ライフサイエンスコーパス: bioengineering

1 /or complementary solutions, such as corneal bioengineering.

2 cells would be of great use in medicine and bioengineering.

3 e in research areas ranging from taxonomy to bioengineering.

4 vored platform in the field of complex organ bioengineering.

5 f synthetic biology, functional genomics and bioengineering.

6 invaluable technique for glycan analysis and bioengineering.

7 ntiation offers a targeted method for tissue bioengineering.

8 terized DNA parts that will accelerate plant bioengineering.

9 ations in liquid separations, catalysis, and bioengineering.

10 al product but also analogs inaccessible via bioengineering.

11 form for immunomodulation and advanced organ bioengineering.

12 ad applicability in systems microbiology and bioengineering.

13 ale models of organs, digital organisms, and bioengineering.

14 iology, regenerative medicine, and synthetic bioengineering.

15 ure directions in environmental and clinical bioengineering.

16 genesis, regeneration, cancer, and synthetic bioengineering.

17 ify bottlenecks to be targeted in subsequent bioengineering.

18 simulations to drive advances in biology and bioengineering.

19 tion in catalysis, separation technology, or bioengineering.

20 logical systems pertaining to healthcare and bioengineering.

21 ronics, chemical and biological sensing, and bioengineering.

22 tions in RNA-targeted drug discovery and RNA bioengineering.

23 cin, showing its promise for applications in bioengineering.

24 dentify future opportunities for resveratrol bioengineering.

25 ety of applications in materials science and bioengineering.

26 se cells offer a novel potential for corneal bioengineering.

27 suggesting applications in biotechnology and bioengineering.

28 very, especially in the imaging sciences and bioengineering.

29 ocalized for applications in bioanalysis and bioengineering.

30 of fundamental interest in microbiology and bioengineering.

31 n protein structure, function, evolution and bioengineering.

32 research, developmental biology, and tissue bioengineering.

33 lular design, pathway evolution and cellular bioengineering.

34 isms and may have practical applications for bioengineering.

35 y used therapeutic agent that is produced by bioengineering.

36 ly designed complex natural products through bioengineering.

37 applications in molecular biotechnology and bioengineering.

38 e significant potential in biotechnology and bioengineering.

39 r cell biology, biochemistry, biophysics and bioengineering.

40 living organisms, therapeutic targeting and bioengineering.

41 play a very significant role in ecology and bioengineering.

42 in energy storage, wearable electronics, and bioengineering.

43 em highly amenable to discovery research and bioengineering.

44 evolution and drive advances in medicine and bioengineering.

45 s is a central goal of synthetic biology and bioengineering.

46 ising applications in therapeutic design and bioengineering.

47 erative repair in medicine and biosensing in bioengineering.

48 ow being addressed by incredible advances in bioengineering.

49 al of SKPs in hair follicle regeneration and bioengineering.

50 ample, in organic electronics, catalysis and bioengineering.

51 well as the features that can be improved by bioengineering.

52 ance for synthetic biology, biochemistry and bioengineering.

53 nically-relevant model in basic research and bioengineering.

54 d benefit complementary structural design in bioengineering.

55 ding the use of precursor T cells and thymus bioengineering.

56 f metabolic strategies both in evolution and bioengineering.

57 Despite the advancements in skin bioengineering, 3D skin constructs are still produced as

58 Bioengineering a cyanobacterial carbon-concentrating mec

59 processes, but also in development of novel bioengineering and bioelectronics applications.

60 dentifies a simple design principle to guide bioengineering and bioinformatic analysis of SD, and ill

61 on method for mature plants to benefit plant bioengineering and biological studies.

62 P-embedded charged residues is important for bioengineering and biomedical applications relying on TM

63 microrobot and other device technologies for bioengineering and biomedical applications.

64 om the "bottom up." In the last few decades, bioengineering and bionanotechnology have borrowed this

65 es for a variety of applications in biology, bioengineering and chemistry.

66 e potential of lanthipeptide synthetases for bioengineering and combinatorial biosynthesis.

67 cell populations with promising potential in bioengineering and dental therapeutics.

68 or future exploration of archaeal viruses in bioengineering and development of multifunctional vector

69 nce of cancer immunotherapy, nanotechnology, bioengineering and drug delivery is opportune, as each o

70 ineering, cell encapsulation, microfluidics, bioengineering and drug delivery.

71 such as biochemistry, enzymology, biofuels, bioengineering and drug discovery.

72 le would have wide applications ranging from bioengineering and food industry to environmental fields

73 National Institute of Biomedical Imaging and Bioengineering and held in Bethesda, Maryland, in Februa

74 perfusion injury, (2) machine perfusion, (3) bioengineering and liver regeneration, (4) transplant on

75 ls for applications in materials science and bioengineering and may also facilitate an improved under

76 ion that this tool will be of great value in bioengineering and medicine.

77 l may find applications in chemical biology, bioengineering and medicine.

78 Bioengineering and metagenomics provide access to librar

79 Capitalising on recent advances in bioengineering and microfabrication aimed at solving the

80 Using sophisticated bioengineering and molecular biology tools, we report th

81 orthogonal l-DNA, suggesting applications in bioengineering and nanomedicine.

82 o biology and represents a long-term goal in bioengineering and precision therapeutics.

83 As organ bioengineering and regeneration has shown the potential

84 Recent achievements in organ bioengineering and regeneration have provided proof of p

85 f of principle that the application of organ bioengineering and regeneration technologies to manufact

86 way and thus, may have significance in space bioengineering and synthetic biology.

87 ructs is an essential enabling technique for bioengineering and synthetic biology.

88 milestone in systems chemistry, soft matter bioengineering and synthetic protobiology.

89 Here, we report the bioengineering and validation of this probe.

90 National Institute of Biomedical Imaging and Bioengineering) and CHDI Foundation Inc.

91 amental biology, biomedicine, biotechnology, bioengineering, and bioenergy.

92 important roles in cell biology, immunology, bioengineering, and biomimetic material design.

93 several fluid-related problems in medicine, bioengineering, and biotechnology.

94 efore fundamental to areas such as genetics, bioengineering, and food safety.

95 The convergence of stem cell biology, bioengineering, and gene editing tools have substantiall

96 lt stem cell enrichment and transplantation, bioengineering, and gene transfer have proved successful

97 As the disciplines of materials science, bioengineering, and immunology mature in the 21st centur

98 ture applications in targeted drug delivery, bioengineering, and lab-on-a-chip devices.

99 ary interface of cancer biology, immunology, bioengineering, and materials science is important to fu

100 tic impact on molecular and systems biology, bioengineering, and medicine--once certain obstacles are

101 dels have significant potential for science, bioengineering, and medicine.

102 ve great potential to accelerate bioscience, bioengineering, and medicine.

103 ture suggests that recent progress in tissue bioengineering, and molecular and cellular biology resea

104 become the method of choice in microbiology, bioengineering, and molecular biology.

105 tions across biochemistry, cellular biology, bioengineering, and optics.

106 m cell biology, genetics, materials science, bioengineering, and tissue engineering.

107 hat could further advance the possibility of bioengineering anticoagulant heparin in cultured cells.

108 ents in the worm gut, could be applicable to bioengineering applications given its potentially high s

109 ggest that these materials have potential in bioengineering applications requiring encapsulation or c

110 with various cell-types for therapeutic and bioengineering applications, as well as providing powerf

111 n enhancing CO(2) fixation and potentials in bioengineering applications, the formation of carboxysom

112 g antitumour, antimicrobial, antioxidant and bioengineering applications, will be presented and discu

113 l biology and for developing therapeutic and bioengineering applications.

114 s required for "off-the-shelf" therapies and bioengineering applications.

115 n of genetic modules for introducing BMCs in bioengineering applications.

116 re routinely used in biophysical studies and bioengineering applications.

117 ecules for medical detection, diagnosis, and bioengineering applications.

118 als remains of significant interest for many bioengineering applications.

119 tical step in a wide range of biomedical and bioengineering applications.

120 ays (LSMAs) are key for material science and bioengineering applications.

121 as to advance various medical techniques and bioengineering applications.

122 This novel bioengineering approach can be readily applied to variou

123 Here, using a bioengineering approach--channel inactivation induced by

124 The findings suggest possible bioengineering approaches for obtaining anionic bacterio

125 In this review we will focus on the latest bioengineering approaches that have been utilised to opt

126 cancer and discuss the emerging preclinical bioengineering approaches that have the potential to ove

127 lar biophysical mechanisms and suggest novel bioengineering approaches to construct functional tissue

128 Here we use bioengineering approaches to identify the roles of cadhe

129 We discuss how utilizing bioengineering approaches to manipulate and integrate sp

130 opening the way for additional cellular and bioengineering approaches to renal repair and regenerati

131 t be satisfied to permit commercially viable bioengineering approaches to specific chemicals and that

132 aimed at tighter regulatory control through bioengineering approaches, along with newer unbiased org

133 stic through co-culture, transplantation and bioengineering approaches.

134 rops, by manipulating TaHRC sequence through bioengineering approaches.

135 ging technologies from optics, genetics, and bioengineering are being combined for studies of intact

136 g highly inductive DP cells to be used in HF bioengineering assays.

137 These results provide the basis for bioengineering ATP synthases with customized ion-to-ATP

138 alized Medicine, IEEE 7th Bioinformatics and Bioengineering attracted more than 600 papers and 500 re

139 The bioengineering basis for the technique is critically pre

140 useful and flexible platform for selectively bioengineering biologic function and half-life to target

141 o all nations as a part of their independent bioengineering, biosecurity, and countermeasure response

142 onstrate that combining 3D cell culture with bioengineering can increase reproducibility and improve

143 For bioengineering, cell transplantation, and disease modeli

144 y a binary 'on' or 'off' response, remains a bioengineering challenge.

145 to the plant plastome provides an effective bioengineering chassis for introduction and evaluation o

146 Bioengineering, chemical biology, molecular biology, and

147 For the general biological and bioengineering community, several noncanonical backbones

148 this wide effective range of RKN resistance, bioengineering crops expressing dsRNA that silence targe

149 ffers a framework to aid forward and inverse bioengineering designs as well as fundamental discovery

150 device engineering (as part of a cornerstone bioengineering devices course).

151 t are also discussed to present integrative, bioengineering-directed approaches to achieve next-gener

152 erials are promising for the field of tissue bioengineering due to their biocompatibility, high poros

153 The knowledge gained from these bioengineering efforts has greatly improved our understa

154 Bioengineering efforts to increase oil in non-storage ve

155 e pig may be a suitable animal model for TMJ bioengineering efforts.

156 The emerging new field of bioengineering-engineering based in the science of molec

157 s are finding widespread application in many bioengineering fields, including controlled bioactive mo

158 impacting emerging high-tech fields, such as bioengineering, flexible electronics, and clean energy.

159 By harnessing the modular techniques of bioengineering for applications in trained immunity, tra

160 Breeding or bioengineering for lower leaf area could, therefore, con

161 promising strategy for iPSC-based cartilage bioengineering for study of disease mechanisms and new t

162 synthesis of these molecules is essential to bioengineering for sustainable production.

163 ut also a viable alternative to isolation or bioengineering for the efficient preparation of polyoxyg

164 d 99.2% (CI, 87.9% to 100%); and Hunan Jynda Bioengineering Group HCV Ag ELISA, 59.5% (CI, 46.0% to 7

165 National Institute of Biomedical Imaging and Bioengineering, had the most rapid growth (320 articles;

166 Recombinant bioengineering has led to replacement therapies with eas

167 tion that research in biomedical imaging and bioengineering has the potential of positively influenci

168 Advances in bioengineering have spawned various imaging modalities w

169 Orb webs are fascinating feats of bioengineering in nature, displaying magnificent archite

170 nsidered when optimizing recombinant Rubisco bioengineering in plants.

171 Bioengineering intestine on vascularized native scaffold

172 These results demonstrate that OnRS-based bioengineering is a common, robust and versatile strateg

173 Bioengineering is a vast field that ranges from biomater

174 Bioengineering is offering new opportunities to both sup

175 Since the success of whole tooth bioengineering is predicated on the availability of larg

176 A major roadblock to successful organ bioengineering is the need for a functional vascular net

177 , one of the fundamental challenges of space bioengineering is to create cellular microgravity respon

178 o exploit the potential of CAM crops and CAM bioengineering, it will be necessary to elucidate the ev

179 -tuning of multiple "upstream" (i.e., lignin bioengineering, lignin isolation and "early-stage cataly

180 Circumventing these bioengineering limitations is critical to tailoring the

181 Although ocean bioengineering may alleviate change, this is not without

182 in areas as diverse as electronics, optics, bioengineering, medicine, and even fashion.

183 tabolism, and such information is useful for bioengineering metabolic pathways for specific terpenes.

184 n, and purification protocols, as well as in bioengineering methodologies, have fueled enthusiasm for

185 ycosyltransferases, coupled with advances in bioengineering methodology, have ushered in a new era of

186 Bioengineering methods, such as encapsulation, and gene

187 Using in vitro bioengineering models in conjunction with molecular cell

188 technology applications in plant biology and bioengineering, nanoparticle-plant interactions, and nan

189 romising candidates for use as materials for bioengineering nerve conduits.

190 lantation, increased livestock productivity, bioengineering new materials, products and even fabrics

191 to form normal teeth, providing a basis for bioengineering new teeth if suitable, non-embryonic cell

192 National Institute of Biomedical Imaging and Bioengineering (NIBIB) was created with a somewhat diffe

193 National Institute of Biomedical Imaging and Bioengineering (NIBIB), NIH Shared Instrumentation Grant

194 National Institute of Biomedical Imaging and Bioengineering (NIBIB).

195 Here, we describe the bioengineering of an accelerated response to natural sha

196 allenge faced by stem cell biologists is the bioengineering of an organ.

197 will provide the information needed for the bioengineering of antigens needed to expand the specific

198 ce for adoptive cell-based SG therapies, and bioengineering of artificial SGs.

199 While the native toxin is extremely lethal, bioengineering of BoNT has the potential to eliminate to

200 logy Laboratory (EMBL) and the Institute for Bioengineering of Catalonia (IBEC) joined forces to unit

201 city induction to the next level by enabling bioengineering of central and peripheral cells that make

202 Advances in cellular scaffolding have made bioengineering of complex tissues a reality.

203 This study provides new opportunities for bioengineering of enediyne derivatives and expands the s

204 Bioengineering of EVs involves the modification of the d

205 Bioengineering of exosomes could be one approach to achi

206 anding tea PA biosynthesis and tools for the bioengineering of flavanols.

207 m cell-derived cardiomyocytes and enable the bioengineering of functional human myocardial-like tissu

208 scale and clinically relevant cells for the bioengineering of functional myocardial tissue based on

209 a) module has implications for stability and bioengineering of isolated antibody and immunoglobulin d

210 s (BMCs) have drawn particular attention for bioengineering of nanoreactors because they are self-ass

211 Bioengineering of native-like multiscale building blocks

212 new natural products, and also to guide the bioengineering of new and existing natural product scaff

213 tides, mRNA-containing liposomes, as well as bioengineering of new hair follicles.

214 -surface and cell-cell interactions, and for bioengineering of novel conductive materials.

215 the regioselectivity of SOMT activities for bioengineering of O-methylated stilbenes.

216 Such improved understanding may enable bioengineering of organisms with improved nutrition and

217 Bioengineering of plant immune receptors has emerged as

218 the successful synthesis of redox active and bioengineering of reduced graphene oxide (RGO) for the d

219 and salt concentration opens avenues for the bioengineering of stress-triggered biological phenomena

220 Physiologic bioengineering of the oral, dental, and craniofacial com

221 has led to technological innovations in the bioengineering of tissue-mimicking grafts that can be ut

222 Bioengineering of viral vectors for therapeutic gene del

223 s represent a significant advancement in the bioengineering of whole organs.

224 Bioengineering offers potential advancements in health,

225 This review discusses emerging bioengineering opportunities for the treatment of stroke

226 le-protein level confirmed the importance of bioengineering optimal protein attachment sites to achie

227 ation of human pluripotent stem cells, which bioengineering or scaffolding strategies have the most p

228 But recent developments in bioengineering, organic chemistry and related fields hav

229 tly limited to varying existing organisms or bioengineering organoids in vitro.

230 Bioengineering organs, by growing patient-derived cells

231 tential implications for related problems in bioengineering, pharmaceuticals, and snow physics.

232 associate in darkness, setting the stage for bioengineering photoprotection in cyanobacteria as well

233 f-assembling materials in combination with a bioengineering platform is proposed to assist functional

234 Possible biological significance and bioengineering potentials of lactonization are discussed

235 OOC), evolved from developmental biology and bioengineering principles, have emerged as major technol

236 remarkable progress in this field, scalable bioengineering processes are also discussed for the real

237 e involves neither toxic/precious metals nor bioengineering processes to achieve enhanced photocataly

238 They can also guide bioengineering projects toward optimal biofuel productio

239 For bioengineering purposes, the leader peptide is beneficia

240 scientific study of cellular metabolism and bioengineering purposes.

241 Systemic Darwinism would greatly further bioengineering research and would provide a significantl

242 at interfaces is important in biological and bioengineering sciences, yet remains technically challen

243 he development of stem cell-based therapy or bioengineering SG tissues to repair/regenerate SG dysfun

244 i HeartCare Medical Technology, HeMo (China) Bioengineering, Sino Medical Sciences Technology.

245 Bioengineering solutions to human space travel must cons

246 Novel bioengineering solutions will be required to generate cu

247 This review focuses on lignin bioengineering strategies and describes emerging technol

248 s, their advantages and limitations, and how bioengineering strategies can be used to steer the cell

249 Bioengineering strategies can overcome each of these lim

250 d liquid biopsies for cancer diagnostics and bioengineering strategies for cancer therapy.

251 structure of the modified lignin and direct bioengineering strategies for future targeted properties

252 een FVIII and VWF is required to drive novel bioengineering strategies for products that either prolo

253 Current bioengineering strategies to regenerate the lung have no

254 g the most successful of a new generation of bioengineering strategies.

255 and Nature Biotechnology present a creative bioengineering strategy for achieving these goals.

256 represent an innovative and scalable tissue-bioengineering strategy for modeling rare kidney disease

257 We have developed a bioengineering strategy to successfully reconstitute SLS

258 microcompartments in prokaryotic biology and bioengineering, structural heterogeneity has prevented a

259 nonimmunogenic scaffolds for future hepatic bioengineering studies.

260 olecular architectures, with applications in bioengineering, supramolecular chemistry, and sensing.

261 mix of quantitative developmental genetics, bioengineering, synthetic biology and artificial life ai

262 ration variables are extremely important for bioengineering systems.

263 n disciplines, from developmental biology to bioengineering, systems biology and biophysics.

264 A number of bioengineering techniques are being developed using micr

265 Bioengineering techniques are currently used in a wide v

266 leaf-litter leachates of helophytes used in bioengineering techniques could alleviate this limitatio

267 rs) and reduce dosing frequency by utilizing bioengineering techniques including PEGylation, Fc fusio

268 h span respectively, using non-invasive skin bioengineering techniques of laser Doppler imaging, a tr

269 Advances in bioengineering technology have driven development of hip

270 ific model systems that can be exploited for bioengineering the development and metabolism of these s

271 Bioengineering the surface of exosomes has been proposed

272 ossibilities for stem cell imaging or tissue bioengineering, their long-term intracellular fate remai

273 Bioengineering therefore requires novel design methodolo

274 cell transplantation, material science, and bioengineering to construct biological substitutes that

275 f cell transplantation, material science and bioengineering to construct biological substitutes that

276 cell transplantation, material science, and bioengineering to construct biological substitutes that

277 ibosomal peptide synthetases will facilitate bioengineering to create novel products.

278 Here, we combine nanotechnology and bioengineering to demonstrate that nanoparticles can be

279 ng to their applications in wide fields from bioengineering to electrochemical devices.

280 In addition, we employed yeast bioengineering to fortify wine with folate.

281 We argue that for bioengineering to fully access biological potential, it

282 ynamics insights will aid rational design in bioengineering to generate versatile, robust, and more s

283 potential for various application areas from bioengineering to medical genetics.

284 Based on unique bioengineering to preserve surgical resections in a long

285 nthesis and metabolism in algae could enable bioengineering to reroute metabolism toward beneficial b

286 r use in a wide range of fields ranging from bioengineering, to robotics to food printing.

287 s a widespread pathogen but can be used as a bioengineering tool for anticancer and gene therapies.

288 uctures is increasingly recognized as both a bioengineering tool for generating new materials and a c

289 e design template for the discovery of novel bioengineering tools and approaches.

290 Different bioengineering tools and microscale/nanoscale devices ha

291 By combining bioengineering tools such as Rosetta, ESMFold, ProteinMP

292 Bioengineering tools useful for multiscale, multimodal s

293 bolism to induce carbonate precipitation for bioengineering under anaerobic conditions and at high pr

294 heir environmental niches, by exploiting the bioengineering versatility of peptidoglycan.

295 Research Reports-Biomaterials & Bioengineering was the most frequent category of cited a

296 ed beta-cell compartment; and 3) whole-organ bioengineering, which capitalizes on the innate properti

297 ling pathways and cell types may improve HSC bioengineering, which could significantly advance critic

298 present authors conducted a horizon scan for bioengineering (Wintle et al., 2017).

299 the processing and culture of human tissue, bioengineering, xenotransplantation and genome editing,

300 er technology focus on challenges related to bioengineering, yet in many applications implementation