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1 her domains (food, cosmetic, pharmaceutical, biomedical).
2 nd social aspects of the disease rather than biomedical.
3 for metal additive manufacturing (AM) in the biomedical and aerospace industries, variability in the
4 ultiple industries, including the aerospace, biomedical and automotive industries.
5  thus holds considerable promise for diverse biomedical and biodefense applications.
6  presenting at the Eye Clinic, Department of Biomedical and Clinical Sciences, Luigi Sacco Hospital,
7 nditions would be a significant advantage in biomedical and clinical studies where untouched and unmo
8 stomer is a highly promising biomaterial for biomedical and engineering applications.
9  may open up new avenues for 2D materials in biomedical and environmental applications.
10  diverse applications in microbiology and in biomedical and forensic studies of humans and other mult
11 mine and their derivatives for the safety of biomedical and health care fields in broad scales.
12 ological cells is critical in a diversity of biomedical and industrial applications.
13 sis of ssDNA that can be used for a range of biomedical and nanotechnology applications.
14 alization of various photonic, data storage, biomedical and optoelectronic applications.
15 gs, and behaviors are used in many fields of biomedical and social science.
16 , for policy, and for future research in the biomedical and social sciences.
17 porphyrins) promise to be of utility in many biomedical and technical applications.
18 mplemented and readily tailored to different biomedical and tissue engineering applications.
19 or molecular ions relevant to environmental, biomedical, and other related areas.
20 d pigs holds great promise for agricultural, biomedical, and pharmaceutical applications.
21                               We demonstrate biomedical applications and verify cell viability in our
22 adhesives for soft substrates (including for biomedical applications and wearable electronics).
23                                        Their biomedical applications are contingent upon retaining th
24                                     However, biomedical applications are limited due to the low selec
25  microscopy (PAM) is uniquely positioned for biomedical applications because of its ability to visual
26  more stable than their RNA counterparts for biomedical applications but have the disadvantage of lac
27 that are better suited for drug delivery and biomedical applications by reducing the possible cytotox
28  has shown potential among a wide variety of biomedical applications especially within the context of
29            Multifunctional nanoparticles for biomedical applications have shown extraordinary potenti
30 ion, paving the way for broad industrial and biomedical applications in processing and securing 3D da
31 erties of CAP have led to its use in various biomedical applications including cancer therapy.
32      Hydrogels are used in a wide variety of biomedical applications including tissue engineering, bi
33 lly resilient and can be used for a range of biomedical applications including tissue engineering, re
34 hroic targeting of chiral nanostructures for biomedical applications is exemplified here as photodyna
35 rge library of candidates for developing the biomedical applications of assemblies of small molecules
36 light the various fabrication principles and biomedical applications of avidin-based nanoparticles in
37                    A brief overview of other biomedical applications of nanoplatinum is also presente
38                                          The biomedical applications of YSNs including biosensing, bi
39 nsive overview of the design, synthesis, and biomedical applications of YSNs is presented.
40 xt of self-assembling nanocarriers usable in biomedical applications such as drug delivery, macroscop
41 s for mimicking biological membranes and for biomedical applications such as targeted drug and gene d
42  highly useful for a variety of research and biomedical applications, but current applications for na
43  examine these materials for their potential biomedical applications, cytotoxicity of nanofibers agai
44  up new possibilities across a wide range of biomedical applications, especially for the study of neu
45 ith enzyme-mimetic properties have found new biomedical applications, from biofilm disruption to prot
46                               In the area of biomedical applications, graphene is especially involved
47 ucial for progressing several biological and biomedical applications, including in meso membrane prot
48   Nanomaterials have been developed for many biomedical applications, including medical imaging, drug
49 , has been increasingly used in a variety of biomedical applications, including tissue imaging of cli
50                                           In biomedical applications, nanoparticles have opened new h
51 ected to have a profound impact upon diverse biomedical applications, providing unlimited opportuniti
52                              Appropriate for biomedical applications, the method could be used on an
53 sired properties for drug delivery and other biomedical applications, while avoiding the safety risks
54 viability, opens the door to a wide range of biomedical applications, yet this remains a significant
55  functional nanomaterials for biological and biomedical applications.
56 and cobalt-doped magnetite nanoparticles for biomedical applications.
57 on of cyanobacteria for biotechnological and biomedical applications.
58 ical to the utilization of nanotechnology in biomedical applications.
59 gning effective polymeric nanostructures for biomedical applications.
60 and to explore novel horizons for enzymes in biomedical applications.
61 his process can have a significant impact in biomedical applications.
62 ned structure that have a high potential for biomedical applications.
63 ls have emerged as a promising candidate for biomedical applications.
64 le played by nanotopography and chemistry in biomedical applications.
65 ful for imaging activated T cells in various biomedical applications.
66 rest as protective coatings from aviation to biomedical applications.
67  to produce mechanical actions on tissue for biomedical applications.
68 ranging from gravitational wave detection to biomedical applications.
69 tation for a variety of in vitro and in vivo biomedical applications.
70 of the inks, extending their possible use to biomedical applications.
71 re point of care devices and advancements in biomedical applications.
72 ted as multifunctional probes for a range of biomedical applications.
73  to be promising materials, particularly for biomedical applications.
74 size limitations reduce power efficiency for biomedical applications.
75 nergy storage, catalysis, environmental, and biomedical applications.
76 nting allows fabrication of 3D scaffolds for biomedical applications.
77 itivity and paves the way for many important biomedical applications.
78  biological delivery agents for research and biomedical applications.
79 ial to be used for both in vitro and in vivo biomedical applications.
80 N2 -diazirines as molecular imaging tags for biomedical applications.
81  for future tissue-engineering scaffolds and biomedical applications.
82 w technologies with chemical, biological and biomedical applications.
83  these nanoscale constructs open avenues for biomedical applications.
84  opal scaffolds have found widespread use in biomedical applications.
85 lls and organs is an important tool for many biomedical applications.
86               We demonstrated three distinct biomedical applications: (a) molecular imaging of blood
87 nlimited source of functional cells for many biomedical applications; however, the development of cel
88  integrated use of the multiple contemporary biomedical assays and technologies that motivate them, w
89 zed for a variety of applications, including biomedical, at low cost.
90 , skills, and motivation leading to improved biomedical, behavioural, and psychosocial outcomes.
91 series of applications including biological, biomedical, biotechnological, clinical and medical diagn
92 e in the current era in which data-intensive biomedical characterization of individuals is possible,
93  used in various fields including aerospace, biomedical, civil engineering, construction, protective
94 tic excesses, which might slow down creative biomedical clinical research without necessarily restric
95 ere significant at the 95% CI level, whereas biomedical coefficients were 0.00-0.10 SD and eight of 5
96 us support to the international genomics and biomedical communities through a web-based, open source
97 ng architecture, and the challenges that the biomedical community faces when trying to translate disc
98        There is an emerging consensus in the biomedical community for the use of large animal models
99    All mice will be readily available to the biomedical community.
100  expanded endeavour to share data across the biomedical community.
101 uable for improving how early-stage academic biomedical concepts are cultivated, culled, and manicure
102 o narrow the gap between needed and existing biomedical data science skills.
103 d is demonstrated on simulated data, various biomedical data sets and a clinical data set, to which d
104 ets, including simulated classifier outputs, biomedical data sets from the University of California,
105 y used constructs for encoding and analyzing biomedical data, but the absence of simple and consisten
106        In three case studies using published biomedical data, the results are compared with NSC and S
107 w, which involved searching 15 international biomedical databases for published and unpublished evide
108  Raman spectroscopy (SERS) in biological and biomedical detection schemes is feasible due to its exce
109 atal, and child health programmes focused on biomedical determinants might not sufficiently enhance c
110 ty and robustness as a potential implantable biomedical device.
111 ng), sensors (electrochemical, biochemical), biomedical devices (magnetic resonance imaging, X-ray co
112 sensors, bioelectronics and state-of-the-art biomedical devices in the future.
113 d wider applicability in many areas, such as biomedical devices or regenerative medicine.
114 to solve, on the way to the manufacturing of biomedical devices, including the lack of standardizatio
115 rse applications from printed electronics to biomedical devices.
116 robots, morphing antenna and RF devices, and biomedical devices.
117 These NPs labels have excellent potential in biomedical diagnostics, particularly when high signal to
118 tonomous sensing, distributed computing, and biomedical diagnostics.
119 o revolutionize many technologies, including biomedical diagnostics.
120 in the general domain are not generic in the biomedical domain due to their referents to specific cla
121 em and benefits from semantic information of biomedical entities.
122 w that semantic information is beneficial to biomedical entity normalization and can be well combined
123 ural network (CNN) architecture that regards biomedical entity normalization as a ranking problem and
124    Experiments on two benchmark datasets for biomedical entity normalization show that our proposed C
125                        Most state-of-the-art biomedical entity normalization systems, such as rule-ba
126 portance for a wide range of applications in biomedical, environmental, and material sciences.
127                        Cell cultures used in biomedical experiments come in the form of both sample b
128 or psoriasis and evaluated psychological and biomedical factors associated with non-adherence using m
129 porated in many emerging applications in the biomedical field including chemical sensing, biological
130 ts of the graphene family materials into the biomedical field.
131 uitable for applications in the industry and biomedical field.
132  potential applications in environmental and biomedical fields as well.
133 t interest in both the biopharmaceutical and biomedical fields.
134 n be expanded to a variety of biological and biomedical fields.
135 vant for optimizing antiretrovirals used for biomedical HIV prevention in women.
136           We discuss the contribution of new biomedical HIV prevention strategies and risk compensati
137 essed the effects of MMN and associations of biomedical (ie, maternal and child anthropometry and hae
138                                       Modern biomedical imaging has revolutionized life science by pr
139 he NIR-II window opens new opportunities for biomedical imaging of deep tissues with improved contras
140 cal coherence tomography (OCT) is a powerful biomedical imaging technology that relies on the coheren
141 cts, which is of interest in remote sensing, biomedical imaging, as well as monitoring of laser ablat
142 n alternative to MRI and X-ray tomography in biomedical imaging, due to its ability to afford high-re
143 t of a 3D OrbiSIMS instrument for label-free biomedical imaging.
144 unctions for many-channel data from emerging biomedical-imaging techniques.
145 ospace industry, cutting and drilling tools, biomedical implants, among many others.
146  Factor Ontology (EFO), and the Ontology for Biomedical Investigation (OBI).
147  transcriptional regulation, is intended for biomedical investigators who work on understanding the r
148 philosophy, however, can handle contemporary biomedical issues.
149 LTN), a heterogeneous network generated from biomedical linked datasets.
150 r objective was to systematically review the biomedical literature and synthesize data for prognostic
151  nomenclature, both in Vivo, and in Vitro in biomedical literature by using text mining methods and p
152 tilation population, only 14 articles in the biomedical literature have tested patient-level factors
153 ive terms (iTerm) that are obtained from the biomedical literature using the eGIFT text-mining system
154 To determine, using systematic review of the biomedical literature, whether pacing reduces risk of re
155  association with cancer, based on available biomedical literature.
156 ing sensing scheme will be useful for future biomedical microsystems.
157 c diversity, and have long been an important biomedical model for a variety of human diseases and in
158                        Pigs are an important biomedical model species and a key source of animal prot
159 ntation of sexuality held (personhood versus biomedical model), nursing home staff adopted a role or
160                           As a long-standing biomedical model, rats have been frequently used in stud
161 easure for interactions in pathways or other biomedical models.
162 d as an additional measure of confidence for biomedical models.
163 ly them to a large number of varied existing biomedical named entity datasets.
164 ily to automate routine and dangerous tasks, biomedical nanorobots are designed for complex, physiolo
165 ogress in the field of automated curation of biomedical networks and models, aided by text mining met
166 teronuclear spins, and thus is promising for biomedical NMR and MRI applications.
167                                          All biomedical (not psychological or social) outcomes in all
168  completed the CALERIE 2 study at Pennington Biomedical.Of 39 participants who were in the follow-up
169 enges in the development and applications of biomedical ontologies to represent and analyze experimen
170  schema involves mapping samples to terms in biomedical ontologies, labeling each sample with a sampl
171 brought together experimental biologists and biomedical ontologists to discuss solutions to organizin
172 CELLS at the the International Conference on Biomedical Ontology (ICBO).
173  on CELLS at the International Conference on Biomedical Ontology has brought together experimental bi
174                                     However, biomedical ontology-based named entity recognition conti
175 is the design of micro-/nanoscale robots for biomedical operations.
176 etal nanoparticles are of broad interest for biomedical, optical and catalytic applications.
177 their assembly behaviours and optimize their biomedical performances.
178 tructural and compositional information from biomedical, pharmaceutical, or clinical samples, among o
179                                   Samples of biomedical polyester (Max-Prene 955) and a fluoropolymer
180                     Concurrently, water-rich biomedical polymers are elastic but weak.
181 ll AuNPs open up a pathway to maximize their biomedical potentials and minimize their toxicity in the
182 xplores the parallels with the 1990s and the biomedical preprint movement of today.
183 ticles and cells is critical to a variety of biomedical processing steps for medical diagnostics and
184 us problem hampering their widespread use in biomedical products.
185 for matching nutritional needs to individual biomedical profiles and the issues surrounding them.
186  date, many reviews have been focused on the biomedical properties and applications of CS-based nanoc
187  of investment and for funding innovation in biomedical R&D.
188  of IDUP to discover ligands for proteins of biomedical relevance.
189  experiments are increasingly commonplace in biomedical research and add layers of complexity to expe
190 uld have a significant impact in fundamental biomedical research and clinical applications.
191 es in the field of thiol-reactive probes for biomedical research and diagnostics, emphasizing the nee
192  widespread use for toxicological screening, biomedical research and pharmaceutical studies, to date
193 hod can be widely applied in biochemical and biomedical research and provide insights into elucidatin
194 Pluripotent stem cells have broad utility in biomedical research and their molecular regulation has t
195 avenue for drug delivery in a broad range of biomedical research and therapeutic applications.
196 s are an ideal animal model for a variety of biomedical research areas such as cancer, virology, circ
197 al Marsden and Institute for Cancer Research Biomedical Research Centre and is coordinated by the Med
198 also supported and partly funded by UCLH/UCL Biomedical Research Centre and The Royal Marsden and Ins
199 ings deserve much broader recognition by the biomedical research community and are highlighted here,
200                                          The biomedical research enterprise depends on the fair and o
201  been raised about the sustainability of the biomedical research enterprise in the United States.
202 forces and improve the sustainability of the biomedical research enterprise.
203 fish is fast becoming a species of choice in biomedical research for the investigation of functional
204                                           As biomedical research has evolved over the past century, t
205 nslational processes for technology-oriented biomedical research have led to some prominent and frequ
206 The pig is recognized as a valuable model in biomedical research in addition to its agricultural impo
207  The field is needed to advance cutting-edge biomedical research in domains in which the benefits to
208 nt annotation methods in order to facilitate biomedical research in epigenomics.
209                                           As biomedical research increasingly relies on computational
210  distinction between basic and translational biomedical research is an anachronism.
211            The thesis presented here is that biomedical research is based on the trusted exchange of
212                      A cornerstone of modern biomedical research is the use of animal models to study
213 ogies offer new options for developing novel biomedical research models and for gene and stem cell ba
214 ning material derived from animal studies in biomedical research more visible and accessible to the s
215 hed analytical method that was first used in biomedical research over 20 years ago.
216 promote understanding of a host of important biomedical research questions for which hamsters are an
217                                              Biomedical research relies on the fast and accurate prof
218                                         Many biomedical research studies use captive animals to model
219 olymer-based nanodiscs are valuable tools in biomedical research that can offer a detergent-free solu
220               There is a continued desire in biomedical research to reduce the number and duration of
221 ok at biological matrices, in particular for biomedical research, although there is still a lot of de
222 easingly used for synthesis of evidence from biomedical research, and often include an assessment of
223 n for transplantation, transfusion and basic biomedical research, as well as technological applicatio
224 SMLM) has become a powerful imaging tool for biomedical research, but it is mostly available in imagi
225                              In the field of biomedical research, deconvolution analysis is applied t
226         Detecting such genes is important in biomedical research, e.g. when identifying genes respons
227 roscopy and tomography techniques applied to biomedical research, especially the study on organism-le
228 sed metabolomics becomes more widely used in biomedical research, it is important to revisit existing
229 today's environment of shrinking budgets for biomedical research, minimizing regulatory burden-partic
230              Despite decades of clinical and biomedical research, the pathogenesis of sepsis and its
231           In addition to its applications in biomedical research, the rapid readout of our platform w
232 several applications of these nanoprobes for biomedical research, with a focus on intraoperative canc
233      The UK Biobank is a unique resource for biomedical research, with extensive phenotypic and genet
234 nities to address long standing questions in biomedical research.
235 luciferase-luciferin pairs is widely used in biomedical research.
236 dditional image analysis applications across biomedical research.
237 rly in vivo, provides an invaluable tool for biomedical research.
238 alytical chemistry in the context of current biomedical research.
239 molecular specificity is highly desirable in biomedical research.
240 al samples, which is useful to many areas of biomedical research.
241  have been sequenced, contributing deeply to biomedical research.
242  manner is of great interest in the field of biomedical research.
243 philosophy that will accompany and supervise biomedical research.
244 increasingly being applied in many fields of biomedical research.
245  tools from the human proteome to facilitate biomedical research.
246 ficient mice have been used predominantly in biomedical research.
247 e of ethylbenzene, a compound of interest in biomedical research.
248  of pigs in both agricultural production and biomedical research.
249  a species that has been used extensively in biomedical research.
250 ng programmable nucleases has revolutionized biomedical research.
251  their kicks by solving puzzles that advance biomedical research.
252 miRNAs and diseases is a critical problem in biomedical research.
253 can be extensively applied in biological and biomedical research.
254 ology play a critical role in bioscience and biomedical research.
255 particles, thus offering new applications in biomedical research.
256 ivery tools for therapeutic applications and biomedical research.
257 , renewed strategies for vector control, and biomedical research.
258 bute billions of dollars annually to support biomedical research.
259 ential components of experimental designs in biomedical research.
260 nome-editing applications has revolutionized biomedical research.
261           Healthy volunteers are crucial for biomedical research.
262 , reproducibility, and open science in basic biomedical research.
263 tation, that can benefit both physicians and biomedical researchers to better diagnose and monitor di
264 id adoption of CRISPR technology has enabled biomedical researchers to conduct CRISPR-based genetic s
265 pts and pipelines, making it problematic for biomedical researchers.
266 se organizations, registries, clinical labs, biomedical resources, and clinical software tools and wi
267                                     A PhD in biomedical science and the critical thinking skills that
268                                              Biomedical science benefits when plain language allows p
269       The United States has been a leader in biomedical science for decades, in large part because of
270  reduce future US discoveries in fundamental biomedical science.
271 his type of memory has exciting potential in biomedical sciences as data storage can be coupled to se
272  empirical studies throughout the social and biomedical sciences focus only on very narrow outcomes s
273 osophical shift has occurred in the field of biomedical sciences from treatment of late-stage disease
274 advantages, its translational application in biomedical sciences has been limited.
275 anotomography, FIB-nt) typically used in the biomedical sciences to the study of natural flocculated
276 nt, SPR application in stem cell biology and biomedical sciences was underused.
277 entific problems that can be accessed in the biomedical sciences.
278 act that cuts across most disciplines of the biomedical sciences.
279   Our work opens new perspectives for PAM in biomedical sciences.Photoacoustic microscopy allows for
280 arable electronics devices for a plethora of biomedical sensing applications.
281 ields including communications, chemical and biomedical sensing, signal processing, multiprocessor ne
282                                 Yet suitable biomedical sensors to monitor body fat burn rates in sit
283 are useful for applications in the fields of biomedical sensors, spectroscopy, fluorescence lifetime
284 as enabled sensitive sensing capabilities in biomedical settings and the addition of an MOF coating o
285 hophysiological conditions with considerable biomedical significance; one example is the formation of
286  open data to make breakthroughs that are of biomedical significance; second, to illustrate that fund
287  has recently re-emerged as a focal point of biomedical studies and, as a result, developmental biolo
288 unication, superbright solid-state lighting, biomedical studies, fluorescence, etc.
289  network encoding knowledge from millions of biomedical studies.
290 h questions in seven domains: a) mechanistic biomedical studies; b) exposure science; c) epidemiology
291 hanical systems to large scale aerospace and biomedical systems.
292            In recent years, vast advances in biomedical technologies and comprehensive sequencing hav
293                                      Current biomedical technologies, which seek to design an implant
294 thout the availability of vaccines and other biomedical technologies.
295  also of practical importance for energy and biomedical technologies.
296 te textual uncertainty being acknowledged in biomedical text mining as an attribute of text mined int
297     Named entity recognition is critical for biomedical text mining, where it is not unusual to find
298 s such as geological subsurface modelling or biomedical tissue analysis.
299 ding proteins, which in turn complicates the biomedical use of this class of biomolecules.
300 degraded by proteases, which may limit their biomedical utility.

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