ライフサイエンスコーパス: biotechnology

1 nd describes the early years of agricultural biotechnology.

2 dicinal chemistry and structural biology and biotechnology.

3 that are used within industrial and medical biotechnology.

4 dal systems for use in materials science and biotechnology.

5 well as for developing new photoswitches for biotechnology.

6 ements of semiconductor microfabrication and biotechnology.

7 ial communities are increasingly utilized in biotechnology.

8 outine applications in molecular biology and biotechnology.

9 ential for applications in basic science and biotechnology.

10 tical utility in functional biomaterials and biotechnology.

11 ion network design to quantitatively improve biotechnology.

12 itol, each a rare sugar that is important in biotechnology.

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

14 ol is a significant challenge in biology and biotechnology.

15 engineering of designed bionanoreactors for biotechnology.

16 found widespread use in chemical biology and biotechnology.

17 energy density is an important goal in algal biotechnology.

18 abolically diverse, with great potential for biotechnology.

19 xciting trend that promises to revolutionize biotechnology.

20 pplicability for research, therapeutics, and biotechnology.

21 f a synthetic LacI/GalR repressor for use in biotechnology.

22 ts biosynthesis has remained a challenge for biotechnology.

23 ions) is an important consideration in algal biotechnology.

24 of great relevance to biology, medicine and biotechnology.

25 read adoption in organic optoelectronics and biotechnology.

26 in basic science, materials engineering, and biotechnology.

27 e as a platform microorganism for industrial biotechnology.

28 rich biochemical and enzymatic resource for biotechnology.

29 -rich nanomaterials for future translational biotechnology.

30 full potential of this simple and successful biotechnology.

31 Immobilized BsMa has a great potential for biotechnology.

32 catalysis, electronics, nanotechnology, and biotechnology.

33 general use of CFPS in synthetic biology and biotechnology.

34 r application of functional nanomaterials in biotechnology.

35 es in the origin of life, extant biology, or biotechnology.

36 development, and new tools for breeding and biotechnology.

37 s are enabling new approaches in science and biotechnology.

38 ted SAM in the areas of material science and biotechnology.

39 e enzyme to be more effectively exploited in biotechnology.

40 can keep pace with the rapid improvements to biotechnology.

41 for broader application across medicine and biotechnology.

42 ractive candidate for future applications in biotechnology.

43 ng of amyloidogenic proteins in medicine and biotechnology.

44 es make birch an attractive model for forest biotechnology.

45 accelerate comparative biology, breeding and biotechnology.

46 ethionine is of major interest in industrial biotechnology.

47 in molecular biology, synthetic biology, and biotechnology.

48 ield of metabolic engineering and industrial biotechnology.

49 le for the improvement of sugar cane through biotechnology.

50 of great relevance to biology, medicine and biotechnology.

51 istematic tissue) is widely applied in plant biotechnology.

52 olecules represent a key goal for industrial biotechnology.

53 sight for improving cotton using miRNA-based biotechnology.

54 ry diverse areas such as optoelectronics and biotechnology.

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

56 become powerful tools for basic research and biotechnology.

57 potential to make a dramatic impact on plant biotechnology.

58 rucial for advancing biological sciences and biotechnology.

59 ying human disease and protein production in biotechnology.

60 charide degraders in the environment and for biotechnology.

61 be efficiently controlled within eukaryotic biotechnology.

62 found widespread use in chemical biology and biotechnology.

63 with widespread applications in medicine and biotechnology.

64 f great value for industrial and therapeutic biotechnology.

65 es relevant to agriculture, human health and biotechnology.

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

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

68 tabolism is a topic of growing importance in biotechnology.

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

70 tonics, magnetic device, nanotechnology, and biotechnology.

71 otential of beta-oxidation mutants for algal biotechnology.

72 attractive material for optoelectronics and biotechnology.

73 ate demand for efficient vaccine development biotechnologies.

74 will expand the repertoire of microbe-based biotechnologies.

75 good candidates for toxic metal remediation biotechnologies.

76 is central to the carbon cycle and renewable biotechnologies.

77 National Cancer Institute and Adaptive Biotechnologies.

78 n expanding the scope of DNA-based nano- and biotechnologies.

79 embryos produced using assisted reproductive biotechnologies.

80 disc-based characterization methodologies or biotechnologies.

81 As 'omics' biotechnologies accelerate the capability to contrast a

82 pectacular advances in molecular biology and biotechnology achieved in the past two decades.

83 cause they are highly relevant to industrial biotechnologies and bioremediation applications.

84 ous lag phases occurring in microbiology and biotechnology and adjusts the generally accepted explana

85 ations for artificial selection protocols in biotechnology and argues for a better understanding of m

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

87 to diverse applications throughout medicine, biotechnology and basic biological research, there is an

88 late phenotypes of relevance to biomedicine, biotechnology and basic science.

89 olerance in bacteria, although important for biotechnology and bioenergy applications, remain incompl

90 osis resolution, accelerated improvements in biotechnology and bioinformatics are expected to improve

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

92 UK Medical Research Council, Wellcome Trust, Biotechnology and Biological Sciences Research Council,

93 UK Medical Research Council, Biotechnology and Biological Sciences Research Council,

94 electric fields is a versatile technique in biotechnology and biomedicine used, for example, in deli

95 heir applications are not only increasing in biotechnology and biomedicine, but also in the environme

96 nature and suggest possible applications in biotechnology and biomedicine.

97 iseases, and new rational design methods for biotechnology and biopharmaceutical applications.

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

99 systems, have proven to be invaluable in the biotechnology and dairy industries.

100 Amylases are of great importance in biotechnology and find application in fermentation, dete

101 They are used widely in biotechnology and food preservation, and are being explo

102 is a fundamental task in molecular biology, biotechnology and gene therapy.

103 In the debates surrounding biotechnology and genetically modified (GM) food, data f

104 I) has ushered in a new era of observational biotechnology and has facilitated the exploration of fun

105 ttractive approach in automated processes in biotechnology and health-care sciences where fast measur

106 e implemented into new application fields in biotechnology and life sciences.

107 creation of complex bioconjugates for use in biotechnology and materials applications.

108 operty studies, and advanced applications in biotechnology and materials science.

109 rties that make them well suited for several biotechnology and medical applications.

110 istries present in natural products (NP) for biotechnology and medicine remains untapped because NP d

111 entially wide application, including in both biotechnology and medicine.

112 ral transgene expression for applications in biotechnology and medicine.

113 logy and may also enable new applications in biotechnology and medicine.

114 ometry with diverse applications in biology, biotechnology and medicine.

115 x systems remains an obstacle to progress in biotechnology and metabolic engineering.

116 ncements in the synergetic interaction among biotechnology and microelectronics have advocated the bi

117 for accurate design of oligonucleotides for biotechnology and nanotechnology applications, but param

118 g biomedical research in academia and in the biotechnology and pharmaceutical industries.

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

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

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

122 ogrammed rearrangements of DNA molecules for biotechnology and synthetic biology.

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

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

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

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

127 Nature Medicine, Nature Biotechnology and the Volkswagen Foundation organized a

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

129 tinue to generate novel discoveries, broaden biotechnologies, and reveal profound mysteries to compel

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

131 us-based materials, focusing on the medical, biotechnology, and energy sectors.

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

133 urther application in the field of synthetic biotechnology, and for expanding the types of molecules

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

135 erous applications including basic research, biotechnology, and human gene therapy.

136 le in biogeochemical processes, agriculture, biotechnology, and human health.

137 targeting applications in molecular biology, biotechnology, and medicinal chemistry.

138 and RNA has a growing importance in biology, biotechnology, and medicine.

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

140 , translational medicine, synthetic biology, biotechnology, and other fields.

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

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

143 This emerging biotechnology appears to be promising for advancing tiss

144 asensitive luminescent probes for a range of biotechnology applications from biomarker discovery to s

145 We also touch on some potential biotechnology applications of an unusual compartment des

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

147 studies for a broad range of biomedical and biotechnology applications, including the treatment of a

148 ng aldehyde-tagged proteins for research and biotechnology applications, we developed methods for rec

149 s great potential for both basic science and biotechnology applications.

150 enriched source for mining novel enzymes for biotechnology applications.

151 ded to understand Earth's deep biosphere and biotechnology applications.

152 odern and ancient biology, and as a tool for biotechnology applications.

153 d is of major interest in the development of biotechnology applications.

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

155 hold tremendous value as reagents in future biotechnology applications.

156 ture may adversely impact basic research and biotechnology applications.

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

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

159 mportant for basic research and agricultural biotechnology applications.

160 abolic pathways paves the way for developing biotechnology approaches toward producing grindelic acid

161 or target for improvement using breeding and biotechnology approaches.

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

163 echnologic advances in molecular biology and biotechnology are increasingly being used for the develo

164 insight into this matter may be relevant to Biotechnology as well as Drug Development.

165 iology, with applications in all branches of biotechnology, as well as strategies for human therapeut

166 Synthetic constructs in biotechnology, biocomputing, and modern gene therapy int

167 try and sustainable development, that is, in biotechnology, biorefining, or biofuels.

168 -expression which finds vast applications in biotechnology, biosciences, and biomedicine.

169 sirable for applications in biochemistry and biotechnology but has eluded supramolecular chemists for

170 ctional roles in biology, nanotechnology and biotechnology, but current methods for autonomously synt

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

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

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

174 rial vegetable oils can be generated through biotechnology, but will likely require non-commodity oil

175 QMC has the potential to revolutionize biotechnology by introducing a new class of capture mole

176 ocess, despite its fundamental importance to biotechnology, cell biology, and pharmaceutics.

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

178 Trust within the biotechnology community creates vulnerabilities at the i

179 For science-based businesses, particularly biotechnology companies, a PhD in the life sciences can

180 maceutical, medical device, diagnostics, and biotechnology companies.

181 the potential importance of algae for green biotechnology, considerable effort has been invested in

182 Agricultural biotechnology continues to generate considerable controv

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

184 Renewables-based biotechnology depends on enzymes to degrade plant lignoc

185 y identifying and eliminating allergens from biotechnology-derived products are important for human h

186 phytoremediation techniques and for further biotechnology development, which can be better designed

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

188 s have found a wide range of applications in biotechnology due to their large water capacity, high bi

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

190 noparticle vehicles for many applications in biotechnology (e.g., vaccines, drug delivery, imaging ag

191 This TIPS mutation recreates the biotechnology-engineered commercial first generation gly

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

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

194 Termite biotechnology falls into two categories: (a) termite-tar

195 atory tools for use in synthetic biology and biotechnology fields.

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

197 nd are also relevant to metal immobilization biotechnologies for bioremediation, metal and P biorecov

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

199 udy demonstrate these approaches as platform biotechnologies for tissue reconstruction for repair, re

200 This is helpful to design miRNA-based biotechnology for improving fiber quality and yield.

201 ls into two categories: (a) termite-targeted biotechnology for pest management purposes, and (b) term

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

203 management purposes, and (b) termite-modeled biotechnology for use in various industrial applications

204 The peptide is also widely employed in biotechnology, for example, in the encapsulation of enzy

205 In the recent issue of Nature Biotechnology, Frock et al. (2015) developed an elegant

206 t genome meeting entitled 'Plant genomes and biotechnology: from genes to networks', held at Cold Spr

207 tunity to reflect on and revise agricultural biotechnology governance.

208 sequenced at the Hudson Alpha Institute for Biotechnology (HAIB, Huntsville, AL) using the Nimblegen

209 While recent advances in biotechnology have brought the opportunity for building

210 th of gene transfer and cell transplantation biotechnologies, have created optimism that previously b

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

212 y postulated requirements for granulation in biotechnology, i.e., the need for hydrodynamic shear and

213 the challenges and opportunities for mineral biotechnologies in the 21st century.

214 Gene editing is a rapidly developing area of biotechnology in which the nucleotide sequence of the ge

215 dation, Brian King Fellowship, and Avalanche Biotechnologies, Inc.

216 ntists, but also from the pharmaceutical and biotechnology industries.

217 through productive interactions between the biotechnology industry and academia.

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

219 ent and investment by the pharmaceutical and biotechnology industry.

220 concern for drug product development in the biotechnology industry.

221 xpression Omnibus at the National Center for Biotechnology Information (accession no: GSE70469).

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

223 ClinVar at the National Center for Biotechnology Information (NCBI) is a freely available a

224 he RefSeq project at the National Center for Biotechnology Information (NCBI) maintains and curates a

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

226 Microbial genomes at the National Center for Biotechnology Information (NCBI) represent a large colle

227 ystems, including the US National Center for Biotechnology Information (NCBI)'s Entrez Utilities (E-U

228 matics centers, the U.S. National Center for Biotechnology Information (NCBI), the European Bioinform

229 ion Omnibus (GEO) at the National Center for Biotechnology Information (NCBI).

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

231 lically available on the National Center for Biotechnology Information database of genotypes and phen

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

233 atasets available at the National Center for Biotechnology Information Genbank sequence data archive.

234 In the National Center for Biotechnology Information Gene Expression Omnibus valida

235 rcinoma accessed through National Center for Biotechnology Information Gene Expression Omnibus, as we

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

237 otein accession numbers, National Center for Biotechnology Information Gene identification numbers, b

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

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

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

241 The National Center for Biotechnology Information's (NCBI) Gene database (www.nc

242 unctional sites from the National Center for Biotechnology Information's conserved domain database (C

243 these sequences from the National Center for Biotechnology Information's GenBank database is problema

244 to proteins using RefSeq (National Center of Biotechnology Information, Bethesda, MD) and visualized

245 a resource hosted by the National Center for Biotechnology Information.

246 chiral amino acids, molecules of significant biotechnology interest.

247 Modern biotechnology is emerging at the intersection of enginee

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

249 de that the multi-heuristic nature of modern biotechnology makes it an engineering field primed for i

250 In recent times, with the advancement of biotechnology, molecular and immunological approaches ha

251 of bioparticle suspensions in the fields of biotechnology, molecular biology, drug discovery, and co

252 es play in the adaptive immune system and in biotechnology, much remains unknown about the quantitati

253 These technologies, including emerging biotechnologies, nanotechnologies, and microfluidics, ho

254 Convergences in biotechnology, nanotechnology, polymer chemistry, surfac

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

256 orters have been a Cinderella subject in the biotechnology of small molecule production, but this is

257 New biotechnologies offer a wide range of opportunities to r

258 Biotechnology offers a new sustainable approach to manuf

259 Modern biotechnologies often result in high-dimensional data se

260 risk assessment of RNAi-based gene silencing biotechnologies on non-target organisms; in this case, a

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

262 in academia have limited exposure to how the biotechnology/pharmaceutical industry approaches drug di

263 velopment of C. reinhardtii as an industrial biotechnology platform can be achieved more efficiently

264 wever, it is unclear whether this microbiome biotechnology platform is stable enough during long oper

265 velopment of C. reinhardtii as an industrial biotechnology platform, avoiding the process of incremen

266 is poised for exploitation as an industrial biotechnology platform.

267 Recent advances in nano-biotechnology play a significant role in providing possi

268 , flow reactor technologies, biomedicine and biotechnology, polymer composites, energy storage, and c

269 Recent reports in Nature Medicine and Nature Biotechnology present a creative bioengineering strategy

270 s could also have novel applications in nano-biotechnology processes.

271 rossflow filtration of beer, dairy foods and biotechnology products.

272 s the incorporation of genetic circuits into biotechnology projects that require decision-making, con

273 important part of many molecular biology and biotechnology projects.

274 The cyber-physical nature of biotechnology raises unprecedented security concerns.

275 ed to transform a wide and diverse swathe of biotechnology ranging from therapeutics and diagnostics

276 ons catalysed by lactobacilli is an untapped biotechnology resource.

277 rotein-producing factories in the industrial biotechnology sector.

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

279 and synthetic biology methods permeate many biotechnology specialties, the design of application-spe

280 -shaped particles could play unique roles in biotechnology, structural mechanics and self-assembly.

281 Modern high-throughput biotechnologies such as microarray are capable of produc

282 Emerging biotechnologies, such as RNA interference, could provide

283 ed with applications in chemical biology and biotechnology, such as target engagement, receptor pharm

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

285 Highly advanced industrial biotechnology systems using bacteria and yeasts were est

286 duces neo-FOS, which makes it an interesting biotechnology target.

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

288 first study in the context of environmental biotechnology that adopts and explores the use of extent

289 eathomics) is an exciting developing area of biotechnology that centers on the capture, identificatio

290 the international language; the red zone of biotechnology; the human side of biotechnology; the tran

291 red zone of biotechnology; the human side of biotechnology; the transgenic papaya story; and my leade

292 r functions, and highlight the potential for biotechnology to build on what nature provides.

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

294 ere, we try to summarize the contribution of biotechnology to our understanding, control, and cure of

295 ses of gene function and expanding the plant biotechnology toolkit beyond traditional constitutive ex

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

297 To further its use as an organism for biotechnology, we sequenced its genome and demonstrate g

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

299 in both termite-targeted and termite-modeled biotechnology will be to consider host and symbiont toge

300 ce enabled us to couple the robotics used in biotechnology with emerging mass spectrometry-based high