition into the cellulosic rays of the cobl2 mutants.

259 hroughout their histology, enclose preserved cellulosic remains in place.

260 Herein, cellulosic residue from corncob was employed as a renewa

261 li (37.7%) without and NaClO2 (9.1%) and the cellulosic residue represents a (22.5%).

262 Herein, soyhulls cellulosic residue was extracted, solubilized in ZnCl(2)

263 7 wt% of the lignin from the husk; leaving a cellulosic rich pulp behind, which released 82 % of the

264 e, pectinaceous mucilage followed by a thick cellulosic secondary cell wall.

265 tio associated with greater thickness of the cellulosic secondary wall.

266 late with the irreversible deposition of non-cellulosic species (either reaction side products or den

267 al, maize can provide both starch (seed) and cellulosic (stover) material for bioethanol production.

268 M-GSH-CuNCs was chemically adsorbed over the cellulosic strips and applied for the naked-eye detectio

269 shown to promote targeted disruption of the cellulosic structure at fiber dislocations.

270 vern the formation and assembly of fibrillar cellulosic structures and cell wall composites during or

271 ostable chimeras assayed hydrolyze the solid cellulosic substrate Avicel at temperatures at least 5 d

272 d complete digestion of hemicellulose on the cellulosic substrate by acid.

273 oducts or denatured enzymes, or both) on the cellulosic substrate surface.

274 nto the structural dynamics occurring on the cellulosic substrate through cellulase action.

275 endoglucanase to completely release, from a cellulosic substrate, glucose which can then be fermente

276 in surface-exposed crystalline areas of the cellulosic substrate.

277 to the controls when assayed on an insoluble cellulosic substrate.

278 G and CBH II, CBH I was poorly active on the cellulosic substrate.

279 e purified and assayed for activity on three cellulosic substrates and 2, 4-dinitrophenyl-beta-D-cell

280 ed enzymes during growth of the bacterium on cellulosic substrates compared to cellobiose.

281 tic bacterium capable of directly converting cellulosic substrates into ethanol.

282 vity patterns, various binding capacities on cellulosic substrates, and different synergies with pivo

283 On biochemical analysis with cellulosic substrates, seven of the gene products (Ra018

284 elivery of vaccines to the deconstruction of cellulosic substrates.

285 hough no activity was observed on a range of cellulosic substrates.

286 which 57% were enzymatically active against cellulosic substrates.

287 d, and processively released cellobiose from cellulosic substrates.

288 s insights into the degradation mechanism of cellulosic substrates.

289 reat difficulty degrading highly crystalline cellulosic substrates.

290 catalytic activity of the LPMOs against the cellulosic substrates.

291 g modules (CBMs) that preferentially bind to cellulosic substructures were fluorescently labeled.

292 ilization pathway, engineered yeast converts cellulosic sugars and toxic levels of acetate together i

293 i-ferulic acid phenolics, hemicellulosic and cellulosic sugars.

294 The biofilms attached strongly to cellulosic surfaces and, despite the growth limitation,

295 hanol for fuel will almost certainly require cellulosic technology.

296 tion of an exceptional collection of ancient cellulosic textiles recovered in the ancient Near East (

297 evidence for a single origin of the group's cellulosic theca, which we show coincided with a radiati

298 serve as a template for the assembly of the cellulosic wall which, in turn, controls cell expansion.

299 , which results in the deposition of ordered cellulosic walls.

300 In a cementitious disposal system, cellulosic waste items present in ILW may undergo alkali