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1 oscopically localized detection based on DNA nanotechnology.
2 ill find application as engines in molecular nanotechnology.
3 vidin-biotin system a versatile platform for nanotechnology.
4 ronment accompanying with the development of nanotechnology.
5 inspired by NPCs, and their applications in nanotechnology.
6 ntial applications in energy utilization and nanotechnology.
7 mbling nanoparticles, useful in medicine and nanotechnology.
8 tions to expand the assembly language of DNA nanotechnology.
9 ently, products generated through the use of nanotechnology.
10 bstacle to realizing new applications of DNA nanotechnology.
11 ossover (DX) tiles, a canonical motif in DNA nanotechnology.
12 c level precision is one of the key goals of nanotechnology.
13 functional materials within the area of DNA nanotechnology.
14 pment of advanced materials for medicine and nanotechnology.
15 solid-state physics, quantum computation and nanotechnology.
16 metal-oxide-semiconductor (CMOS) compatible nanotechnology.
17 lop protein-inspired assembly modules in DNA nanotechnology.
18 tackle current challenges in biomedicine and nanotechnology.
19 iral" paradigm over the field of dynamic DNA nanotechnology.
20 rd the development of modern nanoscience and nanotechnology.
21 They are also an achievable goal of nanotechnology.
22 ons across photonics, material sciences, and nanotechnology.
23 us functional applications in many fields of nanotechnology.
24 hallenges and opportunities for cellular DNA nanotechnology.
25 des for applications in synthetic biology or nanotechnology.
26 s continues to be a key need and interest in nanotechnology.
27 es is currently a topic of large interest in nanotechnology.
28 mic level has given rise to modern bottom-up nanotechnology.
29 nge for today and tomorrow's nanoscience and nanotechnology.
30 may be relevant for some applications of DNA nanotechnology.
31 ontrol that is currently associated with DNA nanotechnology.
32 ng immunoassays/sensors that are reformed by Nanotechnology.
33 ) was developed using surface imprinting and nanotechnology.
34 sing a combination of surface imprinting and nanotechnology.
35 n all-time high due to the emerging field of nanotechnology.
36 als science, geology, biology, tribology and nanotechnology.
37 at bPoNAs will have utility in both bio- and nanotechnology.
38 tionalizing VLPs using the principles of DNA nanotechnology.
39 entions to communicate with the public about nanotechnology.
40 ties for the development of aqueous adaptive nanotechnology.
41 s promising multifunctional 2D materials for nanotechnology.
42 espread applications in chemical biology and nanotechnology.
43 , and should be valuable to the field of DNA nanotechnology.
44 ing targets for supramolecular chemistry and nanotechnology.
45 hlight important recent advances relevant to nanotechnology.
46 ogues in biology research, (epi)genetics and nanotechnology.
47 space and material scalability for bottom-up nanotechnology.
48 terest in biotechnology applications such as nanotechnology.
49 ecome central building blocks in dynamic DNA nanotechnology.
50 ortance in the fields of surface science and nanotechnology.
51 trategy to improve cancer immunotherapy with nanotechnology.
52 erent applications in science, medicine, and nanotechnology.
53 ed shapes would support many applications in nanotechnology.
54 tructural biology, biophysics, and molecular nanotechnology.
55 Here, we report on an in vivo pH mapping nanotechnology.
56 re-program in vivo cellular responses using nanotechnology.
57 tion of biological processes in nucleic acid nanotechnology.
58 obtained with design tools imported from DNA nanotechnology.
59 tions of native CDs in materials science and nanotechnology.
60 RNA function and quantitative design of RNA nanotechnology.
61 ientific fields-interventional radiology and nanotechnology.
62 y offer great potential for membrane protein nanotechnologies.
63 velopment of the first combined audio-visual nanotechnologies.
64 advent of supramolecular chemistry and later nanotechnology a great deal of research has been focused
65 Simultaneously, the advance of nucleic acid nanotechnology, a platform within which reactions can be
69 s article, we provide an overview of popular nanotechnologies and a summary of the current and potent
70 as well as technologies, such as micro- and nanotechnologies and additive manufacturing, have been i
71 erapies is growing, fueled by innovations in nanotechnology and advances in understanding of the unde
72 Some of these challenges are not unique to nanotechnology and are common in the development of othe
74 erforms diverse functional roles in biology, nanotechnology and biotechnology, but current methods fo
76 that synthetic biology may be preferred over nanotechnology and conventional methods for high expecte
78 n essential mechanism in active nucleic acid nanotechnology and has also been hypothesized to occur i
79 al and stereocontrol is a major objective of nanotechnology and holds great promise for many applicat
80 rent state of metrological techniques in DNA nanotechnology and look forward to emerging technologies
81 ng, renewable energy, environmental science, nanotechnology and material science, to name only a few
83 We also show that by combining advances in nanotechnology and materials science with CL, new avenue
84 with recent developments in communications, nanotechnology and materials sciences, there has been ex
87 in assemblies have potential applications in nanotechnology and medicine; however, a major challenge
89 iscuss recent advances in material sciences, nanotechnology and nucleic acid chemistry that have yiel
90 te of the art in the field of structural DNA nanotechnology and presents some of the challenges and o
91 w to integrate the tools provided by DNA/RNA nanotechnology and related new technologies to construct
92 ere, we report two technical advances in DNA nanotechnology and single-molecule genomics: (1) we desc
93 for rational control of membrane proteins in nanotechnology and synthetic biology by manipulating glo
94 s for environmental remediation by comparing nanotechnology and synthetic biology to conventional rem
97 ologies, including emerging biotechnologies, nanotechnologies, and microfluidics, hold the potential
105 le-cell protein, biopolymers, components for nanotechnology applications (surface layers), soluble me
106 biological relevant targets, can be used in nanotechnology applications, and are valuable methodolog
107 gn of oligonucleotides for biotechnology and nanotechnology applications, but parameters currently in
110 ver, the most intriguing applications of DNA nanotechnology - applications that best take advantage o
111 present review discusses new developments in nanotechnology applied to dentistry, focusing on the use
112 t of methamphetamine (METH) abuse, we used a nanotechnology approach to customize the in vivo behavio
113 gy besides novel techniques based on various nanotechnology approaches and molecular biology tools in
114 trong preclinical results suggest that these nanotechnologies are set to transform the therapeutic pa
115 ning novel wood-based materials via advanced nanotechnologies are summarized, including both the cont
116 e process may be of high value to commercial nanotechnology, as it can be easily scaled up to the fab
117 generator, which have exploited advances in nanotechnology at all hierarchical levels of device cons
119 ome of the advancements made in the field of nanotechnology based assays for microbial detection sinc
121 signing and fabricating electrode materials, nanotechnology-based approaches have demonstrated numero
124 study examines the applicability of a novel nanotechnology-based drug delivery system, which induces
126 To overcome these challenges, we developed a nanotechnology-based plasmonic gold chip for autoantibod
129 Modern methods and future directions of nanotechnology-based targeted and personalized therapy a
131 ropolishing of metal wires is attractive for nanotechnology because it provides centimeter long and m
132 trapped charge is thus essential for future nanotechnologies, but their direct detection and manipul
134 sts in designing sequences to be used in DNA nanotechnology, by putting limits on the suppression of
136 ll the results indicated that this novel RNA nanotechnology can overcome conventional cancer therapeu
138 stics to target acne, we used an established nanotechnology capable of generating/releasing NO over t
139 amples and share the experience with the NCI Nanotechnology Characterization Laboratory assay cascade
144 nt role in membrane protein crystallization, nanotechnology, controlled drug delivery, and pathology
145 ts an array of research activities in cancer nanotechnology, convened a strategic workshop to explore
146 ally in such nanocapsules demonstrating that nanotechnology could be a viable method to improve selec
149 process should find ready application in DNA nanotechnology, DNA computing, and in vitro evolution of
153 remarkable advances in material science and nanotechnology enable rational design of heterostructure
154 cate the robustness and adaptability of this nanotechnology-enabled 'detection and perturbation' stra
156 regnant women to safely reap the benefits of nanotechnology-enabled products and assist in the implem
157 e, we show how the modularity offered by DNA nanotechnology enables multiplexing by incorporating ort
159 generative medicine from research to clinic, nanotechnology, especially magnetic nanoparticles have a
161 The SUN consortium (Project on "Sustainable Nanotechnologies", EU seventh Framework funding) uses me
162 One of the long-standing goals of the DNA nanotechnology field has been the assembly of periodic,
164 rmations on individual virions using our new nanotechnology, "flow virometry", and a panel of antibod
166 anoscale and the development of new kinds of nanotechnologies for chemical transport, chemical commun
168 otube field-effect transistors-promising new nanotechnologies for use in energy-efficient digital log
169 nanoparticles for biomedicine, and wearable nanotechnologies for wellness monitoring are briefly cov
171 Despite significant efforts to translate nanotechnology for cancer application, lack of identific
174 work represents the rational application of nanotechnology for immunoengineering and can provide a b
176 is is the first report on this kind of novel nanotechnology for pediatric fixed-dose combinations of
177 tical to the exploitation of nanoscience and nanotechnology for production of electronic devices, ene
179 ties would open up exciting opportunities in nanotechnology, for example, as artificial (molecular st
182 DNA will expand the scope of applications in nanotechnology, gene editing, and DNA library constructi
183 are the main cost factor for studies in DNA nanotechnology, genetics and synthetic biology, which al
187 g synthetic gene regulatory networks and DNA nanotechnology has developed greatly, little control exi
193 oom Temperature Phosphorescence (SS-RTP) and nanotechnology has led to a new approach in the detectio
203 ng in cell-free settings, researchers in DNA nanotechnology have been able to scale up system complex
204 Recent developments in the field of DNA nanotechnology have begun to address these goals, demons
207 id pace in the area of materials science and nanotechnology have made it possible to synthesize nanop
210 ary, opening the door for "heterochiral" DNA nanotechnology having fully interfaced d-DNA and l-DNA c
215 Administration (FDA) is tracking the use of nanotechnology in drug products by building and interrog
216 e the current trends and potential impact of nanotechnology in MSC-driven regenerative medicine.
217 no reviews that outline the applications of nanotechnology in this area despite increasing exploitat
218 potentially wide applications in biology and nanotechnology including single molecule studies and syn
221 National Science Foundation's (NSF) National Nanotechnology Infrastructure Network (NNIN), an integra
222 2000 the United States launched the National Nanotechnology Initiative and, along with it, a well-def
224 sing the promise of next-generation magnetic nanotechnologies is contingent on the development of nov
225 the results demonstrated that the novel ISNP nanotechnology is a promising platform to manufacture pa
229 order to fully realize the potential of DNA nanotechnology, it is crucial to overcome the lack of ro
230 n of MVs for applications in biomedicine and nanotechnology.It is unclear how Gram-positive bacteria,
231 Despite its important role in biology and nanotechnology, many questions remain regarding the mole
232 potential for combinatorial treatments with nanotechnology, markedly increasing the efficacy of exis
236 ivery methods and the transformative role of nanotechnology, microfluidics and laboratory-on-chip tec
238 e decades, the field has been overwhelmed by nanotechnology, nanomedicine, and many nano-sized drug d
239 n order to be competitive, current biosensor nanotechnologies need significant improvements, especial
240 a novel biosensor which combines the use of nanotechnology (non-woven nanofibre mat) with Solid Surf
249 y and Computed Tomography have the impact of nanotechnology on their improved performance, they are h
250 tors have gained an increasing importance in nanotechnology owing to their contributions to both fund
252 des a focused overview of recent advances in nanotechnology platforms for the systemic delivery of th
256 binding to surfaces is an important tool in nanotechnology, quantitative information about the resid
260 advance of chemistry, materials science, and nanotechnology, significant progress has been achieved i
264 of salivary diagnostic electronics based on nanotechnologies that can offer rapid, yet highly accura
266 tal and economic development relies on novel nanotechnologies that offer maximum efficiency at minima
267 Here, we outline recent advancements in nanotechnology that could be exploited to overcome the m
271 pite continuous advances in the field of DNA nanotechnology, the intracellular fate of DNA nanostruct
272 The foundational goal of structural DNA nanotechnology-the field that uses oligonucleotides as a
274 ve led to promising advances in the field of nanotechnology, there remain significant research gaps a
275 ign parameter for engineering of dynamic DNA nanotechnology, thereby expanding the types of architect
276 d, transformative nanosystems, which use new nanotechnologies to simultaneously realize improved devi
278 emerging discipline of dynamic nucleic acid nanotechnology to develop a robust method for multi-colo
280 ept of 'nanochemoprevention' i.e. the use of nanotechnology to improve the outcome of cancer chemopre
282 t development along this line would help RNA nanotechnology to reach the structural control that is c
283 e summarize the current abilities of DNA/RNA nanotechnology to realize applications in live cells and
284 n the novel drug delivery approach that uses nanotechnology to selectively deliver recovery-inducing
285 review will outline the application of micro/nanotechnology to specifically address the physiological
286 in, we demonstrate the strategy of novel bio-nanotechnology to successfully fabricate high-performanc
287 f the state-of-the-art in the application of nanotechnology to waterborne pathogen sampling and detec
289 es which are highly relevant in the field of nanotechnology using colored silica and gold nanoparticl
290 ing on recent developments in DNA structural nanotechnology, we introduce the nanoswitch-linked immun
292 ISNP granules, were prepared using the ISNP nanotechnology, which spontaneously produced drug-loaded
293 ther improve targeting properties of current nanotechnologies while simultaneously enable carriers wi
295 opens the prospect of a new class of quantum nanotechnology with potential applications including pho
298 the development and application of CNT-based nanotechnologies, with a particular focus on the carrier
299 rials for the development of nanoscience and nanotechnology, with applications in very diverse areas
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