ライフサイエンスコーパス: future

1 l be an important research topic in the near future.

2 emissions of V to the atmosphere in the near future.

3 o be exploited as a magnificent field in the future.

4 easures currently in use or proposed for the future.

5 ing objects likely to provide benefit in the future.

6 vaccine formulations should be tested in the future.

7 photovoltaics (OPVs) can be foreseen in near future.

8 erties of variants expected to appear in the future.

9 lored areas that should be considered in the future.

10 s for clinical management of the ACS for the future.

11 sonal redistribution of precipitation in the future.

12 r photosynthesis engineering projects in the future.

13 dustry to improve animal productivity in the future.

14 ecognition by health authorities in the near future.

15 ts at directions the field might take in the future.

16 transitions to sponge dominated reefs in the future.

17 manage antibiotic-resistant bacteria in the future.

18 ment in the development of nations and their futures.

19 dience and what changes await us in the near future?

20 ence (aged 18-19 years: The Tromso Study Fit Futures 2).

21 y European legislation and holds promise for future adaptation to include other mycotoxins for multip

22 them from making informed plans about their future and accessing services.

23 f, the perspective of others, when imagining future and past events, and during mind wandering.

24 on biology and will be an important asset in future anti-inflammatory drug design.

25 alent degraders are anticipated to have wide future applicability.

26 A related future application for GeneImp is whole-genome imputatio

27 The potential future application of the method could be monitoring for

28 outlook is finally given regarding important future applications and technological developments of 2D

29 Future applications could range from biophotonics to mat

30 These results support potential future applications of microstimulation to correct malad

31 his material that are important for possible future applications.

32 he field currently faces and look forward to future applications.

33 Future approaches in treating infections caused by MDR b

34 Major tasks for the future are to apply these approaches to a wider range of

35 ruption is unclear, and this is an important future area of future investigation, as it has implicati

36 le population is projected to recover in the future as long as prey availability and mortality rates

37 ces and enables bacteria to use it to direct future behaviors.

38 derpins our abilities to make predictions on future biodiversity under any range of scenarios.

39 forecast reef-building coral health into the future, but often fail to account for the complex ecolog

40 Future cannabis-related policy decisions should include

41 by the Earth System Models used to forecast future carbon fluxes in recent climate assessments.

42 en by monocyte-derived macrophages, predicts future cardiovascular events in the general population.

43 h chromosomal origin regions localize to the future cell division sites, before FtsZ.

44 erequisite to meaningful predictions of near-future CH4 release in the Arctic.

45 erizing plant responses to past, present and future changes in atmospheric carbon dioxide concentrati

46 cting plant and ecosystem-scale responses to future changes in atmospheric CO2 concentrations, and th

47 eralized additive model (GAM) to examine how future changes in temperature and salinity could affect

48 th may be important for reducing the risk of future CHF events, particularly among HIV and hepatitis

49 se the uncertainty into that associated with future climate change and that associated with forest re

50 gestions that species may be able to survive future climate change in pockets of suitable microclimat

51 many Central European mountain forests under future climate change.

52 missions scenarios, this study shows that in future climate conditions, TC passage frequency will dec

53 regression model to provide finer resolution future climate projections as inputs to the deterministi

54 ed estimates of shrub biomass change under a future climate regime, made possible by recently develop

55 eamflow, and water stress) to projections of future climate.

56 portant for predicting GPP under current and future climate; we highlight the need for experimental s

57 Genetic maladaptation to future climates is likely to become a problem for spruce

58 apolations to novel community assemblages in future climates, which will require a mechanistic unders

59 therapeutic approach with p38 inhibitors for future clinical application.

60 a metastasis and might be a useful tool for future clinical applications, for example, response asse

61 ing an opportunity to improve selectivity of future clinical drug candidates.

62 indings should have significant influence on future clinical testing.

63 otentials and minimize their toxicity in the future clinical translation.

64 nism in the pig provide a rational basis for future clinical trials assessing the benefits of this ap

65 important implications for stratification of future clinical trials.

66 sorders to highlight areas of importance for future clinical trials.

67 However, recycling strategies for future CM quantities in end-of-life vehicles (ELVs) are

68 rease (i.e., positive coupling) in 10-22% of future coffee-suitable areas.

69 Future cohort studies should aim to confirm this possibl

70 th higher capacity would be promising in the future communication systems, especially in the bandwidt

71 e to the insulating state.The development of future computation devices will be aided by a better und

72 increase the capability of models to predict future conditions in P-limited tropical forests, especia

73 in 2014-2016, and could be an indication of future conditions under projected climate change.

74 read increase in subglacial volcanism in the future could have a considerable effect on the stability

75 hesis rates is one of the keys to increasing future crop production; however, this typically requires

76 ty that may be useful for the development of future delivery agents with improved properties.

77 uding current adoption barriers and expanded future demands based on demographic and market forces.

78 ectives on the challenges and directions for future development in this exciting field are provided.

79 sments of the risks of feeding modes for the future development of allergies.

80 Lastly, outlook and the future development of biosensors for the control of anti

81 ineering and can provide a blueprint for the future development of personalized, autologous anticance

82 To facilitate future development of pharmaceuticals against antithromb

83 ual-electrodes may prove significant for the future development of reconfigurable electronic systems.

84 dy could also serve as a useful resource for future development of software for RNA-Seq analysis.

85 Within the conclusion, perspectives on future developments in the context of synthetic control,

86 Future developments may further include compounds that l

87 Finally, we offer a perspective on the future developments of nanohybrid materials and future n

88 miconductor nanostructures holds promise for future device concepts in optoelectronic and spin-based

89 may help to identify the optimal timing for future DHA clinical trials.

90 umour classification highly relevant for the future diagnosis and treatment of meningioma.

91 6 promises to open new avenues for improving future diagnosis, stratification, and treatment response

92 Purpose To explore future diagnosis-specific sickness absence and disabilit

93 ided by the epigenome for the development of future diagnostics, preventive strategies, and therapy f

94 iscuss limitations of the method, along with future directions for further improvements.

95 udies, and insights about the challenges and future directions for the field.

96 hes to limit immunotoxicity, and discuss the future directions of research and reporting that are nee

97 discuss these topics and relate them to the future directions of the field.

98 highlight recent applications to illustrate future directions of tip-enhanced near-field Raman micro

99 We then elaborate the two main future directions that are centralized around the develo

100 We also suggest future directions to inform investigators of potentially

101 sed on current research progress, we propose future directions yet to be explored for enhanced proper

102 progress, recent developments, and promising future directions.

103 natural infections, and may help predict its future directions.

104 aviors, alongside vaccine status, to predict future disease burden.

105 ge in major land use classes impact modelled future distribution patterns.

106 to require the Z-ring for recruitment to the future division site.

107 Clues as to the future do help give us a possible scenario worthy of suc

108 receptor types, may be a viable strategy for future drug development.SIGNIFICANCE STATEMENT Memantine

109 53 are identified via solvent mapping to aid future drug discovery studies.

110 This work will enable future efforts in developing highly efficient biomimetic

111 Future efforts should focus on how to exploit this knowl

112 exploited to markedly improve management of future energy systems.

113 ses of this major feature of biodiversity to future environmental change.

114 ways, and deserves further consideration in future evolutionary studies.

115 natomic sanctuaries for the virus can inform future experiments aimed at further clarifying this issu

116 sumptions, one can incorporate both past and future exposures as multiple negative control exposures

117 tory parameters such as growth, survival and future fecundity.

118 field, highlighting the research needed for future focus.

119 ptibility loci for pediatric VTE and warrant future functional studies to unravel the underlying mole

120 f cardiac structure and warrant follow-up in future functional studies.

121 successive generations should be weighed in future gastric cancer control programs.

122 Hence, future generations of catalysts must perform at temperat

123 We anticipate that future generations of programmable molecular machines ma

124 Our data provide a framework for how future genome sequencing efforts should incorporate tran

125 ng and suggest that the EAIS contribution to future global sea-level projections may be under-estimat

126 develop a recombinant inbred population with future goals of identifying genomic regions associated w

127 ake decisions for action that are related to future goals, or at least free from the constraints of i

128 sion point in the life of plants determining future growth and development.

129 Future growth is dependent on the successful over-winter

130 h potential of nanoplasmonic sensors and the future growth prospects of the community as a whole.

131 we claim that our approach can be used as a future guide to investigate the role of glutamate, ion c

132 Using climate projections, we show that future heat stress could reduce the forest edge growth e

133 indicate this gene as a promising target for future hemipterans pest control.

134 whether HIV infection increases the risk of future HFrEF and HFpEF and to assess if this risk varies

135 early detection, management, and control in future HPAI virus outbreaks.

136 dPCR may be the optimal molecular method for future HRV quantification studies and for quantitating o

137 have the potential to become PET tracers for future human use.

138 These studies lay a foundation for future identification of causative variants and genes fo

139 Finally, we discuss the current and future impact of AMDs on systemic lupus erythematosus, r

140 t robust initial results and suggestions for future implementations.

141 are much lower, therefore possibilities for future improvement of the detection limit are discussed.

142 uroprotective potential of HSJ1, and deserve future interest as therapeutic strategies for neurodegen

143 Our findings offer valuable lessons for future Internet-based biosurveillance tools.

144 urements of peripouch fat, which will foster future investigation of the role of mesentery fat in col

145 ear, and this is an important future area of future investigation, as it has implications beyond anti

146 cal environments whose functional role needs future investigation.

147 d host phenotypes, a hypothesis that demands future investigation.

148 s are abridged to reinvigorate and stimulate future investigations.

149 These data provide an important resource for future LD studies and demonstrate the utility of proximi

150 macological activities, may be the basis for future liposomal drug development.

151 are promising multi-functional additives for future lithium-sulfur (Li-S) batteries.

152 metabolic abnormalities as the predictor of future liver fat and fibrosis.

153 Future longitudinal studies of peripheral changes in AMD

154 Future longitudinal studies with multiple postoperative

155 dependently associated with a higher risk of future lung cancer.Significance: This large cohort study

156 ther assist in the design and development of future malarial vaccines.

157 tudy of SANS is ongoing for consideration of future manned missions to space, including a return trip

158 tial reductions in PLD due to ocean warming, future marine reserve networks would require more and/or

159 t a broad-reaching and important advance for future mental health care.

160 ration of internal biophysical mechanisms in future model developments.

161 Future molecular MRI targeting P-selectin may be used to

162 ported in the same material, pave the way to future multiferroic and magnetoelectric investigations i

163 ure developments of nanohybrid materials and future nanosensors, outline possible directions to be pu

164 nergy metabolites and other constituents for future needs.

165 ion and training is needed to better prepare future nephrologists for the growing challenges of kidne

166 ys, and benign breast disease (BBD) predicts future non-TNBC.

167 virus vaccine in 3 countries that would make future NVIs more successful.

168 Future ocean and sea-ice changes affecting the distribut

169 rs of marine ecosystem change develop in the future ocean.

170 the impact that 3D-printing will have on the future of analytical device fabrication, miniaturization

171 However, issues central to the future of health and health care in the United States tr

172 ular chemistry will play a vital role in the future of the drug delivery field.

173 extrinsic mortality risk - documenting more future-oriented thinking among low- compared to high-SES

174 mportant implications for the development of future PALM tags.

175 licits contextual fear learning and enhances future passive avoidance learning, which may model certa

176 model runs for the historical period and the future period corresponding to the Representative Concen

177 rved effect of baseline central adiposity on future periodontitis progression is conditional on proin

178 Future peripheral artery disease cell therapy investigat

179 The most dramatic direct effects of future pH may be expected on epibenthic invertebrates (c

180 been associated with enhanced creativity and future planning.

181 alance exercises, and assist in prioritizing future plastic debris monitoring and mitigation strategi

182 Future population growth and economic development are fo

183 is effect is indicative of a reduced risk of future progression to end-stage renal disease.

184 What makes future projections different from these past warm climat

185 differences in natural history of TB and in future projections of TB.

186 ting of historical hindcasts (1850-2005) and future projections to 2100 following representative conc

187 al interface disorders, as well as potential future prophylactic and treatment strategies.

188 elminth-derived products is also an exciting future prospect.

189 Future prospective testing, including additional dimensi

190 into translational applications, we discuss future prospects for integrating personalized immunoengi

191 , its physiological role on human health and future prospects.

192 ress this conundrum and provide insights for future public health efforts, we analyze the geospatial

193 ld make the humanitarian system relevant for future public health responses: (1) operationalise the c

194 miconductor charge island is promising for a future quantum current standard.

195 A second model simulated current and future ragweed pollen levels.

196 CO2 losses from tropical forest soils under future rainfall changes.

197 Accumulating evidence indicates that future rates of atmospheric N deposition have the potent

198 e become central for improved predictions of future reef form and function.

199 Future regulatory design will minimize compliance costs

200 rker of chronicity, are all risk factors for future relapse after interactions with CRTs.

201 is needed to create accurate projections of future relative sea level rise upon which to base planni

202 Our emphasis is on future research directions linking spectral fluorescence

203 ns, switches, and replacements, and identify future research directions that can contribute to a more

204 These data will help to prioritize future research directions.

205 iome, metabolomics, and transcriptomics into future research efforts; and build molecular annotations

206 shared themes that may be key for advancing future research in both fields.

207 we propose that it is a sensible target for future research into rehabilitative treatments.

208 nt and management than at present and enable future research into the effect of carcinoid syndrome co

209 ly against K. pneumoniae in serum, informing future research into the medicinal behaviours and dosing

210 e of biting midges as vectors, a key area of future research is to establish the impact of this endos

211 We propose that future research on alpha neurofeedback should explore re

212 Future research should aim to establish clinical, serolo

213 Future research should examine the generalizability of t

214 Future research should focus more specifically on BCC in

215 Future research should focus on developing a working def

216 Future research should focus on optimal probiotic dose,

217 Future research should validate this checklist in other

218 l and the possible unexplored directions for future research studies is also addressed.

219 n recent findings and propose directions for future research that involve microbe-induced changes to

220 ions in physical scores should be a focus in future research to optimize treatment strategies to redu

221 of fNIRS during natural speech production in future research with typical and atypical child populati

222 Amongst many fascinating problems for future research, the data revealed a YtfE orthologue, Dd

223 vilian settings, and presents directions for future research.

224 g knowledge gaps, and suggest priorities for future research.

225 ledge and proposed and prioritized areas for future research.

226 We generate several hypotheses for future research.

227 ve antibiotic choices, and suggest areas for future research.

228 ntribute to improved patient care and inform future research.

229 Predicting future reward is paramount to performing an optimal acti

230 nical settings, can be useful for predicting future risk of suicidal behavior.

231 nstruct the predictive models, capturing the future risks of GDM in the temporally aggregated EHRs.

232 d neoplasms, with a focus on the current and future role of HTS-based assays.

233 Future school-based environmental interventions may be b

234 posterior cortex can dissociate current from future search goals in working memory.

235 Information about relatively low future sickness absence and disability pension levels ca

236 ion among complex traits and will facilitate future soybean functional studies and breeding through m

237 time could inform policy efforts to contain future spending growth.

238 ective endocarditis and outlines current and future strategies to limit its impact.

239 Future strides, extending those made in recent decades,

240 insulin resistance, those at higher risk for future stroke or myocardial infarction (MI) derive more

241 Future studies are needed to address whether similar mec

242 stasis, these results lay the groundwork for future studies assessing the therapeutic potential of ta

243 Future studies can explore the identity of these genetic

244 to be the recommended single-agent dose for future studies in FL and DLBCL, with 800 mg being suffic

245 rapeutic agent and provides a foundation for future studies in this difficult-to-treat patient popula

246 Future studies might elucidate how brain diseases change

247 hese data provide an invaluable resource for future studies of function and biological significance o

248 expression of MNs, which is likely to enrich future studies of MN disease.

249 hese results raise several opportunities for future studies of the pathogenesis of thyroid cancer.

250 HPT-JT syndrome, provide in vivo models for future studies of these tumours.

251 UHI intensity, which should be considered in future studies on air pollution and urban climates.

252 Future studies should attempt to replicate these results

253 Future studies should examine the minimum treatment inte

254 Future studies should explore risk factors for increased

255 Future studies should focus on better defining the role

256 Future studies should focus on understanding the determi

257 Future studies should measure multiple biomarkers in eac

258 knowledge, and make suggestions on necessary future studies to optimize organ transplantation for old

259 Our results provide a framework for future studies to understand better the regulation of ch

260 Future studies will explore methods to reduce kidney act

261 into a provisional framework that can guide future studies.

262 will allow the comparison of outcome data in future studies.

263 potentially pathogenic alleles identified in future studies.

264 atients awaiting LT which may be assessed in future studies.

265 advance on average) prediction of patients' future suicidal behavior.

266 supply and need tool developed to anticipate future supply and need for all physician specialties.

267 gorization of ACS to provide a framework for future tailoring, triage, and therapy for patients in a

268 e appears to be both an anticipatory effect (future targeted procedures reducing readmission before p

269 encouraging implications for the success of future targeted therapies in advanced-stage disease.

270 Our study shows that the future temporal and spatial variation characteristics of

271 c proctectomy is to be widely applied in the future, the costs of the procedure must be reduced.

272 of anti-inflammatory proteins for potential future therapeutic applications.

273 concludes by identifying key strategies for future therapeutic intervention.

274 obal methylation patterns that may allow for future therapeutic opportunities.

275 ogenetic basis of L-ORD has implications for future therapeutic strategies such as gene augmentation

276 supporting hBM34+ cell transplantation as a future therapeutic strategy for ALS patients.

277 CRISPR/Cas components would greatly improve future therapeutic utility.

278 New strategies are needed to design future therapies that target resistant cells.

279 ow clinicians may be able to use them in the future to predict the course of disease and, perhaps, th

280 nships in the surgical context to inform the future training of surgical coaches.

281 local topological connections available for future travel and right anterior hippocampal activity re

282 y and provide insight into the mechanism and future treatment of epileptogenesis in EIEE13.

283 evidence that LDR is a promising option for future treatment strategies to prevent cancer metastasis

284 Credible future tree ring isotope studies require explicit accoun

285 These findings encourage future trials of MMN as a biomarker for individual assig

286 transfusion, may be appropriate subjects of future trials to improve outcomes of children requiring

287 e urban population and are where much of the future urban growth is expected to occur.

288 ations of current organoid systems for their future use in ZIKV research.

289 Stem cell harvest for future use may be considered in first remission for pati

290 ted evidence from literature points toward a future UWM that offers significant potential benefits th

291 ife history strategy, a greater focus on the future (vs. present), and a stronger focus on self-contr

292 pect of our study exemplifies the promise of future widespread resequencing of tumor genomes in provi

293 options to overcome resistance, but, in the future, will also be the basis for implementing precisio

294 he electrochemical performance and can guide future work on designing high-performance MXene-based ma

295 logy and the concentration of atmospheric O2 Future work on glaciation-weathering-carbon cycle feedba

296 Future work should focus on facilitating induction to XR

297 escue from gene augmentation therapy support future work to move CNGB1-RP therapies toward clinical t

298 ork will provide a standardized baseline for future work to optimize recommended diets further.

299 This method enables future work to utilize the isotopic composition of HONO

300 Future work will reassess these estimates in light of mo