ライフサイエンスコーパス: biomedical

1 ed entity recognition of disease mentions in biomedical abstracts, but did not know if this was true

2 rning model for recognizing PICO elements in biomedical abstracts.

3 alTrials.gov NCT04338360.FUNDINGMayo Clinic, Biomedical Advanced Research and Development Authority (

4 lone acetonide suspension (CLS-TA; Clearside Biomedical, Alpharetta, GA) administered suprachoroidall

5 es was highlighted and the applicability for biomedical analyses was demonstrated, measuring miRNA-49

6 It is of great interest for a biomedical analyst or an investigator to correctly model

7 e biology and evolution of miRNAs as well as biomedical and biomarker research.

8 areas of drug discovery, vaccine design, and biomedical and biotechnology research.

9 Harnessing the expertise of the biomedical and clinical communities is imperative to exp

10 iomarker for stress monitoring; however, the biomedical and clinical relevance is still controversial

11 Biomedical and clinical sciences are experiencing a rene

12 d opportunities, and expertise from multiple biomedical and engineering fields will be needed to full

13 population, which has inevitably led to new biomedical and environmental issues.

14 We discuss their usage in various biomedical and environmental monitoring applications, fr

15 its genetics is therefore required for both biomedical and evolutionary studies.

16 net search data to identify and characterize biomedical and health sciences faculty at US higher educ

17 t screening applications of relevance to the biomedical and pharmaceutical sectors.

18 ompounds with various properties valuable to biomedical and polymer industries.

19 fferent fields, such as energy, electronics, biomedical, and water treatment, no reviews have revisit

20 Then, the realization, characterization and biomedical application of natural and synthetic thermore

21 at potential as an off-the-shelf therapy for biomedical application such as drug delivery and regener

22 gical or biochemical stimuli have found many biomedical applications for tissue engineering, therapeu

23 d heteromultivalent DNA will offer important biomedical applications given the utility of DNA-functio

24 The development of nanoparticle-based biomedical applications has been hampered due to undesir

25 ities and selectivities, raising the hope of biomedical applications in the near future.

26 and state-of-the-art progress related to the biomedical applications of BiNPs with different structur

27 cal fluids poses a considerable roadblock to biomedical applications of DNA nanotechnology.

28 The biomedical applications of the m-bots in diagnosis, sens

29 d into hard-to-reach tissues for a number of biomedical applications ranging from targeted drug/gene

30 residues is important for bioengineering and biomedical applications relying on TMP systems, in which

31 successful integration of nanoparticles into biomedical applications requires modulation of their sur

32 Hydrogels for biomedical applications such as controlled drug release

33 are one of the most promising candidates for biomedical applications such as magnetic hyperthermia an

34 ts in confined spaces and may enable various biomedical applications such as regenerative repair in m

35 e focus of investigation for a wide range of biomedical applications that fall into the categories of

36 II fluorophores have shown great promise for biomedical applications with superior in vivo optical pr

37 phase, as a promising magnetic material for biomedical applications with superior magnetic performan

38 The properties of WSCC hosts associated with biomedical applications, and their use as vessels to car

39 g techniques becomes the crucial step toward biomedical applications, especially for the in vivo uses

40 crocomposite cryogels show great promise for biomedical applications, especially in tissue engineerin

41 rivatives are to become useful materials for biomedical applications, it will be necessary to evaluat

42 a common type of functionalized ENP used in biomedical applications, on cultured primary neurons har

43 ical tensions is of great importance in many biomedical applications, such as RBC damage (hemolysis)

44 s have had demonstrated successes in several biomedical applications, they are difficult to use for n

45 and development of biopolymer hydrogels for biomedical applications, with an emphasis on biopolymer

46 r device technologies for bioengineering and biomedical applications.

47 modification, and summarize the most recent biomedical applications.

48 hemical diversity that can be repurposed for biomedical applications.

49 ic degradation, boosting their potential for biomedical applications.

50 fluorescent materials known and suitable for biomedical applications.

51 systems for a range of biotechnological and biomedical applications.

52 s for molecular diagnostics and image-guided biomedical applications.

53 the identification of gold nanoparticles for biomedical applications.

54 roughput, size-based cell sorting in diverse biomedical applications.

55 rticles are used in an expanding spectrum of biomedical applications.

56 rties also drive a variety of industrial and biomedical applications.

57 responses, thereby enabling a broad range of biomedical applications.

58 ytes is an emerging approach in a variety of biomedical applications.

59 re among the most studied nanostructures for biomedical applications.

60 s applications, spanning from bioanalysis to biomedical applications.

61 ted materials as sonosensitizers for various biomedical applications.

62 eir function in, e.g., biological systems or biomedical applications.

63 esive properties have potential for numerous biomedical applications.

64 volutionary forces and can be engineered for biomedical applications.

65 eir potential for solar-driven chemistry and biomedical applications.

66 combination thereof is essential for various biomedical applications.

67 igestion, which limits their utility in many biomedical applications.

68 ms, performance validation/optimization, and biomedical applications.

69 e) (PLGA) have been demonstrated for diverse biomedical applications.

70 ntroduce unique properties, from textiles to biomedical applications.

71 nd the development of synthetic fusogens for biomedical applications.

72 paper) for diagnostics and drug delivery for biomedical applications.

73 velopment of novel epigenetic inhibitors for biomedical applications.

74 cle (VLP) conjugates are being developed for biomedical applications; however, there is a lack of qua

75 particular species or habitats and targeted biomedical approaches (targeted reactive approaches) mig

76 arly important for applications of AutoML to biomedical big data analysis.

77 logies such as in-depth molecular profiling, biomedical big data and machine intelligence methods wil

78 On the other hand, paving the way to biomedical breakthroughs and discoveries requires granti

79 The story of twentieth century biomedical breakthroughs could be told through cholester

80 in cultures and in bioengineered grafts is a biomedical challenge that has yet to be met(3-9).

81 (ADCs) have recently gained traction in the biomedical community due to their promise for human ther

82 riations, the method has been widely used in biomedical computation, for instance in the genome-wide

83 Despite multiple attempts, existing biomedical concept embeddings generally suffer from subo

84 of the largest among the publicly available biomedical concept embeddings to date.

85 BioConceptVec covers over 400,000 biomedical concepts mentioned in the literature and is o

86 more than 30,000 datasets hosted from major biomedical consortia, users may contribute their own dat

87 Methods: (132)La was produced on a biomedical cyclotron.

88 and sparse data, which is something usual in biomedical data and biomarkers analysis.

89 However, the biomedical data inequality between different ethnic grou

90 ng these subtypes in noisy, high dimensional biomedical data is often impossible for humans and chall

91 mall sample size, particularly when studying biomedical data may hinder the use of classical statisti

92 However, one challenge for large-scale biomedical data on the cloud is providing secure access,

93 More than the sheer size of biomedical data, it is the layering of multiple data mod

94 However, in biomedical data, there are often baseline characteristic

95 mputational workbench where users can access biomedical datasets across multiple cloud computing plat

96 d extensible approach for securely accessing biomedical datasets distributed across cloud computing p

97 the genomics era, the availability of large biomedical datasets with genome-wide readouts has the po

98 nables an end-to-end exploratory analysis of biomedical datasets, giving researchers a clearer pictur

99 cs, researchers strive to build cutting-edge biomedical devices capable of detecting health-monitorin

100 of interest for microscale soft robotic and biomedical devices.

101 ding soft robotics, morphing structures, and biomedical devices.

102 arable electronics, consumer electronics and biomedical devices.

103 of scientific publications in the fields of biomedical diagnosis, food safety, environmental health,

104 gesting a promising application potential in biomedical diagnostics.

105 f genomics data sets, designed to accelerate biomedical discovery.

106 MF is also applied to data from the biomedical domain and its performance is compared with a

107 synthetic antibodies have found favor in the biomedical domain since 2010, when for the first time, t

108 training corpora, which is a problem in the biomedical domain with its often rather small gold stand

109 tilized in many applications including food, biomedical, electroanalysis, energy storage, wastewater

110 cantly contributed to the recent progress in biomedical electron paramagnetic resonance (EPR) due to

111 due to their suitability for applications in biomedical engineering and environmental remediation.

112 ts microbial EPSs have a promising future in biomedical engineering and medicine, especially as an al

113 The unmet chemistry and biomedical engineering challenge to develop controlled r

114 -optical chips in photonics, photochemistry, biomedical engineering, chemical engineering, and beyond

115 ng and detection (LiDAR), machine vision and biomedical engineering; however, bulky system size and s

116 34 different corpora covering five different biomedical entity types, yielding an average increase in

117 gical fluids is increasingly required in the biomedical environment.

118 HS motifs which is crucial for their future biomedical exploitation.

119 choice of appropriate application within the biomedical field.

120 ded the applicability of fluorescence in the biomedical field.

121 applicable in many other scenarios from the biomedical field.

122 et oxygen ((1)O(2)) in the environmental and biomedical fields has motivated research for effective (

123 stablished tool for cell analysis in diverse biomedical fields such as cancer biology, microbiology,

124 lts and deserve more attention in the future biomedical graph analysis.

125 from archaeological populations using mu-CT biomedical imaging and geometric morphometric analyses.

126 ractically applied techniques for ultrasonic biomedical imaging employ delay-and-sum (DAS) beamformin

127 Biomedical imaging is a driver of scientific discovery a

128 l process with application to drug delivery, biomedical imaging, separation, and mixing.

129 njectable hyperpolarized contrast agents for biomedical imaging.

130 properties have become vital to the field of biomedical imaging.

131 gital holography, optical communications and biomedical imaging.

132 sed materials are used in medical lasers and biomedical implants.

133 are increasingly needed to support advanced biomedical information management and discovery applicat

134 l to be applied in the future development of biomedical instruments and therapeutics.

135 ely important class of epigenetic enzymes of biomedical interest.

136 autistic humans, and providing guidance for biomedical interventions.

137 Research waste is highly prevalent across biomedical investigations.

138 alkaloids and related structures for future biomedical investigations.

139 endly data portal, enabling a broad range of biomedical investigations.

140 We use biomedical knowledge bases to create a knowledge graph o

141 ere we describe the breadth and depth of the biomedical knowledge contained within Wikidata, and disc

142 for the real-time synthesis of institutional biomedical knowledge.

143 nduct a systematic comparison on 3 important biomedical link prediction tasks: drug-disease associati

144 Recently, biomedical literature has been considered as a valuable

145 Curation of the biomedical literature in an effort to extract this infor

146 Biomedical literature is growing at a rate that outpaces

147 irect relationships among genes based on the biomedical literature mining data.

148 , ProQuest Dissertations and Theses, Chinese BioMedical Literature Service System, WANFANG database,

149 Given the rapid growth of biomedical literature, it is paramount to build tools th

150 itizing microbial metabolites from published biomedical literature, which can set a foundation for fu

151 -associated variants are still hidden in the biomedical literature.

152 o keep up with the exponential growth of the biomedical literature.

153 riant-genotype-phenotype associations in the biomedical literature.

154 as genes and mutations, are mentioned in the biomedical literature.

155 iew thus addresses four different aspects of biomedical m-bots: design/fabrication, functionalization

156 tions, in soft robotics, adhesive systems or biomedical medical devices.

157 se results have importance toward developing biomedical microdevices for drug discovery, antibiotic r

158 e chromosomes and was especially high in the biomedical model breeds such as SNU (100%) and NIH (76%)

159 he new state-of-the-art performance on seven biomedical nested event extraction tasks.

160 On the other hand, for a variety of biomedical network analysis tasks, traditional technique

161 works and are not comprehensively studied on biomedical networks under systematic experiments and ana

162 groups) for various applications, including biomedical NMR and MRI of cellular and in vivo metabolis

163 inoids affect brain development an important biomedical objective.

164 different application fields, including the biomedical one.

165 data, including the crowdsourced curation of biomedical ontologies, phenotype-based diagnosis of dise

166 ation of ionic gold emphasizes its potential biomedical opportunities while reducing the quantity of

167 This is largely because most biomedical PhD graduates do not become Principal Investi

168 To demonstrate its biomedical potential, we further induce in-situ biosynth

169 ve compounds of immense biotechnological and biomedical potential.

170 has made the development of a vaccine a top biomedical priority.

171 We demonstrate HFM for several physical and biomedical problems by extracting quantitative informati

172 s into cells via electroporation is a common biomedical procedure, its protocols are often based on t

173 e realization of peptide nanotechnology into biomedical products.

174 s, systems biology analytical approach using biomedical profiles from fifty-nine astronauts and data

175 robial metabolites from 28 million published biomedical records.

176 We propose a novel sequence labeling-based biomedical relation extraction method named Bio-Seq.

177 athogenesis can therefore enable grading the biomedical relevance for specific pathways within specif

178 Despite its biomedical relevance, the origin of the phenomenon is st

179 r of Pseudomonas-phages that have increasing biomedical relevance.

180 creening deck at the Novartis Institutes for BioMedical Research (NIBR).

181 despite the importance of these animals for biomedical research and agriculture.

182 intelligence (AI) is increasingly applied to biomedical research and clinical decisions, developing u

183 arities through data-driven, algorithm-based biomedical research and clinical decisions.

184 s with focusing on the future application in biomedical research and clinical diagnosis.

185 TANCE Animal models are crucial in advancing biomedical research and defining the pathogenesis of hum

186 inding to antibodies, which are critical for biomedical research and disease diagnosis and treatment.

187 The COVID-19 pandemic has broadly impacted biomedical research and health care.

188 f carcinogenicity has become a main focus of biomedical research and regulatory toxicology.

189 ted to supporting the safety of the nation's biomedical research and training environments.

190 iting in eukaryotes has revolutionized basic biomedical research and translational sciences.

191 lenges of these systems in basic and applied biomedical research are presented and discussed.

192 ssion under NIR laser radiation are the main biomedical research areas involving BiNPs that have open

193 lysis of a comprehensive corpus of published biomedical research articles, we measure whether the NIH

194 PR-Cas genome engineering has revolutionized biomedical research by enabling targeted genome modifica

195 itute of Health Research in part through the Biomedical Research Centre at University College London

196 NIHR Imperial Biomedical Research Centre, as part of the NIHR Health I

197 idemic Preparedness Innovations, NIHR Oxford Biomedical Research Centre, Thames Valley and South Midl

198 tute for Health Research (NIHR), NIHR Oxford Biomedical Research Centre, Thames Valley and South Midl

199 ational Institute for Health Research Oxford Biomedical Research Centre, UK Medical Research Council,

200 ational Institute for Health Research Oxford Biomedical Research Centre.

201 Institute of Health and Research Manchester Biomedical Research Centre.

202 om five collaborating hospitals hosting NIHR Biomedical Research Centres in the UK (all tertiary cent

203 d the National Institute for Health Research Biomedical Research Centres.

204 sing quality and quantity of imaging data in biomedical research comes the demand for computational m

205 offers a platform in which the chemistry and biomedical research communities can access a comprehensi

206 Here, we describe how members of the biomedical research community can use GDV and the relate

207 APAatlas will help the biomedical research community elucidate the functions an

208 n steadily since they were introduced to the biomedical research community in the late 1970s, and we

209 n effort to ameliorate this devastation, the biomedical research complex has allocated billions of do

210 ty research needs across the prostate cancer biomedical research domain, Movember conducted a landsca

211 , and reduce illness and disability," the US biomedical research enterprise must directly confront th

212 uals for a broader expanse of careers in the biomedical research enterprise.

213 s of protein synthesis in the biological and biomedical research fields.

214 The rat is an important model organism in biomedical research for studying human disease mechanism

215 This article highlights biomedical research goals for the development of critica

216 This article highlights biomedical research goals providing critical tools neces

217 ty of CRISPR-Cas endonucleases as a tool for biomedical research has led to diverse applications in g

218 storically, murine models of inflammation in biomedical research have been shown to minimally correla

219 Recent advances in biomedical research have made massive amount of transcri

220 Improving the reproducibility of biomedical research is a major challenge.

221 Biomedical research is becoming increasingly data driven

222 to the proper training of undergraduates in biomedical research laboratories.

223 However, biomedical research often involves analysis of time-to-e

224 hese may be used as a xeno-free platform for biomedical research or cell therapy.

225 Biomedical research studies have generated large multi-o

226 itis elegans is a valuable model organism in biomedical research that has led to major discoveries in

227 It is increasingly common in biomedical research to have case-control (binary) respon

228 h-dimensional data are routinely employed in biomedical research to visualize, interpret and communic

229 am with the major goal of culture change for biomedical research training and training that prepares

230 has greatly advanced optical microscopy for biomedical research with superior sensitivity, resolutio

231 exploration of human disease pathogenesis in biomedical research, as well as for the development of t

232 ed variability hypothesis'); historically in biomedical research, females have been excluded for this

233 In biomedical research, participants are key among those st

234 e reform while recognizing the importance of biomedical research, providers, and healthcare delivery

235 gration of genomics into almost all areas of biomedical research, the adoption of genomics into mains

236 rical overrepresentation of male subjects in biomedical research, the US National Institutes of Healt

237 the increasing necessity of animal models in biomedical research, there is a vital need to harmonise

238 use are critical for clinical management and biomedical research, which require advanced tools with a

239 s system (CNS) has moved to the forefront of biomedical research, with the discovery that these two p

240 table step in experimental design of current biomedical research.

241 mammalian cells represent important goals of biomedical research.

242 ed to the routine application of PRSs across biomedical research.

243 increase the utility of poly(orthoesters) in biomedical research.

244 ential for many fields of optoelectronic and biomedical research.

245 lights the vital role IMS can play in modern biomedical research.

246 of omics data and lead to a new paradigm for biomedical research.

247 lopment and progression is a central goal of biomedical research.

248 of all the laboratory animal species used in biomedical research.

249 ts of aging is increasingly important within biomedical research.

250 o has been one of the major animal models in biomedical research.

251 the major vertebrate model organisms used in biomedical research.

252 ost widely studied nonhuman primate (NHP) in biomedical research.

253 ve frequently pushed the frontiers of modern biomedical research.

254 important roles in clinical diagnostics and biomedical research.

255 eployment within the Novartis Institutes for BioMedical Research.

256 idual cells and have an increasing impact on biomedical research.

257 res that have become increasingly popular in biomedical research.

258 r drug candidates is an ongoing challenge in biomedical research.

259 prioritizing and accelerating investments in biomedical research; and growing a diverse, culturally c

260 a sets provide a compendium of resources for biomedical researchers and achieve, to our knowledge, th

261 examples of how IMEx data are being used by biomedical researchers and integrated in other bioinform

262 our model and web server will be useful for biomedical researchers who are interested in finding sal

263 We recommend that biomedical researchers, especially those in the field of

264 r analyses and use of the CMT model by other biomedical researchers, we provide FREYA, a robust data

265 Primary outcomes were changes in biomedical (Rotterdam Renal Replacement Knowledge Test l

266 emphasis on the insight into their roles in biomedical science and provide perspectives on the chall

267 inhalation is of interest to a wide range of biomedical sciences due to the noninvasive therapeutic r

268 of a survey of 1284 postdocs working in the biomedical sciences in the US.

269 who are underrepresented in medicine and the biomedical sciences include individuals from certain rac

270 emerged in recent years as a cornerstone in biomedical sciences.

271 roughput sequencing has become ubiquitous in biomedical sciences.

272 ques are used by researchers in the life and biomedical sciences.

273 e propose actions that can be adopted by the biomedical scientific community to address long-standing

274 d cardiology, as well as other organ-related biomedical sensing abilities including ambulation.

275 ented them from taking a constant and active biomedical sensing role in our daily lives.

276 ennium, focusing on both in-body and on-body biomedical sensing solutions.

277 er the remarkable developments in TENG-based biomedical sensing which have arisen in the last octenni

278 Biomedical sensors have been essential in improving heal

279 plore TENGs as power sources for third party biomedical sensors in a number of fields, and conclude o

280 We begin by covering TENG as biomedical sensors in the most relevant, mortality-assoc

281 s of attention to fully translate TENG-based biomedical sensors into clinically and commercially viab

282 n delivering self-powered and wear-optimized biomedical sensors, and are paving the way for a novel p

283 focusing on the future perspectives of TENG biomedical sensors, highlighting key areas of attention

284 such as advanced optoelectronic devices and biomedical sensors.

285 ss, analyze, and disseminate NCBI and custom biomedical sequence data.

286 rge-scale profiling of Ig glycosylation in a biomedical setting is challenged by the existence of dif

287 ures is high, which is a common situation in biomedical settings.

288 Despite its biomedical significance, studies on AspH have long been

289 the dataset and limiting its applications in biomedical studies.

290 sts, spending on health care services versus biomedical technologies, phasing out low-value care, usi

291 an facilitate the research on document-level biomedical text mining.

292 ystem for extracting semantic relations from biomedical text.

293 raction algorithms to harvest information in biomedical texts.

294 are highly desirable for minimally invasive biomedical therapeutics.

295 within Hispanics/Latinos that may influence biomedical traits, demonstrating a need to improve our u

296 dentify DNA sequence variants that influence biomedical traits, particularly those related to the ons

297 me and discuss their potential for advancing biomedical translation through the interpretation of gen

298 However, SERS can be unreliable for biomedical use since it sacrifices reproducibility, unif

299 zed light can guide cellular development for biomedical use.

300 resulted in their underrepresentation in the biomedical workforce, especially in academia.