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1  scaffolds for drug delivery and bone tissue engineering.
2 and simulations to mechanobiology and tissue engineering.
3 ctured scaffold design for functional tissue engineering.
4 otential to enable new strategies for genome engineering.
5 an be tailored through artificial structural engineering.
6 ly attached to receptors by metabolic glycan engineering.
7  research, niche construction, and ecosystem engineering.
8 oxides and controlled by surface-termination engineering.
9 n integral for advancing the field of tissue engineering.
10 ultimately impact many fields of science and engineering.
11 nsights will guide vascular regeneration and engineering.
12 nd therefore be a powerful tool for cellular engineering.
13 g customized cell-based therapies for tissue engineering.
14 own internal models, with minimal human hand engineering.
15 the study of metabolic pathway evolution and engineering.
16  CRISPR-Cas9 systems and may facilitate Cas9 engineering.
17 s great potential for cell-based bone tissue engineering.
18 s expressed as observables through materials engineering.
19 n the fields of sensory materials and device engineering.
20 ld represent an important advance for tissue engineering.
21 diverse fields, ranging from neuroscience to engineering.
22 ons is at the heart of (applied) science and engineering.
23 iences, material sciences and high-precision engineering.
24 ization to solving problems in chemistry and engineering.
25 body domains in isolation would aid in their engineering.
26 aking them interesting targets for metabolic engineering.
27 ndamental interest in biological science and engineering.
28 ll these advantages can only be reached when engineering a complex type of material, nanocomposites,
29 f late-onset HPP with extended life spans by engineering a floxed Alpl allele, allowing for condition
30 lementation (AiFC) method for RNA imaging by engineering a green fluorescence protein (GFP)-mimicking
31       We rewrote the entire ImageJ codebase, engineering a redesigned plugin mechanism intended to fa
32 reamlined de novo DNA synthesis approach for engineering a synthetic pathway with microchip-synthesiz
33 zed that exogenous forces can be applied for engineering a variety of significantly different MSC sha
34                                       Tissue engineering, a recent promising way to possibly resolve
35 ools that can be used to regulate the genome engineering activities of CRISPR-Cas9.
36 r of materials is the key to fundamental and engineering advances in materials' performance.
37            Advances in stem cell biology and engineering allow for the generation of constructs that
38 t-phenotype mapping provides a framework for engineering AMPAR gating using auxiliary subunits.
39              We believe that this example of engineering an adaptive Li/electrolyte interface brings
40                                     However, engineering an increasingly positive charge in a critica
41  prompt a revolution in mitochondrial genome engineering and biological understanding.
42                             Finally, genetic engineering and cell-specific application of extracellul
43                                 Based on the engineering and characterization of a minimal CPC, we su
44                    Recent advances in enzyme engineering and design have expanded nature's catalytic
45                                              Engineering and enhancing the breaking of inversion symm
46                                              Engineering and evaluation of synthetic routes for gener
47  crystals, which requires careful dispersion engineering and is usually narrowband.
48 use of models in modern applications such as engineering and manipulating microbial metabolism by syn
49 roach to emerging RGENs should enhance their engineering and optimization for therapeutic and other a
50 a complex phenotype through multiplex genome engineering and predictive modeling.
51 ogels should find use in a variety of tissue engineering and regenerative medicine applications.
52 rous scaffolds play a pivotal role in tissue engineering and regenerative medicine by functioning as
53  showcase their broad applications in tissue engineering and regenerative medicine, followed by a sum
54  and are widely used biomaterials for tissue engineering and regenerative medicine.
55 h may be amenable to numerous enzymes and to engineering and screening approaches to identify activat
56 latform technology that combines recombinant engineering and site-specific conjugation to create mult
57 loped using the design principles of crystal engineering and structure-property correlations, resulti
58 pplications in different fields in medicine, engineering and technology but their enhanced mechanical
59 novel insights into the antibody alternative engineering and the universal application in biological
60 d blockers with strong, specific binding for engineering and therapeutic applications.
61 advances in bioreactor technology, metabolic engineering, and analytical instrumentation are improvin
62 in the selection of optimal T cells, genetic engineering, and cell manufacturing are poised to broade
63 n through selective breeding without genetic engineering, and fuels the topical controversy of revivi
64 , decision science, alternatives assessment, engineering, and law and policy.
65 arge numbers of college science, technology, engineering, and mathematics (STEM) faculty to include a
66 eveloping competence in science, technology, engineering, and mathematics (STEM) is critically import
67 ittee of the National Academies of Sciences, Engineering, and Medicine has made 14 recommendations th
68  various interdisciplinary areas of science, engineering, and medicine.
69 nfrared imaging, chemical sensing, materials engineering, and quantum information processing.
70 ic strategies including cell therapy, tissue engineering, and regenerative medicine and are frequentl
71 se systems have been applied in therapeutic, engineering, and research settings.
72 trategy combining anion substitution, defect engineering, and the dopant effect to address the above
73 ication of nanocomposite hydrogels in tissue engineering applications are described, with specific at
74                                          For engineering applications, however, the failure probabili
75 as systems have potential for many microbial engineering applications, including bacterial strain typ
76 lular urethra bioscaffolds for future tissue engineering applications, using bioscaffolds or bioscaff
77 possess several unique attributes for genome engineering applications.
78  tailored to different biomedical and tissue engineering applications.
79 , civil, materials, electronics and chemical engineering applications.
80 d evidence in the context of a human factors engineering approach as well as educational intervention
81 Herein, we demonstrate a new microstructural engineering approach for producing low-cost titanium all
82 inone monomers we now present a model-driven engineering approach to improve molecular buffering usin
83 s of gene expression dynamics with a reverse engineering approach to infer data-driven dynamic networ
84                 Accordingly, we used a glyco-engineering approach wherein synthetic CD22 ligands link
85 vity and pave the way to explore new protein engineering approaches aimed at designing redox-active p
86 are distinct from commonly leveraged stealth engineering approaches such as nanoparticle surface func
87  and dicot genomes using a variety of genome engineering approaches.
88  recent advances regarding terpene metabolic engineering are highlighted, with a special focus on tob
89                       Advances in biological engineering are likely to have substantial impacts on gl
90        Moreover, recent advances in antibody engineering are providing further improvements in MAb po
91 uman skin is a promising conduit for genetic engineering, as it is the largest and most accessible or
92           A century-old tenet in physics and engineering asserts that any type of system, having band
93                                    In tissue engineering, autofluorescence of polymer scaffolds often
94                      Here we describe genome-engineering based evaluation of RNA regulatory element a
95   Here, an overview of the latest studies on engineering biomaterials for the enhancement of anticanc
96                  Here, we review advances in engineering both imaging modalities and material propert
97 lowering kappaL , but also the importance of engineering both thermal and electronic transport simult
98 o engage with the public on GMOs and genetic engineering broadly.
99 as9 endonucleases are widely used for genome engineering, but our understanding of Cas9 specificity r
100 e assessed the indirect effects of ecosystem engineering by a wood-boring beetle in a neotropical man
101                                           By engineering C-terminal charges, we develop CRY2high and
102                                       Tissue-engineering can serve as an alternative to conventional
103 zed against phase separation by deliberately engineering carrier diffusion lengths and injected carri
104 and fisheries, and those in professional and engineering categories had higher relative mortality ris
105                            In cardiac tissue engineering cells are seeded within porous biomaterial s
106 nd sensing to targeted genome regulation for engineering cellular functions.
107 cations, while avoiding the safety risks and engineering challenges associated with viruses.
108 s, making FTVs impractical due to instrument engineering challenges.
109 rotein design and discuss best practices for engineering chromatin to assist scientists in advancing
110 ived strong interest from the scientific and engineering communities because they offer fresh approac
111 nal (3D) architectures that bypass important engineering constraints and performance limitations set
112 ons show that the inner and outer structural engineering contributing to the synergistic effects of 2
113 ons among plumbing components that undermine engineering controls for opportunistic pathogens (OPs).
114        Improving DGAT activity using protein engineering could lead to improvements in seed oil yield
115      Recently, we have successfully achieved engineering critical current density beyond 2.0 kA/mm(2)
116 s making it a potentially useful pathway for engineering crop plants with improved drought tolerance.
117 logy, quality improvement, cognitive systems engineering (CSE), and applied cognitive psychology.
118 o improve the fuel economy of vehicles using engineering design modifications that compromise other p
119 This fundamental property is used in diverse engineering designs including mechanical, civil, materia
120                 We investigated this idea by engineering di-ubiquitin chains containing differential
121  synthetic biology has been reinvented as an engineering discipline to design new organisms as well a
122 the first focus is a discussion on molecular engineering (e.g., backbone, side chains, and substituen
123 ts), then the discussion moves on to polymer engineering (e.g., molecular weight).
124 to plant growth and defense will help lignin engineering efforts to improve the production of biofuel
125 terparts, indicating that current polymerase engineering efforts would benefit from new benchmarking
126     Our work provides general guidelines for engineering electromagnetic illusions but can be extende
127 ion metal oxides, and provides a pathway for engineering emergent properties in quantum matter.
128 d may greatly accelerate future genome-scale engineering endeavours in yeast.
129                                Incorporating engineering ethics early during the planning stages of o
130 cel based bottom-up model is developed using engineering first-principles to calculate mass and energ
131 ol and has formed the foundation of cellular engineering for adoptive cell therapy in cancer and othe
132                      We argue that metabolic engineering for producing the secondary metabolites in p
133          DSDs have applications in metabolic engineering for the production of valuable protocatechua
134 uld be performed as a function of metal node engineering, framework topology, and/or the presence of
135               He obtained a BSc in aerospace engineering from the University of Cincinnati in 1969 an
136 rotein immobilization strategies is vital to engineering functional hydrogels.
137                                       Tissue engineering, gene therapy, drug screening, and emerging
138  a rich interplay of fundamental science and engineering, give rise to fascinating everyday effects (
139 ed is key to meeting these challenges and to engineering guard cells for improved water use efficienc
140 )H NMR data, demonstrating that model-driven engineering has considerable potential in supramolecular
141                                      Protein engineering has enabled the optimization of existing enz
142      Organoid technology and organ-on-a-chip engineering have emerged as two distinct approaches for
143 ype Spectralis OCT-A (Spectralis; Heidelberg Engineering, Heidelberg, Germany), AngioPlex (Cirrus 500
144 sing a wide-angle Spectralis OCT (Heidelberg Engineering, Heidelberg, Germany).
145                                              Engineering high-energy interfacial structures for high-
146         Finally, we examine possibilities of engineering hormone cross talk for improvement of plant
147 f delivery of immunomodulatory therapeutics, engineering immune cells, and constructing immune-modula
148 t layers revealed the specificity of isotope engineering in a layered material, with a modification o
149  strategy for multiplex combinatorial genome engineering in eukaryotes.
150 d force could be external stimuli for domain engineering in ferroelectrics with significant current l
151                                      Genetic engineering in mice enables the time-controlled labeling
152 hieved in Escherichia coli through molecular engineering, including manipulation of the protein trans
153                                       Strain engineering is a promising method for next-generation ma
154 ticated devices based on 2D materials.Strain engineering is an essential tool for modifying local ele
155                                 Cell surface engineering is an expanding field and whilst extensive r
156 trategy involving outer and inner structural engineering is developed for superior water splitting vi
157                                       Tissue engineering is one of the most prominent examples of int
158 olecular assembly and hierarchical molecular engineering is to control and program the directional se
159                           The goal of tissue engineering is to mitigate the critical shortage of dono
160 thods for widespread epigenome profiling and engineering may generate new avenues for using the full
161       The rapidly improving tools of genetic engineering may make it possible to overcome the humoral
162 derlying distinct cell fates using a reverse engineering method and uncovered the dose-dependent rewi
163 rent capabilities of the widely used protein engineering method, expressed protein ligation.
164                   To enable iterative genome engineering, Millstone allows users to design oligonucle
165 ons of this mechanism can be created through engineering minimal antisense RNAs.
166 responsive fashion, providing a platform for engineering molecular circuits and devices with a wide r
167                                           In engineering MPs, it can be extremely challenging to reta
168 PR solves the major problem of animal genome engineering, namely the inefficiency of targeted DNA cas
169                                              Engineering nanoparticle (NP) functions at the molecular
170 egies of excessive Li and better interfacial engineering need to be investigated.
171        Here the authors develop a screen for engineering new split FPs, and report a yellow-green spl
172 gnant tissue growth, regenerating organs and engineering new-age medical devices.
173        Significant progress has been made in engineering novel aptamer domains for new small molecule
174                             Rational surface engineering of 2D nanoarchitectures-based electrode mate
175       Here, we demonstrate controlled strain engineering of 2D semiconductors during synthesis by uti
176                           Here we report the engineering of a cytochrome P450 enzyme by directed evol
177                        Here, we describe the engineering of a light-activated human caspase-3 (Caspas
178                           Here we report the engineering of a protein scaffold for preferential bindi
179  on a plant FBP appears useful for metabolic engineering of a wide range of crops to enhance the cont
180 es such chromophores are rare, and molecular engineering of absorbers having such properties has prov
181 ity in the biology of real organisms and the engineering of artificial microswimmers.
182 ory control of carotenogenesis and metabolic engineering of carotenoids in light of plastid types in
183 orating cell surfaces with biomolecules, the engineering of cell surfaces with particles has been a l
184  variants, providing a basis for the further engineering of CRISPR-Cpf1.
185                   We used CRISPR/Cas9 genome engineering of Drosophila legless (lgs) and human BCL9 a
186 hape global agriculture through the targeted engineering of endogenous pathways or the introduction o
187 try breaking paves the way for deterministic engineering of fractional quantum Hall states, while our
188 ers (e.g. Sox2-V5 and Sox2-mCherry); and (4) engineering of glioma mutations (TP53 deletion; H3F3A po
189 resent a transformational approach to genome engineering of herpes simplex virus type 1 (HSV-1), whic
190  chemistry, thereby permitting the bottom-up engineering of increasingly complex reaction networks fr
191 ision breeding of plants and animals and the engineering of industrial microbes.
192 ing mathematical modelling and the molecular engineering of insulin itself and its potency, towards a
193 g as promising alternatives to the metabolic engineering of living cells.
194  of co-translational integration and for the engineering of membrane proteins with enhanced membrane
195 benzene as a versatile aromatic scaffold for engineering of molecular materials with tailored and exp
196 r coexistence is a promising route in defect engineering of MoS2 to fabricate suitable devices for el
197                                          The engineering of mouse models of inherited aortopathies ha
198         These results may guide the rational engineering of multilayer and core-shell oxide nanomater
199 ally "noisy" bioenvironments require careful engineering of nanoscale components that are highly sens
200 inimization and potentially accelerating the engineering of next-generation thermoelectric devices.
201 bility of using yeast to accelerate rational engineering of nonribosomal peptide antibiotics.
202                                        Facet engineering of oxide nanocrystals represents a powerful
203 ect extraction, recent progress in metabolic engineering of plants offers an alternative supply optio
204 synthetic biology that involve the multistep engineering of plastid genomes.
205 osts provided proof of concept for metabolic engineering of pseudolaratriene.
206 ht and matter are strongly coupled, allowing engineering of rapid changes in the force landscape, sto
207 evelop and implement strategies for in vitro engineering of replacement kidney tissue, and to devise
208 ed here provide a valuable tool to guide the engineering of specific Env glycoforms for HIV vaccine d
209               This concept of bending strain engineering of spins via topological nanomechanical arch
210 aling will allow improved strategies for the engineering of staple crops to accumulate additional bio
211 rther understanding of stem cell biology and engineering of stem cells for therapeutic applications.
212                      To conclude, mRNA-based engineering of stem cells is a rapid and integration-fre
213 s exciting opportunities for molecular-level engineering of stress-responsive properties of polymers.
214 ities because they offer fresh approaches to engineering of structural hierarchy and adaptive functio
215                                      Genetic engineering of structure-designed bromodomain and plant
216      Many of these projects will require the engineering of substantial changes in fluxes of central
217                In the present study, complex engineering of the carotenoid pathway has been performed
218                           Atomically precise engineering of the position of molecular adsorbates on s
219 essing the quality of the gates used for the engineering of their state.
220 ays, and also examine sample problems in the engineering of these pathways.
221 lications presented, a vision for the future engineering of wood-based materials to promote continuou
222                           Additional surface engineering on the next generation immunogen, DEKnull-2,
223 his living component is rarely considered in engineering operations carried out in these environments
224     The insights we obtain are important for engineering opto-spintronic devices that rely on optical
225 unity or self-targeted cell killing, and the engineering or control of metabolic pathways for improve
226 chieved in the three domains without feature engineering or the use of knowledge sources.
227                         Herein we utilize an engineering perspective to advance understanding of the
228  method can also be incorporated into tissue engineering platforms in which depletion of the stem cel
229 date, conservation investment has emphasized engineering practices or vegetative strategies centered
230 roperties in ceramics through grain boundary engineering, precise mechanical characterization of indi
231 study allowed the formulation of the general engineering principles for the selection of polymeric ma
232                          Here, we define the engineering principles impacting biological activity, de
233 h breeding and through biotechnology and the engineering principles on which increased phytonutrient
234                                   These cell engineering processes need to be carefully controlled an
235                       As the field of tissue engineering progresses ever-further toward realizing cli
236 ied that may be exploited for photosynthesis engineering projects in the future.
237                                 Neuromorphic engineering promises to have a revolutionary impact in o
238 OFs) were investigated as a model system for engineering radionuclide containing materials through ut
239 E to site saturation mutagenesis for protein engineering, reconstruction of adaptive laboratory evolu
240  of biomedical applications including tissue engineering, regenerative medicine, and cell and therape
241  as a platform for synthetic biology, strain engineering remains slow and laborious.
242 as advanced materials in biomedicine, tissue engineering, renewable energy, environmental science, na
243 nce might benefit from deeper involvement in engineering research in the area of health.
244  problem, we demonstrate that modular tissue engineering results in an s.c. vascularized bed that ena
245 es is a promising platform for future tissue-engineering scaffolds and biomedical applications.
246                 Dormancy was also reduced by engineering seed-specific accumulation of jasmonic acid
247 tensively used molecular building blocks for engineering self-assembling materials.
248 rovements in plant photosynthesis by genetic engineering show considerable potential towards this goa
249 pplications such as medical implants, tissue engineering, soft robotics, and wearable electronics.
250 es of the embryonic mesenchyme and establish engineering strategies for more robustly directing tissu
251 n, which may be useful in future dentin-pulp engineering strategies that target fibroblast C5L2 to in
252 oduced from diacylglycerol (DAG), successful engineering strategies to enhance TAG levels have focuse
253 insight for future phenylpropanoid metabolic engineering strategies.
254 s with computational modelling to design the engineering strategy and to understand the metabolic phe
255 bility via a generally applicable orthogonal engineering strategy presented here.
256     Here, we demonstrate a novel dissipation engineering strategy that can support stable oscillation
257 strates the feasibility of applying a tissue engineering strategy towards the development of scalable
258 sfully developed by a simple chemical defect-engineering strategy.
259 antibody specificity as an emerging antibody engineering strategy.
260                               Incoming women engineering students (n = 150) were randomly assigned to
261   Important implications of our findings for engineering synthetic circuits are: (i) sRNAs can potent
262                                              Engineering synthetic pathways for production of alpha-m
263 terologous expression in a modular metabolic engineering system in Escherichia coli Members of the TP
264                                              Engineering T cells with an Akt-insensitive Ezh2 mutant
265 ly applicable as scaffolds in cardiac tissue engineering (TE).
266 romagnetic metals by using various interface engineering techniques is presented, such as inserting a
267                                         Band-engineering techniques should aim to a full control of t
268 es to solve the limitations of materials and engineering techniques.
269 ization treatment offer the possibilities of engineering the advanced hybrid perovskites with specifi
270                                              Engineering the Bacillus paralicheniformis 9945a DISARM
271 NV protease binding affinity, as revealed by engineering the binding loop of aprotinin, a small prote
272                              Our approach of engineering the conserved processes of DNA replication,
273 cks, there has been longstanding interest in engineering the incorporation of alternative extender un
274                                              Engineering the preform structure grants control over th
275 dipose-derived stem/stromal cells (ASCs) for engineering the pulmonary vasculature in a decellularize
276 rical rules are inherently less reliable for engineering the structures of molecular solids.
277 e material system with reduced dimension via engineering the surface boundary conditions.
278 ernative grafting-from strategy for directly engineering the surfaces of live yeast and mammalian cel
279 tes and metamaterials at bulk length-scales, engineering the thermal conductivity at micro- and nano-
280 alidation in cohorts with severe obesity and engineering the variants in model organisms will be need
281 w understanding has emerged renewed hope for engineering these assembly lines to produce new material
282                                     However, engineering this transformation deliberately using ion i
283 so present a possible strategy based on loss engineering to achieve more control over the mode select
284 d will facilitate CAM-into-C3 photosynthesis engineering to enhance water-use efficiency in crops.
285 properties of neuronal dynamics and in neuro-engineering to implement closed-loop applications.
286 hydroxylation in OleTJE could enable protein engineering to improve catalysis or to introduce decarbo
287  (Pik) pentaketides that mimic early pathway engineering to probe the substrate tolerance of the PikA
288 and demonstrate the feasibility of metabolic engineering to produce components of these defense compo
289  use as synthetic biology moves beyond parts engineering to the design and construction of more sophi
290 allenge of chemistry, materials science, and engineering to understand and mimic biological systems t
291                                  The genetic engineering tools and resources established in this stud
292                                        Since engineering trimers can be limited by the difficulty of
293 ermoelectric materials through crystal phase engineering using a strategy of entropy stabilization of
294                                  The entropy engineering using multicomponent crystal structures or o
295 molecule superresolution imaging and genetic engineering, we study in living Escherichia coli cells t
296 s in metal-free catalysis or organic crystal engineering, where double-H-bonding donor boronic acids
297 us propose new approaches of plant metabolic engineering, which are inspired by an ancient Chinese ir
298 -mismatched constituents also enables strain-engineering, which can be used to further enhance materi
299            Approaches that integrate vaccine engineering with an understanding of evolution and epide
300 validates the promising combination of plant engineering with microbial chassis development for the p

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