ライフサイエンスコーパス: bioprocess

1 energy fuels by cost-effective 'consolidated bioprocesses'.

2 the productivity or efficiency of a biofuel bioprocess.

3 ajor advance toward realizing a consolidated bioprocess.

4 s to one or a group of cells involved in the bioprocess.

5 directly optimise the output of a co-culture bioprocess.

6 he economic competitiveness of our developed bioprocess.

7 peptide ligands for on-line IgG detection in bioprocesses.

8 ces in transcriptome studies of cell culture bioprocesses.

9 ncreasingly used for rational improvement of bioprocesses.

10 ious applications in upstream and downstream bioprocesses.

11 ar level and will drive the design of future bioprocesses.

12 the microbes from wastewater for industrial bioprocesses.

13 required for successful commercialization of bioprocesses.

14 significant proportion of cell death in many bioprocesses.

15 on-line monitoring of fermentation and other bioprocesses.

16 earch, as well as for controlling industrial bioprocesses.

17 key to the development of robust, high-yield bioprocesses.

18 able end products may be applicable to other bioprocesses.

19 tand their unique functions in a plethora of bioprocesses.

20 mize, and design new strategies for improved bioprocesses.

21 strating its application potential for other bioprocesses.

22 (2), to support sustainability of industrial bioprocesses.

23 r RNAs (mRNAs), plays critical roles in many bioprocesses.

24 development of robust and optimal stem cell bioprocesses.

25 rve signals aside from several other crucial bioprocesses.

26 ic biomass into ethanol through consolidated bioprocessing.

27 mation, and genetic stability for continuous bioprocessing.

28 have significant implications for downstream bioprocessing.

29 ethods for protein product monitoring during bioprocessing.

30 of the protein isolates were not affected by bioprocessing.

31 its monitoring is critical in healthcare and bioprocessing.

32 emerged as an attractive route for chemical bioprocessing.

33 for applications in health, agriculture, and bioprocessing.

34 nt biomass could be harnessed for industrial bioprocessing.

35 erscores the importance of host selection in bioprocessing.

36 a strain with improved potential for lignin bioprocessing.

37 compared to the protein isolate made without bioprocessing.

38 ergent enzyme candidates for lignocellulosic bioprocessing.

39 industrial enzymes in use for lignocellulose bioprocessing.

40 lation will have wide applications for yeast bioprocessing.

41 uction and quality of recombinant protein in bioprocessing.

42 render lignocellulose less recalcitrant for bioprocessing.

43 uch more relevant (19.1-fold) than enzymatic bioprocessing (1.8-fold).

44 ce between the strategies was that enzymatic bioprocessing accelerated ferulic acid release, while th

45 vide essential functional regulation of many bioprocesses across all scales of life; however, new tec

46 um or larger diameters is a common method in bioprocessing analytics.

47 recycling the biowastes promotes sustainable bioprocess and circular bioeconomy.

48 lone unit when integrated with the anaerobic bioprocess and demonstrated that we can selectively extr

49 Technoeconomic analysis of the bioprocess and downstream processing predicted a beta-ke

50 ng those HCPs that are retained throughout a bioprocess and HCPs can co-elute with the target product

51 aluable organic molecules combining multiple bioprocesses and metal-catalyzed transformations.

52 rasts markedly with the complexity of extant bioprocesses and provides a new paradigm for the use of

53 herent small scale and capital efficiency of bioprocesses and the ability of engineered biocatalysts

54 alyses were used to identify key regulators, bioprocesses and transcriptional networks controlling lu

55 The findings provide insights into low-cost bioprocesses and underscore the importance of sustainabl

56 compounds from whole-wheat breads: enzymatic bioprocessing and addition of green coffee infusion.

57 Bioprocessing and biotechnology exploit microorganisms (

58 anding in this area of crucial importance in bioprocessing and further discusses strategies for harne

59 ndustrial cleaning processes, biomedical and bioprocessing and many more.

60 onstrates the functional potential of DOL in bioprocessing and provides insight into the rational des

61 mifications for the fields of biotechnology, bioprocessing and synthetic biology.

62 ally improve the economics of lignocellulose bioprocessing and utilization.

63 Understanding key biological processes (bioprocesses) and their relationships with constituent b

64 cted functionally related genes, mapped core bioprocesses, and identified pleiotropic genes, whereas

65 entified cell type specific gene signatures, bioprocesses, and key regulators.

66 ling is too infrequent to fully characterize bioprocesses, and the typical time from sample generatio

67 nt study systemically mapped key regulators, bioprocesses, and transcriptional networks controlling l

68 enzymes underpins development of biosensing, bioprocessing, and analytical chemistry tools.

69 nd bioactivity of cloudberry was modified by bioprocessing, and highly bioactive fractions were produ

70 development of diagnostic assays, sequential bioprocessing, and lab assays in both traditional and mi

71 Most mono- and co-culture bioprocess applications rely on large-scale suspension f

72 ful use of growth factors in therapeutic and bioprocessing applications requires overcoming two atten

73 ical relevance to chemoorganotrophic mineral bioprocessing applications, and, to the best of our know

74 In addition to bioprocessing applications, GMD technology should benefi

75 lding and optimizing synthetic consortia for bioprocessing applications.

76 ful in disease diagnosis, drug screening and bioprocessing applications.

77 factories, is a major concern for industrial bioprocessing applications.

78 ory mechanisms would expedite development of bioprocessing applications.

79 ultrasonication is central to biomedical and bioprocessing applications.

80 ally attractive Next-Generation Consolidated BioProcessing approach where a single species is suffici

81 Based on this feature, bioprocesses are being developed for the microbial elect

82 However, bioprocesses are difficult to capture because they may o

83 tool, with many emerging applications in the bioprocessing arena.

84 lements critical to modern technologies view bioprocessing as a promising alternative or adjunct to n

85 cies interactions, food production, and drug bioprocessing, as well as playing less heroic roles as d

86 eactors become available and high-throughput bioprocessing becomes a reality.

87 tion of metabolic load by compartmentalising bioprocesses between multiple sub-populations.

88 esis and lipid accumulation, and the extract bioprocessed, "Biotransformed" extract could be used to

89 ferase 4 (PRMT4) was incorporated in various bioprocesses, but its role in renal injuries has not bee

90 nitrifying biological phosphorus (P) removal bioprocesses, but the roles of differential denitrificat

91 deling are two such approaches that optimize bioprocesses by better understanding and predicting glyc

92 ol for studying the stimulation of anaerobic bioprocesses by bioavailable essential trace metals.

93 Bioprocesses can potentially provide a solution to the n

94 strategies to augment living materials with bioprocessing capabilities.

95 sortia in separate microgels, the collective bioprocessing capability of the scaffold is significantl

96 differences of functional potentials of some bioprocesses caused by differing environmental condition

97 andidate for the realization of consolidated bioprocessing (CBP) and is known as an industry standard

98 The consolidated bioprocessing (CBP) of corn stover pretreated via ammoni

99 most research efforts to date, consolidated bioprocessing (CBP)--featuring cellulase production, cel

100 o ethanol in a process known as consolidated bioprocessing (CBP).

101 efficient product recovery are long-standing bioprocess challenges.

102 zed to identify alterations originating from bioprocess changes and to determine the impact of assemb

103 Germination represents a vital bioprocess characterized by numerous biochemical transfo

104 ed to predict the performance of the DAC and bioprocess components.

105 hus established that can be used to optimize bioprocessing conditions and identify useful genetic man

106 ust nanoCLAMP scaffold compatible with harsh bioprocessing conditions.

107 for acid pretreatment and thereby facilitate bioprocess consolidation.

108 a hybrid form was shown to perform well for bioprocess control applications.

109 Thus, glutamine monitoring is important in bioprocess control.

110 se stresses reduce productivity and increase bioprocess costs.

111 ess development and production enables rapid bioprocess decision-making and process optimization.

112 emerging as a means to increase the speed of bioprocess design and reduce material requirements.

113 rocess information early on, so as to inform bioprocess design and speed translation to the manufactu

114 nd environmental traits with improvements in bioprocess design.

115 By acknowledging these and using bioprocess-design information based on fundamental studi

116 responses and apply these to high-throughput bioprocess development and monitoring of cellular health

117 nalysis and provides an improved support for bioprocess development and product purity assessment.

118 acturing option with benefits both for phage bioprocess development at the engineering run research s

119 on of microbial metabolism to accelerate the bioprocess development cycle is recognized.

120 oduction profiles toward acceleration of the bioprocess development cycle.

121 A key step in bioprocess development for monoclonal antibodies (mAbs)

122 re productivity has shifted the attention of bioprocess development to operations downstream of the p

123 ed under similar time constraints to support bioprocess development, scaleup and formulation.

124 the utility of recombinant Pp for commercial bioprocess development.

125 Real-time monitoring of bioprocess during operation is a prerequisite for unders

126 encies of polyvalent immunoglobulins but the bioprocessing ease and stability of immunoglobulin G (Ig

127 nsiderable obstacles, including scalability, bioprocessing efficiency, and resilience to climate chan

128 for proteins beyond antibodies would improve bioprocessing efficiency.

129 hat recent developments in material science, bioprocess engineering and protein science continue to o

130 to design experiments and workflows from the bioprocess engineering community, we outline a framework

131 ng with the microbiology and ending with the bioprocess engineering studies that already have been pe

132 lations remains a critical bottleneck within bioprocess engineering, notably by undermining bioproduc

133 roduction of food flavoured chemicals by the bioprocess engineering.

134 cs and metatranscriptomics to a denitrifying bioprocess enriched in as-yet-uncultivated denitrifying

135 erapies require extensive use of inefficient bioprocessing equipment and specialized reagents that ca

136 sed bed bioreactor, together with single-use bioprocessing equipment, with complete control of nutrie

137 ate, presenting a target for optimization of bioprocesses exploiting this hydrocarbon-production path

138 ngement, synthesis of bioactive compounds in bioprocessed flours and slight reduction in the crystall

139 The results are suggestive that bioprocessed flours could serve as potential ingredients

140 Bioprocessed flours exhibited degraded protein matrix; h

141 Bioprocessed flours were characterized by altered functi

142 e of industries, such as water purification, bioprocessing, food processing and chemical production(1

143 This research aimed to develop a bioprocess for branched medium chain fatty acids (MCFAs)

144 , we developed an efficient and solvent-free bioprocess for the synthesis of a phenolic ester of DHA.

145 on operation (CANDO) is a promising emerging bioprocess for wastewater treatment that enables direct

146 ovide a framework for further development of bioprocesses for biomass utilization, organopollutant de

147 d expanded fuel upgrading worldwide, because bioprocesses for fuel upgrading do not require hydrogen

148 d lead to the development of energy positive bioprocesses for sustainable wastewater treatment.

149 sustainability, prompting the exploration of bioprocesses for the production of chemicals.

150 of MTB physiology will allow development of bioprocesses for the production of magnetosomes, and wil

151 n, enabling further developments of low-cost bioprocesses for the production of these valuable compou

152 These bioprocessed grape pomaces with significant amounts of c

153 ntification of anti-SARS-CoV-2 antibodies in bioprocess harvests and intermediate fractions (i.e., a

154 The use of microbial consortia for bioprocessing has been limited by our ability to reliabl

155 r in a complex environment during industrial bioprocessing has traditionally relied on labor-intensiv

156 ion of specific host cell proteins (HCPs) in bioprocess, however, has yet to be well established.

157 xhibit indistinguishable potency compared to bioprocessed IgG and protect against lethal pneumonia in

158 olomics data to identify genetic targets for bioprocess improvement in a more streamlined way.

159 etabolic activity compared to an unoptimised bioprocess in a minimal number of bioreactor experiments

160 ct, obtained from citrus industrial residue, bioprocessed in order to generate a commercial source of

161 cous forces, cilia drive a number of crucial bioprocesses in all vertebrate and many invertebrate org

162 Such bioevents are often used to refer to bioprocesses in text, which current techniques, relying

163 of a thermoreversible hydrogel scaffold, the bioprocessing including iPSC expansion, iPSC differentia

164 nd plays important roles in almost all vital bioprocesses, including cancer development.

165 The bioprocessing increased the protein (up to 80%) and fat

166 t, and lipid metabolism/transport were major bioprocesses induced during the saccular stage of lung d

167 th cases the aim is to generate quantitative bioprocess information early on, so as to inform bioproc

168 This study provides new insights towards the bioprocess integration, enabling further developments of

169 rlying dynamic regulation mechanisms for PHA bioprocess is a bottleneck owing to surfeit model comple

170 Moreover, a bioprocess is often composed of a series of bioevents, w

171 However, a challenge facing bioprocesses is cost competitiveness with chemical proce

172 Development of such bioprocesses is enabled by recent advances in genomics,

173 For bioprocesses, key performance indicators are the concent

174 to elucidate the relationship between these bioprocess level events and HEK293T cell metabolism.

175 rect effect on the responses observed at the bioprocess level.

176 Bioprocess limitations imposed by microbial cell-to-cell

177 Subsequent enrichment-based bioprocess mapping revealed alterations in phase I/II me

178 Germination has been proposed as an adequate bioprocessing method to improve seed protein digestibili

179 The effect of three combinations of bioprocessing methods by lactic acid fermentation, cell

180 Conventional bioprocess models for wastewater treatment are based on

181 glucose levels has potential applications in bioprocess monitoring and in minimizing health complicat

182 es such as those found in up- and downstream bioprocess monitoring and similar challenging applicatio

183 Bioprocess monitoring can improve the understanding and

184 Examples include bioprocess monitoring of bacterial cultures and measurem

185 lved oxygen remain the most commonly used in bioprocess monitoring, but continued research has result

186 as, such as medicine, biology, oceanography, bioprocess monitoring, corrosion studies, on the use of

187 assays for a wide variety of applications in bioprocess monitoring, food safety, and biological threa

188 amperometric biosensors in environmental or bioprocess monitoring, for example for in situ detection

189 oyment of SEC assays are warranted, enabling bioprocess monitoring, purity assessment, and characteri

190 phy, making it applicable to high-throughput bioprocess monitoring.

191 ntal monitoring, biomedical diagnostics, and bioprocess monitoring.

192 To characterize this, we introduce bioprocessing noise and identify its epigenetic origins.

193 x interactions highlights the possibility of bioprocessing of extraterrestrial metal resources and re

194 The definition of clean bioprocessing of foods should relate to the discharge of

195 ng it an efficient host for the consolidated bioprocessing of lignin, and it also lacks the ability t

196 ineering of microbial hosts for consolidated bioprocessing of lignocellulose.

197 Bioprocessing of lingonberries with enzymes, lactic acid

198 However, the bioprocessing of oxide ores such as laterites lags comme

199 am processing will all positively impact the bioprocessing of viral vectors.

200 one-pot conversion strategy or, consolidated bioprocessing, of biomass into ethanol would provide the

201 l represents a new paradigm for consolidated bioprocessing, offering the potential for carbon neutral

202 The impact of bioprocessing on lingonberry flavour was studied by sens

203 sludges as seed material for sulfur-reducing bioprocesses operated at hyperthermoacidophilic conditio

204 he approach involves the study of individual bioprocess operations at the microlitre scale using eith

205 ns that include the monitoring of industrial bioprocessing operations, food safety analyses, disease

206 a slow adoption of PAT tools into industrial bioprocessing operations, particularly in the manufactur

207 or the identification of genetic targets for bioprocess optimisation.

208 rain engineering targets that can accelerate bioprocess optimisation.

209 hat produce ectoine with CO(2) still require bioprocess optimization and resilient microorganisms abl

210 experimental comparability, reproducibility, bioprocess optimization and scale-up.

211 While cell line engineering and bioprocess optimization have yielded high protein titers

212 tion system is a successful demonstration of bioprocess optimization under photobioreactor conditions

213 In the near future, bioprocess optimization will change paradigms as massive

214 t and monoclonal antibody (mAB) discovery to bioprocess optimization.

215 ch (PMM), remains a substantial challenge in bioprocess optimization.

216 an organism-for example for the purposes of bioprocessing or synthetic biology-limiting resources ma

217 xpression and the repression of the microRNA bioprocessing pathway during glucocorticoid-induced apop

218 Here we demonstrate that the bioprocess performance and stability can be improved and

219 ll lines that will facilitate enhancement of bioprocess performance.

220 mic profiles of cancer to gain insights into bioprocesses perturbed during tumor development and prog

221 To illustrate the bioprocessing potential of this consortium, we demonstra

222 This economically feasible bioprocess produced molar flow rates of 4550 mol per day

223 ore the importance of focusing on food waste bioprocessing products to expand the range of alternativ

224 Generally, the bioprocessed protein isolate had lower protein solubilit

225 ration, by understanding the relationship of bioprocess - protein structure - functionality - amphiph

226 and starch gel (SG), for the development of bioprocesses related to enzyme applications.

227 Host cell proteins (HCPs) are bioprocess-related impurities arising from cell-death or

228 lecular underpinnings of complex biomass and bioprocessing-related traits.

229 Fermentation-based bioprocesses rely extensively on strain improvement for

230 n proteomics are enriching biotechnology and bioprocessing research across a wide spectrum of applica

231 Further development of this bioprocess resulted in uncoupling the pHCA and pHS produ

232 loped for the quantitation of polysorbate in bioprocess samples.

233 lications such as the design of more complex bioprocessing strains and aid in identifying new antimic

234 e to toxic chemicals--could lead to superior bioprocessing strains.

235 y glucose and xylose, offering a sustainable bioprocessing strategy for WB valorization and supportin

236 Many current bioprocess streams depend on the genetic tractability of

237 Conversely, bioprocess streams for lignin transformation remain embr

238 functional importance in various fundamental bioprocesses, studies of N(6)-methyladenosine (m6A) in t

239 located in genes with functions relevant to bioprocessing, such as apoptosis.

240 for model root systems and have promise as a bioprocessing system.

241 l for implementation in ionic solution based bioprocessing systems.

242 This article provides an overview of current bioprocessing techniques that could be used to generate

243 icle presents a range of methods for finding bioprocess terms and events.

244 In this decade, bioprocesses that offer either a process or a product ad

245 rtant enzyme in human physiology involved in bioprocesses that trigger collagen cross-linking and blo

246 s work aimed to study the metals released by bioprocessing the Panasqueira mine tailings, as a strate

247 bility of the urine influent composition and bioprocess, the electrochemical cell was steered via a c

248 functional importance in various fundamental bioprocesses, the studies of m(6)A in cancer have been l

249 , with current cell culture technologies and bioprocessing, the cost for biomanufacturing clinical-gr

250 losic biomass reserves and the difficulty in bioprocessing them without expensive pretreatment and fu

251 poson activation, stress response, and other bioprocesses, there are some discrepancies in the curren

252 ion helps in decision-making about the ideal bioprocessing time.

253 hat can potentially be used for consolidated bioprocessing to convert chitin to value-added chemicals

254 feedstock pretreatment and hydrolysis during bioprocessing to release soluble sugars.

255 toxins should be aimed at targeting remedial bioprocessing to safe limits as stipulated by regulatory

256 he results obtained in this study can direct bioprocessing to the desired quality attributes based on

257 the sulfur content have promoted studies of bioprocessing to upgrade fossil fuels.

258 hat the contribution of microbially mediated bioprocesses toward maintenance of life on earth is vita

259 ombined with other thermal, non-thermal, and bioprocessing treatments to enhance their efficiency.

260 d as safe" material with minimal, low-energy bioprocessing, two independent aquaculture trials were p

261 key barrier to this advancement is a lack of bioprocess understanding that would enable the design an

262 ng shell waste and an enzymatic/fermentative bioprocess using metabolically engineered Escherichia co

263 A bioprocess using oxygenic photogranules is an attractive

264 olution for non-invasive glucose sampling in bioprocesses using microdialysis sampling technique.

265 ve the potential to enable a new paradigm of bioprocessing using synthetic microbial consortia.

266 A sustainable bioprocess was developed for the valorization of a no/lo

267 The bioprocess was verified using both recombinant (Escheric

268 To facilitate the protection of bioprocesses, we explored the basis for the susceptibili

269 to its proposed role in extracellular NAD(+) bioprocessing, we found that recombinant human CD73 only

270 rties might be useful as parts of a two-step bioprocess where an initial kinetic resolution is follow

271 e Bacillus marmarensis as a platform for new bioprocesses which meet all these challenges.

272 oduct-monitoring technology for a particular bioprocess will depend on a variety of assay factors and

273 CCAs (MCCA oil) by integrating the anaerobic bioprocess with membrane-based liquid-liquid extraction

274 of an Escherichia coli succinate production bioprocess with this methodology revealed three signific

275 ectrophoretic pattern of the protein isolate bioprocessed with added enzymes.

276 The goal when imaging bioprocesses with optical microscopy is to acquire the m

277 f the protein isolates was nearly doubled by bioprocessing with cell wall hydrolyzing enzymes and phy

278 ling tools in the design and optimization of bioprocesses, with the emphasis on the effect on process

279 Bioprocessing, with the consequent economies of scale, i

280 screen on the Tecan Freedom EVO200 automated bioprocess workstation led to identification of ion exch