ライフサイエンスコーパス: biotechnology

1 nuclease sequences with implications across biotechnology.

2 ting of reusable enzymes that can be used in biotechnology.

3 ontrolled manner is an integral step in cell biotechnology.

4 lications ranging from energy to sensing and biotechnology.

5 and vacuum technology and even medicine and biotechnology.

6 d catalytic activity has long been a goal in biotechnology.

7 ental remediation, sensing, ionotronics, and biotechnology.

8 erotrophs hold great promise for sustainable biotechnology.

9 utilization as a carbon source for microbial biotechnology.

10 oorganisms are promising resources for green biotechnology.

11 to applications in clinical diagnostics and biotechnology.

12 applications in medicine, biomaterials, and biotechnology.

13 ions in advanced fluorescence microscopy and biotechnology.

14 rinciples of RNA folding and applications in biotechnology.

15 tion in genetics, developmental biology, and biotechnology.

16 for the design of pores with applications in biotechnology.

17 s of many natural and engineered proteins in biotechnology.

18 ng implications for human health and applied biotechnology.

19 in chemical biology, protein chemistry, and biotechnology.

20 growing intersection of computer systems and biotechnology.

21 d open up new opportunities, in medicine and biotechnology.

22 their potential applications in medicine and biotechnology.

23 erating their translation and application in biotechnology.

24 cation in microbial genetics, evolution, and biotechnology.

25 r applications in nucleic acid chemistry and biotechnology.

26 S assembly and aids its control as a tool in biotechnology.

27 ogy, and for the exploitation of enzymes for biotechnology.

28 e 5-100 nm scale for diverse applications in biotechnology.

29 pplicability for research, therapeutics, and biotechnology.

30 read adoption in organic optoelectronics and biotechnology.

31 e enzyme to be more effectively exploited in biotechnology.

32 es make birch an attractive model for forest biotechnology.

33 ry diverse areas such as optoelectronics and biotechnology.

34 Cancer Research UK, AstraZeneca, and Puma Biotechnology.

35 nger to our health and a stumbling block for biotechnology.

36 become powerful tools for basic research and biotechnology.

37 c devices for applications in healthcare and biotechnology.

38 potential to make a dramatic impact on plant biotechnology.

39 rucial for advancing biological sciences and biotechnology.

40 ying human disease and protein production in biotechnology.

41 charide degraders in the environment and for biotechnology.

42 be efficiently controlled within eukaryotic biotechnology.

43 found widespread use in chemical biology and biotechnology.

44 with widespread applications in medicine and biotechnology.

45 f great value for industrial and therapeutic biotechnology.

46 ems with potential benefits for medicine and biotechnology.

47 es relevant to agriculture, human health and biotechnology.

48 ols or as a high-rate, real-time remediation biotechnology.

49 tabolism is a topic of growing importance in biotechnology.

50 tonics, magnetic device, nanotechnology, and biotechnology.

51 netic variants that can advance agricultural biotechnology.

52 hway that serves as a novel tool for systems biotechnology.

53 d experimental avenues in plant research and biotechnology.

54 dous promise in nanomaterial fabrication and biotechnology.

55 ange of Cas9 applications in biomedicine and biotechnology.

56 riant library makes this a valuable tool for biotechnology.

57 nical anti-bacterial therapy, and industrial biotechnology.

58 inks to several diseases and applications in biotechnology.

59 hloroplasts valuable targets in agricultural biotechnology.

60 mers (MIPs) have received great attention in biotechnology.

61 old capable of dual emission with utility in biotechnology.

62 r plant genetic engineering and agricultural biotechnology.

63 w poised to transform the potential of plant biotechnology.

64 monitoring to drug discovery and industrial biotechnology.

65 ng from remediation of contaminated sites to biotechnology.

66 is central to the carbon cycle and renewable biotechnologies.

67 will expand the repertoire of microbe-based biotechnologies.

68 disc-based characterization methodologies or biotechnologies.

69 oad applications in biocatalysis and related biotechnologies.

70 ul means for the development of a variety of biotechnologies.

71 ties have numerous potential applications in biotechnology, agriculture, and medicine.

72 mework will rapidly advance microbiome-based biotechnologies aimed at improving human and animal heal

73 Enhanced precision over population-averaging biotechnologies and conventional microscopy demonstrates

74 heir (potential) application in medicine and biotechnology and as a potential source for new therapeu

75 insights gleaned from the recent advances in biotechnology and bioinformatics, emerging ideas centere

76 quisa, Economic and Social Research Council, Biotechnology and Biological Sciences Research Council,

77 ith implications for several human diseases, biotechnology and biomaterial sciences.

78 s and resulted in variety of applications in biotechnology and biomedicine.

79 ential candidate for various applications in biotechnology and biomedicine.

80 substrates, which may lead to new tools for biotechnology and biomedicine.

81 l, Economic and Social Research Council, and Biotechnology and Biosciences Research Council.

82 This RNAP class plays important roles in biotechnology and cellular energy production, but we kno

83 design efficient ligases with application in biotechnology and drug development.

84 ferent aspects of life science, biomedicine, biotechnology and drug discovery where protein associati

85 s studying Fundamental Biology, Biomedicine, Biotechnology and Energy.

86 ystem, and discuss potential applications in biotechnology and evolutionary biology.

87 n synthetic biology and have applications in biotechnology and genome engineering.

88 expands the range of chemicals accessible by biotechnology and has yielded the first commercial produ

89 rescence, are nothing short of ubiquitous in biotechnology and medical diagnostics today.

90 eins to living cells is a central problem in biotechnology and medicine.

91 activity has many practical applications in biotechnology and medicine.

92 ication in a variety of disciplines, such as biotechnology and medicine.

93 g as well as possible future applications in biotechnology and medicine.

94 ogy and could have practical applications in biotechnology and nanotechnology.

95 ferent environments are important factors in biotechnology and paleomagnetism.

96 Various academic groups as well as biotechnology and pharmaceutical companies are on the ve

97 racellular metabolism is the mainstay in the biotechnology and physiology settings.

98 animal testing to incorporating advances in biotechnology and predictive methodologies into alternat

99 hieve, yet it is crucial for applications in biotechnology and proteomics.

100 lular platform for translational research in biotechnology and regenerative medicine.

101 NA is used widely in studies of RNA biology, biotechnology and RNA therapeutics.

102 ors (aTFs) have proven widely applicable for biotechnology and synthetic biology as ligand-specific b

103 As the fields of biotechnology and synthetic biology expand, cheap and se

104 ge serine integrases are extensively used in biotechnology and synthetic biology for assembly and rea

105 as to those applications in basic research, biotechnology and synthetic biology that involve the mul

106 lysts for diverse applications in chemistry, biotechnology and synthetic biology.

107 rget binding offer powerful capabilities for biotechnology and synthetic biology.

108 ities to exploit gene and genome transfer in biotechnology and synthetic biology.

109 d broad applications in biomolecular design, biotechnology and synthetic biology.

110 function remains a considerable challenge in biotechnology and synthetic biology.

111 th improvements through breeding and through biotechnology and the engineering principles on which in

112 d-handling robots have many applications for biotechnology and the life sciences, with increasing imp

113 CRISPR-Cas9 genome editing has transformed biotechnology and therapeutics.

114 areas such as diagnostics, water treatment, biotechnology and therapeutics.

115 separation are found widely in agriculture, biotechnology, and advanced manufacturing; yet, the emer

116 cations in the fields of structural biology, biotechnology, and biopharmaceutics.

117 ee detection of biomolecules across medical, biotechnology, and environmental science applications.

118 duction of phage preparations into medicine, biotechnology, and food industry requires a thorough cha

119 cluding EndoH, an enzyme extensively used in biotechnology, and for which the mechanism of substrate

120 rticular, in medicine, ecology, agriculture, biotechnology, and forensics.

121 have been broadly adopted for basic science, biotechnology, and gene and cell therapy.

122 e today used throughout scientific research, biotechnology, and medicine, in part for their ability t

123 will find widespread use in basic research, biotechnology, and medicine.

124 Recent advances in materials, manufacturing, biotechnology, and microelectromechanical systems (MEMS)

125 ion process widely exploited for diagnostic, biotechnology, and nanotechnology applications.

126 highest production of valuable compounds for biotechnology, and sequencing.

127 e remarkable advancements in basic research, biotechnology, and therapeutics science that these devel

128 h limited resources to engage in chloroplast biotechnology, and to accelerate progress in the field,

129 ng of genetically reprogrammed organisms for biotechnology applications and research.

130 plant pathogen, CPMV is of major interest in biotechnology applications such as nanotechnology.

131 at may prove useful in novel therapeutics or biotechnology applications, we recast mechanisms control

132 n issue for industrial systems and synthetic biotechnology applications, which require good quality r

133 animal infections, and are relevant for nano-biotechnology applications.

134 he efficiency of phosphite uptake by HtxB in biotechnology applications.

135 gnals play an increasingly important role in biotechnology applications.

136 ne integration, into plant cells for diverse biotechnology applications.

137 t are attractive for protein engineering and biotechnology applications.

138 of switches suitable for a diverse range of biotechnology applications.

139 nd in nature and is thus used extensively in biotechnology applications.

140 caceus as new alternatives, in environmental biotechnology applications.

141 rmycin A1 derivatives for antibiotherapy and biotechnology applications.

142 ce the use of TNA monomers in exobiology and biotechnology applications.

143 hold tremendous value as reagents in future biotechnology applications.

144 sive species, and the safe study of emerging biotechnology applications.

145 HP-inducible system in synthetic biology and biotechnology applications.

146 trochemically produce chiral amino acids for biotechnology applications.

147 n harnessed for therapeutic purposes in many biotechnology applications.

148 or target for improvement using breeding and biotechnology approaches.

149 Quorum sensing-based biotechnologies are developed with the aims to fight aga

150 Novel biotechnologies are required to remediate iron ore mines

151 of using enlarge compartments in chloroplast biotechnology are discussed.

152 Optogenetics is an emerging biotechnology armed with the capacity to precisely modul

153 disturbances are relevant for environmental biotechnology as they can lead to alternative stable sta

154 atures leading to remarkable achievements in biotechnology as well as novel insights into biological

155 Here, we describe a biotechnology based on synthetic, biodegradable nanopart

156 ead application in biology, biomedicine, and biotechnology because its functions can be flexibly comb

157 is one of the most widely used proteases in biotechnology because of its exquisite sequence specific

158 itute essential tools for basic research and biotechnology because they activate gene expression only

159 roblems in fundamental biology, biomedicine, biotechnology, bioengineering, and bioenergy.

160 n diverse areas within analytical chemistry, biotechnology, biomedicine, and molecular biology.

161 Given the widespread use of TEV in biotechnology, both our evolved TEV mutants and the dire

162 arbon fixation, with potential importance in biotechnology, but have eluded a full description of the

163 lytic activities is a widely adopted tool in biotechnology, but is constrained by the requirements fo

164 on is a key molecular process in biology and biotechnology, but so far there is no predictive model f

165 esearchers from fields such as telemedicine, biotechnology, chemical sciences and environmental scien

166 needed, including biomedicine, agriculture, biotechnology/chemical industry, and cleaning utensils.

167 In this study, single-cell Raman biotechnology combined with deuterium isotope probing (R

168 Trust within the biotechnology community creates vulnerabilities at the i

169 d include new transgenic traits developed by biotechnology companies.

170 e analytical tools in the biosciences and in biotechnology, complementing and superseding existing co

171 In addition, recent progress in biotechnology contributes markedly to better engineering

172 st-line FCR treatment, we used NGS (Adaptive Biotechnologies Corporation) to assess MRD in 62 patient

173 Papers recently published in Nature Biotechnology describe two independent machine-learning-

174 The pharmaceutical and biotechnology developers are now challenged to find thei

175 may greatly advance clinical diagnostics and biotechnology development.

176 As algal biotechnology develops, there is an increasing requireme

177 represents an enormous untapped resource for biotechnology discovery programmes in an era where resis

178 NA cleavage have found broad applications in biotechnology, DNA computing and environmental sensing.

179 f healthcare delivery and recent advances in biotechnology-driven therapeutics and companion diagnost

180 e microbial system for molecular biology and biotechnology due to its remarkably short generation tim

181 cancer cells and plays an important role in biotechnology during production of proteins or metabolic

182 Biotechnology, emboldened by recent advances in syntheti

183 importance in both evolutionary biology and biotechnology, enabling horizontal gene transfer in the

184 ur research team demonstrated the utility of biotechnology-enhanced approaches for SIT by developing

185 lts have important implications in microbial biotechnology, especially for those responsible for the

186 nt actors often fear a 'public rejection' of biotechnology, especially regarding genetic modification

187 rent advanced applications (e.g. in coating, biotechnology etc.).

188 is, extraction, electrochemistry, analytics, biotechnology, etc.

189 sieving, which is a fundamental tool in the biotechnology field, can be automated using capillary ge

190 Here, we discuss the potential of biotechnology, focusing on microbes with a natural abili

191 e of the most energy-efficient environmental biotechnologies for nitrogen removal from wastewater.

192 l as a template to guide efforts to engineer biotechnology for carbon dioxide conversion.

193 (CRISPR/Cas9) system is emerging as a robust biotechnology for targeted-DNA mutation.

194 stabilization have potential applications in biotechnology for the development of systems exhibiting

195 aromatic nitration reaction may be useful in biotechnology for the synthesis of drugs or small molecu

196 em has implications in synthetic biology and biotechnology, for example, in applications for wastewat

197 h Institute of Molecular Animal Breeding and Biotechnology, Gene Center, LMU Munich, Munich, Germany)

198 Advancements within biotechnology, genetic engineering, and synthetic chemis

199 aced short-palindromic repeat (CRISPR)-based biotechnologies has revolutionized the life sciences and

200 The use of mRNA in biotechnology has expanded with novel applications such

201 Improved capacity of genomics and biotechnology has greatly enhanced genetic studies in di

202 a consequence, enhancing WUE by breeding or biotechnology has proven challenging but not impossible.

203 Advancement in nano-biotechnology has provided new paradigm for biosensor pl

204 genome designs and harnessing revolutionary biotechnologies have contributed substantially to the gr

205 Recent advances in CRISPR based biotechnologies have greatly expanded our capabilities t

206 Recent advances in biotechnology have improved the biological data to inclu

207 Advances in biotechnology have led to the development of a number of

208 ly enhancing microbial community function in biotechnology, health, and agriculture [13].

209 These biotechnologies highlight the potential to develop strat

210 Since the birth of biotechnology, hundreds of biotherapeutics have been dev

211 bles unrestricted use of streptavidin-biotin biotechnology in cellular uptake.

212 xploit the full power of streptavidin-biotin biotechnology in cellular uptake.

213 nstrate the advantages of using agricultural biotechnology in concert with classical pest control tac

214 as been exploited in various applications in biotechnology, in particular for the attachment of alkyl

215 ted interactions that occur in mixed-species biotechnologies, including biosensors, hinder chemical d

216 al assemblies is critical to applications in biotechnology, increasing the durability of enzymes in b

217 and beneficial use, it was a surprise to the biotechnology industry to discover an endemic rhabdoviru

218 henomenon is particularly problematic in the biotechnology industry, as production scale bioreactors

219 In the biotechnology industry, gram-negative bacteria (e.g., Es

220 ocess in academic research as well as in the biotechnology industry.

221 As of October 2016, the National Center for Biotechnology Information (NCBI) database contained >2 m

222 The National Center for Biotechnology Information (NCBI) is an archive providing

223 ited in Genbank from the National Center for Biotechnology Information (NCBI) is higher than the comp

224 The National Center for Biotechnology Information (NCBI) previously made availab

225 The National Center for Biotechnology Information (NCBI) provides a large suite

226 is approach on 2 popular National Center for Biotechnology Information (NCBI) repositories: Gene Expr

227 ets: (1) SALVIAS and (2) National Center for Biotechnology Information (NCBI) Taxonomy.

228 Res, 44:D48-50, 2016) - National Center for Biotechnology Information (NCBI), European Bioinformatic

229 base (UniProtKB) and the National Center for Biotechnology Information (NCBI).

230 publicly available at the National Center of Biotechnology Information (NCBI).

231 nd were submitted to the National Center for Biotechnology Information (NCBI).

232 We examined Ensembl and National Center for Biotechnology Information databases to identify availabl

233 xpression Omnibus at the National Center for Biotechnology Information for 120 peripheral blood monon

234 e MPS, we collected from National Center for Biotechnology Information Gene Expression Omnibus (NCBI-

235 mple is available at the National Center for Biotechnology Information Gene Expression Omnibus reposi

236 the dUTPase (DUT) gene (National Center for Biotechnology Information Gene ID 1854), affecting both

237 Staff from the National Center for Biotechnology Information in the US describe recent impr

238 eads were aligned to the National Center for Biotechnology Information nucleotide reference database

239 was performed using The National Center for Biotechnology Information PubMed online database, applyi

240 ndependent search of the National Center for Biotechnology Information PubMed, Medline, and the Cochr

241 Taxonomy of Viruses for National Center for Biotechnology Information virus RefSeq.

242 netic data stored in the National Center for Biotechnology Information's (NCBI's) Sequence Read Archi

243 quences repositories like National Center of Biotechnology Information's GenBank for downstream analy

244 Comparison with the National Center for Biotechnology Information's Pathogen Detection database

245 s currently in the NCBI (National Center for Biotechnology Information) database(4) increased by more

246 We searched PubMed (National Center for Biotechnology Information), Embase (Elsevier), and CINAH

247 tic analysis of GenBank (National Center for Biotechnology Information, Bethesda, MD, USA) DNA sequen

248 epresents a promising target for breeding or biotechnology intervention strategies as gene knockdown

249 Chloroplast biotechnology is a route for novel crop metabolic engine

250 Yet, the sustainability potential of biotechnology is not without trade-offs.

251 The promise of biotechnology is tempered by its potential for accidenta

252 In Nature Biotechnology, Koehler et al. (2017) have developed a hu

253 biofouling is attractive for applications in biotechnology, medicine and heat transfer(1-10).

254 d significantly expand their applications in biotechnology, medicine, and research.

255 in guiding efforts in metabolic engineering, biotechnology, microbiology, human health, and cell cult

256 abling technologies to the market, including biotechnologies, microfluidics, advanced materials, biom

257 With advances in the field of biotechnology, microfluidics and nanotechnologies, many

258 : UK Medical Research Council; Department of Biotechnology, Ministry of Science & Technology, Governm

259 Complex economic activities, such as biotechnology, neurobiology and semiconductors, concentr

260 layers in the global carbon cycle and in the biotechnology of anaerobic digestion.

261 New biotechnologies offer a wide range of opportunities to r

262 nes, foreshadowing potential applications to biotechnology or biomedicine.

263 ein-surface interactions in both biology and biotechnology, our understanding of their origins is lim

264 New advances in genomic biotechnologies-particularly CRISPR-based tools-have rev

265 ions for the design of phage applications in biotechnology, phage therapy and the evolutionary dynami

266 to impact many scientific fields, including biotechnology, pharmaceuticals, and clinical sciences.

267 ns in environmental monitoring, food safety, biotechnology, pharmaceuticals, and healthcare.

268 ed in a wide range of applications including biotechnology, pharmacy, and medicine.

269 any different disciplines, such as medicine, biotechnology, physics and biocomputing.

270 e the identification of ecological roles and biotechnology potential of uncultured microbial groups.

271 ractions impact ecosystems, human health and biotechnology profoundly.

272 d of faculty, staff, and trainees across the biotechnology quad at Georgia Institute of Technology, s

273 activate sigma(54)-dependent promoters with biotechnology relevance in non-model bacteria.

274 the ODX has a wide range of applications in biotechnology research and industry.

275 iscovery, vaccine design, and biomedical and biotechnology research.

276 rotein-producing factories in the industrial biotechnology sector.

277 xenobiotics, a feature that is valuable in a biotechnology setting.

278 al properties that promote their use in many biotechnology settings.

279 found in AFV1 also has many implications for biotechnology, since this membrane can survive the most

280 The combination of modern biotechnologies such as DNA synthesis, lambda red recomb

281 utilizing these mechanisms in environmental biotechnologies such as element biorecovery and bioferti

282 eable and applicable to many areas of modern biotechnology such as DNA hybridization chip microarrays

283 ls.gov NCT02453048, NCT00870350.FUNDINGILiAD Biotechnologies, Swedish Research Council (Vetenskapsrad

284 epeat) endonucleases are at the forefront of biotechnology, synthetic biology and gene editing.

285 make them potentially very advantageous for biotechnology/synthetic biology applications.

286 approaches to vaccine development use novel biotechnology, target new mechanisms, and shape the immu

287 cy of disease-causing microorganisms; and in biotechnologies that operate at the limits of microbial

288 In the field of protein engineering and biotechnology, the discovery and characterization of str

289 diverse applications, ranging from cell-free biotechnology to biomedicine.

290 lication of synthetic biology to chloroplast biotechnology to generate plants capable of producing ne

291 ated to protein adsorption, from medicine to biotechnology to heterogeneous nucleation, the question

292 ntific advancements, ranging from industrial biotechnology to innovations in bioenergy and medical in

293 FGE has emerged as an enabling biotechnology tool due to the robust utility of the alde

294 Modern phenomic and biotechnology tools will facilitate these enquiries.

295 While novel biotechnology undoubtedly offers benefits, like all new

296 Successful commercialization of any biotechnology usually requires accurate characterization

297 al investigator at the Flemish Institute for Biotechnology (VIB) in Belgium, and her laboratory focus

298 rowing interest in several fields, including biotechnology, wastewater monitoring, and nanobubble pre

299 ce in cellular processes and abundant use in biotechnology, we lack a detailed understanding of the k

300 how they escape host proteins, their uses in biotechnology, where they are found in nature, and their