ライフサイエンスコーパス: nanotechnology

1 monstrated their applications in dynamic DNA nanotechnology.

2 f both new phenomena and new applications in nanotechnology.

3 analytical techniques covering the field of nanotechnology.

4 han a magnetic field is of great interest in nanotechnology.

5 als and offers many new opportunities in DNA nanotechnology.

6 hetic materials with several applications in nanotechnology.

7 chanics of frustration is now possible using nanotechnology.

8 ctural control, the primary advantage of DNA nanotechnology.

9 sers into powerful tools for nanoscience and nanotechnology.

10 ing targets for supramolecular chemistry and nanotechnology.

11 vidin-biotin system a versatile platform for nanotechnology.

12 inspired by NPCs, and their applications in nanotechnology.

13 ossover (DX) tiles, a canonical motif in DNA nanotechnology.

14 solid-state physics, quantum computation and nanotechnology.

15 iral" paradigm over the field of dynamic DNA nanotechnology.

16 s continues to be a key need and interest in nanotechnology.

17 may be relevant for some applications of DNA nanotechnology.

18 s promising multifunctional 2D materials for nanotechnology.

19 hlight important recent advances relevant to nanotechnology.

20 ogues in biology research, (epi)genetics and nanotechnology.

21 space and material scalability for bottom-up nanotechnology.

22 terest in biotechnology applications such as nanotechnology.

23 n delivered effectively to cancer cells with nanotechnology.

24 ecome central building blocks in dynamic DNA nanotechnology.

25 ortance in the fields of surface science and nanotechnology.

26 trategy to improve cancer immunotherapy with nanotechnology.

27 erent applications in science, medicine, and nanotechnology.

28 ed shapes would support many applications in nanotechnology.

29 tructural biology, biophysics, and molecular nanotechnology.

30 Here, we report on an in vivo pH mapping nanotechnology.

31 re-program in vivo cellular responses using nanotechnology.

32 roadblock to biomedical applications of DNA nanotechnology.

33 itical to expanding the functionality of DNA nanotechnology.

34 chers and the public alike since the dawn of nanotechnology.

35 strand displacement cascades in nucleic acid nanotechnology.

36 elds beyond specialist groups working in DNA nanotechnology.

37 bout the issues and developing trends in FNA nanotechnology.

38 practical applications in biotechnology and nanotechnology.

39 reat importance for biological processes and nanotechnology.

40 form the microscopic world of structural DNA nanotechnology.

41 eloping nanopore methods associated with DNA nanotechnology.

42 od to achieve dynamic switching in DNA-based nanotechnology.

43 ork thereby introduces a science of gammaPNA nanotechnology.

44 sign and other areas of modern computational nanotechnology.

45 o produce a suite of practical protein-based nanotechnologies.

46 affect the safety, toxicity, and efficacy of nanotechnologies.

47 for a systems approach to designing proposed nanotechnologies.

48 for last-generation functional materials and nanotechnologies.

49 ts, spurring research towards beyond-silicon nanotechnologies.

50 velopment of the first combined audio-visual nanotechnologies.

51 unction and engineering new therapeutics and nanotechnologies.

52 ivery and cancer regression (Pi et.al Nature Nanotechnology, 2018:13, 82-89; Li et al., Scientific Re

53 s been experimentally demonstrated using DNA nanotechnology(4) with up to 22 tile types(5-11).

54 By progress in nanotechnology, a great potential has been giving to nan

55 Simultaneously, the advance of nucleic acid nanotechnology, a platform within which reactions can be

56 Dynamic DNA nanotechnology, a subfield of DNA nanotechnology, is con

57 Nanotechnologies allow the production of yarns containin

58 DNA nanotechnology allows for the design of programmable DNA

59 as well as technologies, such as micro- and nanotechnologies and additive manufacturing, have been i

60 Exciting advances in the application of nanotechnology and 3D bioprinting to urethral tissue eng

61 reas by combining advanced microelectronics, nanotechnology and advanced biomaterial science.

62 accine development and highlight the role of nanotechnology and advanced manufacturing.

63 Recent advanced in the fields of nanotechnology and atmospheric sciences underline the in

64 and pharmaceutical industries, as well as in nanotechnology and biotechnological processes.

65 rating chemical gradients, electrocatalysis, nanotechnology and cell biology.

66 neous catalysis and materials engineering to nanotechnology and energy sciences.

67 The combination of cell-membrane-coating nanotechnology and genetic editing technique offers a sa

68 olitical or religious polarization regarding nanotechnology and genetically modified foods.

69 With the rapid increase in the use of nanotechnology and immunotherapy for cancer management i

70 ific interest as it has many applications in nanotechnology and in nature.

71 l modifications as part of their work in DNA nanotechnology and inspire chemists to address current c

72 ties to achieve new structural motifs in DNA nanotechnology and introduce new functionalities to DNA

73 rent state of metrological techniques in DNA nanotechnology and look forward to emerging technologies

74 ng, renewable energy, environmental science, nanotechnology and material science, to name only a few

75 ng towards applications in chemical biology, nanotechnology and material science.

76 copy (SEM), is the most popular tool used in nanotechnology and material science.

77 in recent years, progress made in chemistry, nanotechnology and materials science has started to impa

78 rstanding and controlling disorder is key to nanotechnology and materials science.

79 synergistically combine the strengths of DNA nanotechnology and nanopores.

80 rs of nucleic acid association events in RNA nanotechnology and nucleic-acid-based molecular computat

81 This Review explores how nanotechnology and related approaches are being applied

82 As the fields of both DNA nanotechnology and single-molecule characterisation inte

83 ere, we report two technical advances in DNA nanotechnology and single-molecule genomics: (1) we desc

84 for rational control of membrane proteins in nanotechnology and synthetic biology by manipulating glo

85 ribosome and increases the tool kit for RNA nanotechnology and synthetic biology.

86 ntial use as a THF responsive module for RNA nanotechnology and synthetic biology.

87 s occupy a material space distinct from 'DNA nanotechnology' and DNA origami.

88 ammable nucleic acid components in medicine, nanotechnology, and biocomputing.

89 for application in therapeutics, biosensing, nanotechnology, and biocomputing.

90 optoelectronics, photonics, magnetic device, nanotechnology, and biotechnology.

91 r future exploration in drug development and nanotechnology, and discussing future prospects for mana

92 is central to biophysics, materials science, nanotechnology, and food and cosmetic applications, but

93 Advances in miniaturization, nanotechnology, and microfluidics, along with developmen

94 sive applications in DNA scaffolds, sensors, nanotechnology, and other chemical applications.

95 The advent of nanotechnology, and the need to understand the chemical

96 a comprehensive overview on the landscape of nanotechnology application in medicine.

97 Nevertheless, nanotechnology application in the petroleum industry pre

98 y biorecognition motifs has a broad range of nanotechnology applications in plant biology and bioengi

99 DNA and RNA have emerged as a material for nanotechnology applications that take advantage of the n

100 ctability are increasingly being used in DNA nanotechnology applications, in which they offer versati

101 s been developed for multiple biomedical and nanotechnology applications, including immunotherapy.

102 exploited for diagnostic, biotechnology, and nanotechnology applications.

103 new materials based on PNA self-assembly for nanotechnology applications.

104 eveloping materials for scientific study and nanotechnology applications.

105 mbinations for diverse future biomedical and nanotechnology applications.

106 at can be used for a range of biomedical and nanotechnology applications.

107 , especially neuroscience, and potential for nanotechnology applications.

108 lar assemblies will pave the way for various nanotechnology applications.

109 common problems of GT agents by using a DNA nanotechnology approach.

110 gy besides novel techniques based on various nanotechnology approaches and molecular biology tools in

111 Nanotechnology approaches are being developed both to de

112 urvey and Summary, we explore and review DNA nanotechnology approaches for microRNA detection, survey

113 e time, preclinical studies have highlighted nanotechnology approaches that facilitate the specific t

114 Biosensors based on nanotechnology are developing rapidly and are widely app

115 e heterogeneity of cancer and limitations of nanotechnology are discussed to facilitate translational

116 The incorporation of nanotechnology as a means for nanopesticides is in the e

117 ers have turned toward the use of biomimetic nanotechnology as a means of addressing these hurdles.

118 Structural DNA nanotechnology, as exemplified by DNA origami, has enabl

119 deline to researchers who aim to fabricate a nanotechnology-assisted LC materials-based biosensor for

120 ffort to describe the advancements in LC and nanotechnology-assisted LC systems for developing an eff

121 The biosensing mechanism associated with nanotechnology-assisted LC-based sensing systems, challe

122 spire further researches in developing novel nanotechnologies based aptasensors for possible on-site

123 Inspired by nanotechnologies based on DNA strand displacement, herei

124 datasets can answer fundamental questions in nanotechnology based drug delivery are proposed.

125 Nanotechnology- based delivery systems grabbed tremendou

126 This flexible nanotechnology-based approach is shown here to work with

127 egies that show clinical efficacy and review nanotechnology-based approaches that are currently being

128 spectra, and laser tweezer as well as micro/nanotechnology-based device such as microfluidics, micro

129 In this review, we discuss nanotechnology-based drug delivery approaches for acute

130 Chronic toxicity evaluations of nanotechnology-based drugs are essential to support init

131 To overcome these challenges, we developed a nanotechnology-based plasmonic gold chip for autoantibod

132 Here, a bioinspired, programmable nanotechnology-based platform is described that harnesse

133 vances in molecular subtyping and multiomics nanotechnology-based prostate cancer risk delineation ca

134 Here we demonstrate a nanotechnology-based semiconductor detector using cross-

135 This protocol describes a nanotechnology-based single-cell and single-molecule per

136 Nanotechnology-based smart sensors are opening new avenu

137 o the development of investigative tools and nanotechnology-based solutions.

138 This review aims to summarize nanotechnology-based strategies that have been explored

139 rious immune cells can potentially make this nanotechnology become a general platform for the design

140 As nanotechnology becomes increasingly used in biomedicine,

141 Nanotechnology benefits modern vaccine design since nano

142 The convergence of cancer immunotherapy, nanotechnology, bioengineering and drug delivery is oppo

143 ions, now spanning across materials science, nanotechnology, biology, medicine, geology, optics, cata

144 otential in a broad range of applications in nanotechnology, biomaterials science, nanomedicine and h

145 trapped charge is thus essential for future nanotechnologies, but their direct detection and manipul

146 l interfaces and to demonstrate how emerging nanotechnologies can interrogate neural systems spanning

147 t that a synthetic nanopore designed via DNA nanotechnology can accommodate folded proteins.

148 Mass spectrometry enhanced by nanotechnology can achieve previously unattainable sensi

149 onstrate that three distinct problems in RNA nanotechnology can be reduced to a pathfinding problem a

150 Nanotechnology can improve the performance of dental pol

151 ansforming cancer diagnostics and treatment, nanotechnologies capable of manipulating interactions th

152 (EUNCL) and the US National Cancer Institute Nanotechnology Characterization Laboratory (NCI-NCL) hav

153 Active research in nanotechnology contemplates the use of nanomaterials for

154 an integrated and prospective vision on how nanotechnology could enable smart plant sensors that com

155 icted short active motifs of AMPs along with nanotechnology could not only overcome the limitations o

156 This innovation translates nanotechnology developed for delivery of RNAi for human

157 With the advancement of nanotechnology, development of nanomedicines to efficien

158 Due to the modularity of DNA nanotechnology, DNA double strands with different comple

159 Nowadays, tremendous advances in nanotechnology-empowered diagnostics are serving a subst

160 The methods of DNA nanotechnology enable the rational design of custom shap

161 d other diseases are the most common form of nanotechnology enabled pharmaceuticals (NEPs) submitted

162 l of this new mechanism of flight to realize nanotechnology-enabled flying vehicles without any movin

163 Here, we report a nanotechnology-enabled high-throughput screen to identif

164 The nascent field of nanotechnology-enabled metallurgy has great potential.

165 and emerging theme in the interface between nanotechnology, energy, and life.

166 rehensive overview of the recent advances in nanotechnology-enhanced X-ray-excited imaging and therap

167 Viral nanotechnology exploits the prefabricated nanostructures

168 One of the long-standing goals of the DNA nanotechnology field has been the assembly of periodic,

169 the issues and developing trends of the FNA nanotechnology field.

170 Structural DNA nanotechnology finds applications in numerous areas, but

171 rmations on individual virions using our new nanotechnology, "flow virometry", and a panel of antibod

172 to critically assess the significant role of nanotechnology for encapsulation of AIs for pesticides.

173 work represents the rational application of nanotechnology for immunoengineering and can provide a b

174 ired researchers to study the application of nanotechnology for oil cleanup.

175 tical to the exploitation of nanoscience and nanotechnology for production of electronic devices, ene

176 DNA is extremely crucial before applying any nanotechnology for ssDNA analysis.

177 DNA will expand the scope of applications in nanotechnology, gene editing, and DNA library constructi

178 Although the field of structural DNA nanotechnology has been advancing with an astonishing pa

179 However, structural DNA nanotechnology has been limited to substantially hydrate

180 A long-standing goal of DNA nanotechnology has been to assemble 3D crystals to be us

181 Nanotechnology has begun to play a remarkable role in va

182 While DNA nanotechnology has demonstrated many synthetic supramole

183 Tremendous progress in nanotechnology has enabled advances in the use of lumine

184 DNA nanotechnology has established approaches for designing

185 sophistication and the field of dynamic DNA nanotechnology has grown exponentially.

186 In the past years, emerging nanotechnology has led the way to minimally invasive, pr

187 st decades, the blossoming of structural DNA nanotechnology has provided us with a large reservoir of

188 Nanotechnology has several applications in food industry

189 The field of DNA nanotechnology has shown great promise in the creation o

190 The advancements in nanotechnology have created multifunctional nanomaterial

191 Recent breakthroughs in nanotechnology have yielded multifunctional theranostic

192 ary, opening the door for "heterochiral" DNA nanotechnology having fully interfaced d-DNA and l-DNA c

193 heir potential for real-life applications in nanotechnology, healthcare and information storage.

194 Advancing biosensing nanotechnologies in chemically "noisy" bioenvironments r

195 te systems is critical to the utilization of nanotechnology in biomedical applications.

196 de with a brief outlook on the future of DNA nanotechnology in biosensing for microRNA and beyond.

197 resin, thereby supporting the utilization of nanotechnology in dentistry.

198 The shortcomings associated to nanotechnology in food science have illustrated along wi

199 past, there are great implications for using nanotechnology in immuno-oncology.

200 The application of nanotechnology in medicine has the potential to make a g

201 marized, thereby unlocking the advantages of nanotechnology in multimodal IGS-assisted precision syne

202 e responsible and sustainable development of nanotechnology in the agri-business sector.

203 Advanced nanotechnology in the construction of nanomaterials (NMs

204 e envision the necessities and challenges of nanotechnology in the development of in situ cancer vacc

205 Review presents the possible applications of nanotechnology in this area.

206 The detailed elucidation of BBB-crossing nanotechnology in this review is anticipated to attract

207 Considering the success of nanotechnology in transforming cancer diagnostics and tr

208 The continued growth of the nanotechnology industry and the incorporation of nanomat

209 drogels represent the realization of peptide nanotechnology into biomedical products.

210 DNA nanotechnology is a rapidly advancing field, which incre

211 Molecular nanotechnology is a rapidly developing field, and tremen

212 Functional nucleic acid (FNA) nanotechnology is an interdisciplinary field between nuc

213 Functional nucleic acid (FNA) nanotechnology is an interdisciplinary field between nuc

214 portable and non-invasive clinical sampling, nanotechnology is at its inflection point where current

215 Structural DNA nanotechnology is beginning to emerge as a widely access

216 humans, but there are common challenges that nanotechnology is beginning to help address.

217 Nanotechnology is identified as a key enabling technolog

218 From our perspective nanotechnology is revealed as a vital resource for this,

219 One long-sought after nanotechnology is systems able to achieve the assembly-l

220 A current remaining challenge in nanotechnology is the fast and reliable determination of

221 ynamic DNA nanotechnology, a subfield of DNA nanotechnology, is concerned with the study and applicat

222 order to fully realize the potential of DNA nanotechnology, it is crucial to overcome the lack of ro

223 et of things." It is well established in the nanotechnology literature that techniques such as field

224 he field of biotechnology, microfluidics and nanotechnologies, many exciting developments have been m

225 SAR boundaries including synthesis planning, nanotechnology, materials science, biomaterials, and cli

226 ces can have a large impact in the fields of nanotechnology, materials, and biomedical sciences.

227 As DNA nanotechnology matures, there is increasing need for fas

228 how novel formulations employing micro- and nanotechnologies may address these concerns.

229 Novel diagnostic technologies, including nanotechnology, microfluidics, -omics science, next-gene

230 ances in cutting-edge technologies including nanotechnology, microfluidics, electronic engineering, a

231 These areas include DNA/RNA nanotechnology, multivalent nucleic acid nanostructures,

232 e decades, the field has been overwhelmed by nanotechnology, nanomedicine, and many nano-sized drug d

233 n order to be competitive, current biosensor nanotechnologies need significant improvements, especial

234 The development of DNA nanotechnology nonetheless provides possible solutions t

235 The advantages of DNA/RNA nanotechnology offer numerous opportunities for in-cell

236 Nucleic acid nanotechnology offers a promising route towards this goa

237 Nanotechnology offers many possibilities to improve drug

238 Nanotechnology offers various unique characteristics suc

239 l properties are altered for applications in nanotechnology or thermoresponsive materials.

240 about molecular assemblers in the context of nanotechnology, our demonstration that primitive assembl

241 The rapid development of nanotechnology over the last decade offers great promise

242 Given the enormous progress of dynamic DNA nanotechnology over the past years, the field now seems

243 We also discuss the advantages of nanotechnology, over other more invasive and laborious m

244 tors have gained an increasing importance in nanotechnology owing to their contributions to both fund

245 nufacturing enables the commercialization of nanotechnology, particularly in applications such as nan

246 i-Motifs are widely used in nanotechnology, play a part in gene regulation and have

247 dicine, and animal nutritions, as well as in nanotechnology processes.

248 Recent advances in nanotechnology provide unparalleled flexibility to contr

249 binding to surfaces is an important tool in nanotechnology, quantitative information about the resid

250 Recent developments in nanotechnology raise opportunities for the application o

251 Sustainable nanotechnology requires a scientifically based and propo

252 Modern nanotechnology research has generated numerous experimen

253 play indispensable roles in nanoscience and nanotechnology research, as they provide rich informatio

254 synthesis, material science, and micro- and nanotechnology research.

255 During the last decade, the nanotechnology revolution has made a great impact in med

256 RNA nanotechnology seeks to create nanoscale machines by rep

257 two deficiencies in the current nucleic acid nanotechnology software environment: the lack of both a

258 ign of biomaterials, delivery strategies and nanotechnology solutions, for the realization of individ

259 such as electrochemiluminescence (ECL) with nanotechnology sparked new analytical applications, in p

260 th scales, however, we are bound to top-down nanotechnology techniques to realise order.

261 Here, we outline recent advancements in nanotechnology that could be exploited to overcome the m

262 des long understanding in device physics and nanotechnology that electrical approaches have the poten

263 field between nucleic acid biochemistry and nanotechnology that focuses on the study of interactions

264 field between nucleic acid biochemistry and nanotechnology that focuses on the study of interactions

265 Developing nanotechnology that would allow molecular-level phenomen

266 s such, opportunities at the intersection of nanotechnology, the microbiome and cancer are massive.

267 The foundational goal of structural DNA nanotechnology-the field that uses oligonucleotides as a

268 With the development in nanotechnology, there have been great interests in using

269 increasing complexity of the devices used in nanotechnology, there is a pressing need for characteriz

270 ltaneous combination of advanced fabrication nanotechnologies to tailor the size, geometry, and appli

271 Here we use DNA nanotechnology to build a synthetic molecular gate that

272 We have reported the application of RNA nanotechnology to construct FA-displaying exosomes for e

273 Here we use DNA nanotechnology to create probes that measure and manipul

274 review, we provide an overview of the use of nanotechnology to harmonize intra-tumoral oxygen or supp

275 e must be critically evaluated when applying nanotechnology to immuno-oncology challenges.

276 ept of 'nanochemoprevention' i.e. the use of nanotechnology to improve the outcome of cancer chemopre

277 nities and approaches for the application of nanotechnology to improve the use efficiency of necessar

278 are widely used in applications ranging from nanotechnology to industrial engineering.

279 Using nanotechnology to overcome the challenges, we developed

280 of nanoengineered structures applied in food nanotechnology to tune the characteristics of convention

281 Collectively, the convergence of nanotechnology tools and structural imaging builds a str

282 ghlight key opportunistic areas for applying nanotechnologies towards manipulating the microbiome for

283 DNA nanotechnology uses oligonucleotide strands to assemble

284 Using nanotechnology, we created a mouse model of corticostero

285 y harnessing both dynamic and structural DNA nanotechnology, we demonstrate dynamic control of the se

286 ing on recent developments in DNA structural nanotechnology, we introduce the nanoswitch-linked immun

287 Despite advances in nanotechnology, we still lack the ability to print arbit

288 In the field of DNA nanotechnology, we use programmable interactions between

289 st 20 years in which inorganic chemistry and nanotechnology were implemented in each of the core comp

290 on is driving novel treatment paradigms: (1) nanotechnology, which has revolutionized drug delivery i

291 With the advent of carbon nanotechnology, which initiated significant research eff

292 ships could be exploited in the field of DNA nanotechnology, which paves the way for designing a new

293 Nanotechnology will be an important driver for the impen

294 We believe the integration of nanotechnology with cancer immunotherapy for nano-immuno

295 This was done by combining DNA nanotechnology with colloidal science.

296 e latest remarkable advances in BBB-crossing nanotechnology, with an emphasis on the judicious design

297 rials for the development of nanoscience and nanotechnology, with applications in very diverse areas

298 for a rapidly growing area of protein-based nanotechnology, with numerous underlying connections to

299 ructures make them attractive candidates for nanotechnology, yet insufficient stability and mechanica

300 ields, including, medicine, diagnostics, and nanotechnology, yet methods to modulate antibody-antigen