ライフサイエンスコーパス: environmental monitoring

1 Python package PyLEnM (Python for Long-term Environmental Monitoring).

2 on-invasive clinical diagnostics and in-situ environmental monitoring.

3 areas of society, ranging from healthcare to environmental monitoring.

4 f applications ranging from life sciences to environmental monitoring.

5 ic, creating a need for robust and sensitive environmental monitoring.

6 urther development of analytical methods for environmental monitoring.

7 for simple, low-cost and reagentless on-site environmental monitoring.

8 can be incorporated into devices for remote environmental monitoring.

9 medical diagnosis, biological research, and environmental monitoring.

10 ction and speciation analysis is crucial for environmental monitoring.

11 ny fields, ranging from disease detection to environmental monitoring.

12 efore offering an interesting perspective in environmental monitoring.

13 sed in clinical diagnostics and for food and environmental monitoring.

14 specific binding for further application to environmental monitoring.

15 ial to revolutionize medical diagnostics and environmental monitoring.

16 y indices have been proposed for purposes of environmental monitoring.

17 probes for intracellular, toxicological, and environmental monitoring.

18 cal diagnostics, food safety, forensics, and environmental monitoring.

19 netic risk factors, medical diagnostics, and environmental monitoring.

20 ons in cellular imaging, systems biology and environmental monitoring.

21 nsor technology to improve public health and environmental monitoring.

22 that are relevant to medical diagnostics and environmental monitoring.

23 se in public safety, industrial hygiene, and environmental monitoring.

24 d as default mode regions, which may reflect environmental monitoring.

25 iar and noisy fMRI environment, may increase environmental monitoring.

26 plication in such areas as food industry and environmental monitoring.

27 erged as a key component of biodiversity and environmental monitoring.

28 amental biomedical research, food safety and environmental monitoring.

29 inical testing, pharmaceutical analysis, and environmental monitoring.

30 indicated that the method has potential for environmental monitoring.

31 the method can be expected to be useful for environmental monitoring.

32 ated wastewaters but may not be suitable for environmental monitoring.

33 tection in, for example, food inspection and environmental monitoring.

34 ins, including human health, agriculture and environmental monitoring.

35 bioanalytical assessments, food safety, and environmental monitoring.

36 tial applications in resource management and environmental monitoring.

37 ter samples is crucial for public health and environmental monitoring.

38 fields such as proteomics, metabolomics, and environmental monitoring.

39 s, including disease biomarker detection and environmental monitoring.

40 ts in water discharge is an integral part of environmental monitoring.

41 alth/disease monitoring, drug discovery, and environmental monitoring.

42 e of global challenges across healthcare and environmental monitoring.

43 -making and interventions in agriculture and environmental monitoring.

44 ational security, military applications, and environmental monitoring.

45 the concept into a practical technology for environmental monitoring.

46 demonstrated high recovery rates in food and environmental monitoring.

47 to include fluid dynamics, electronics, and environmental monitoring.

48 the potential of THz technology for detailed environmental monitoring.

49 ide-scale application of DNAzyme sensors for environmental monitoring.

50 of integration with downstream analysis for environmental monitoring.

51 erexplored despite their proven potential in environmental monitoring.

52 ctions, and to inform the next generation of environmental monitoring.

53 ons, from industrial processes to health and environmental monitoring.

54 ise as a comprehensive, nontargeted tool for environmental monitoring.

55 including biosensing, disease diagnosis, and environmental monitoring.

56 ariety of applications from life sciences to environmental monitoring.

57 esearch, clinical diagnosis, food safety and environmental monitoring.

58 specific bioindicators for wastewater-based environmental monitoring.

59 ny applications in drug screening and remote environmental monitoring.

60 h attention and increased public concerns on environmental monitoring.

61 ive detection of melamine in food safety and environmental monitoring.

62 with applications from gas leak detection to environmental monitoring.

63 rly in the context of sustainable energy and environmental monitoring.

64 dly sensing tool for food safety control and environmental monitoring.

65 es, offering a reliable approach for routine environmental monitoring.

66 gh-throughput, nontargeted, and quantitative environmental monitoring.

67 rial toxins remains a pressing challenge for environmental monitoring.

68 l as a reliable platform for food safety and environmental monitoring.

69 ational security, military applications, and environmental monitoring.

70 s in healthcare, biomedical, food safety and environmental monitoring.

71 ion in chemical and biomolecule analysis and environmental monitoring.

72 romising for applications in food safety and environmental monitoring.

73 s (MIPs) has become an interesting field for environmental monitoring.

74 ead applications in industry, healthcare and environmental monitoring.

75 ng potential for early disease diagnosis and environmental monitoring.

76 ns in rapid diagnosis, mobile-healthcare and environmental monitoring.

77 the investigation of infectious diseases and environmental monitoring.

78 gies for clinical analysis, food safety, and environmental monitoring.

79 promising potential in bio-diagnosis and the environmental monitoring.

80 s of analytical technique useful for routine environmental monitoring.

81 diagnostics, food safety, public health, and environmental monitoring.

82 for point-of-care diagnosis, food safety and environmental monitoring.

83 hput and rapid food detection, biosafety and environmental monitoring.

84 derable potential for ecological studies and environmental monitoring.

85 TNT) is in high demand for public safety and environmental monitoring.

86 ields, including human diagnostics, food and environmental monitoring.

87 for applications in medical diagnostics and environmental monitoring.

88 ing and will be applied, for example, in (1) environmental monitoring, (2) a more in-depth study of e

89 ,2) may form the basis of future systems for environmental monitoring(3), population surveillance(4),

90 to electrical signals, making them ideal for environmental monitoring(5,6), healthcare diagnostics(7)

91 dvances in DNA sequencing, physiological and environmental monitoring, advanced imaging, and behavior

92 Furthermore, nearly 20 years of environmental monitoring allowed us to control for poten

93 ryptosporidium outbreak, we demonstrate that environmental monitoring allows for inference regarding

94 stance, potentially enabling applications in environmental monitoring and agronomic research.

95 lasma samples archived by the Biological and Environmental Monitoring and Archival of Sea Turtle Tiss

96 impacts on the environment, and the costs of environmental monitoring and assessment have reduced dra

97 l samples and provide more accurate data for environmental monitoring and assessment of action plan t

98 ous applications ranging from food industry, environmental monitoring and biomedical fields as well a

99 , drug discovery, commonly use food control, environmental monitoring and biomedical research.

100 m detection capabilities within food safety, environmental monitoring and clinical diagnosis.

101 to a number of analytical fields, including environmental monitoring and clinical diagnostics.

102 Environmental monitoring and clinical surveillance for L

103 d-batch and manual processes that often lack environmental monitoring and control or on bioreactors t

104 important in many areas, including medicine, environmental monitoring and defence.

105 ing it a powerful tool especially suited for environmental monitoring and detection of microbial haza

106 ications in human health, homeland security, environmental monitoring and diagnostics.

107 chips with high sensitivity is essential for environmental monitoring and disease diagnosis.

108 This method is appropriate for routine environmental monitoring and drinking water quality asse

109 ingly used in other fields such as medicine, environmental monitoring and food quality analysis.

110 Biosensors to meet the needs in health and environmental monitoring and food safety have become com

111 ld become a robust contender in the areas of environmental monitoring and food safety testing.

112 ve found versatile applications varying from environmental monitoring and food safety to clinical dia

113 xcellent recovery, proving its potential for environmental monitoring and food safety.

114 analysis, offering practical applications in environmental monitoring and food safety.

115 ) detection, with potential implications for environmental monitoring and food safety.

116 research tool with promising applications in environmental monitoring and for uncovering conserved ce

117 s the potential to become a valuable tool in environmental monitoring and forensics.

118 on can be used for applications ranging from environmental monitoring and homeland defense to food pr

119 ields such as early-stage disease diagnosis, environmental monitoring and homeland security.

120 ption factors (aTFs) are promising tools for environmental monitoring and human health.

121 tial to be made portable for applications in environmental monitoring and in-field applications.

122 particles (NPs) in solution is essential for environmental monitoring and indirect detection of chemi

123 as analysis in various applications, such as environmental monitoring and medical breath diagnosis.

124 ications, from industrial process control to environmental monitoring and medical devices.

125 sample preparation method is a challenge for environmental monitoring and mitigation.

126 home security systems, particle sensors for environmental monitoring and motion sensors in mobile ph

127 as stream with applications in, for example, environmental monitoring and online industrial process m

128 d a substantial impact on molecular biology, environmental monitoring and other areas of research.

129 ect antigens in real-time and provide remote environmental monitoring and point-of-care diagnosis tha

130 e has extensive application in the fields of environmental monitoring and pollutant degradation.

131 he potential for applications such as remote environmental monitoring and portable health care device

132 l have a significant impact on the fields of environmental monitoring and protection.

133 vironmental quality is crucial for real-time environmental monitoring and protection.

134 istance with promising applications for both environmental monitoring and rapid clinical detection.

135 monstrated, and the implications for on-site environmental monitoring and rapid security screening/wa

136 iment in recent decades, and deserve further environmental monitoring and research.

137 om national security and demilitarization to environmental monitoring and restoration.

138 xicity and will help with the development of environmental monitoring and risk assessment of FPW spil

139 As such, speciation analysis is critical for environmental monitoring and risk assessment.

140 xposure to 6PPD-Q, thereby being valuable to environmental monitoring and risk assessment.

141 d sites, with corresponding implications for environmental monitoring and risk assessment.

142 strate how these results can uniquely inform environmental monitoring and risk assessments of surface

143 ing and quantification play pivotal roles in environmental monitoring and surveillance.

144 ions, ranging from food and drug analysis to environmental monitoring and to chemical and biological

145 ed healthcare in the developing world and in environmental monitoring and water analysis.

146 This result is of particular importance for environmental monitoring and water quality analysis prov

147 current prospective disease surveillance and environmental monitoring) and analysis (preserving tempo

148 ve of ARG amplicon lengths commonly used for environmental monitoring) and long amplicons (800-1200 b

149 food and water safety, medical diagnostics, environmental monitoring, and bio-threat applications ar

150 applications including food quality control, environmental monitoring, and breath analysis for diseas

151 n toxic gas detection, food quality control, environmental monitoring, and breath analysis for diseas

152 find wide application in forensic analysis, environmental monitoring, and clinic diagnostics.

153 ing medical diagnostics, biomedical imaging, environmental monitoring, and delivery of therapeutics t

154 applications, including medical diagnostics, environmental monitoring, and drug detection.

155 ng applications including disease diagnosis, environmental monitoring, and elucidating the molecular

156 including pre-emptive medicine, diagnostics, environmental monitoring, and food industry.

157 impact to the field of biomedical analysis, environmental monitoring, and food safety survey.

158 port applications in biomedical diagnostics, environmental monitoring, and food safety.

159 is important in the fields of human health, environmental monitoring, and food safety.

160 stems for applications in organic chemistry, environmental monitoring, and healthcare.

161 age disease diagnosis, food quality control, environmental monitoring, and homeland security protecti

162 ) are widely utilized in biomedical sensing, environmental monitoring, and imaging due to their tunab

163 mall molecules in the fields of food safety, environmental monitoring, and medical diagnostics.

164 elated to analytical chemistry, diagnostics, environmental monitoring, and national security and more

165 analytical chemistry, molecular diagnostics, environmental monitoring, and national security.

166 nities in gas sensing, threat detection, and environmental monitoring, and open the door for a new cl

167 ld with potential applications in biosafety, environmental monitoring, and personalized medicine.

168 elds like military surveillance, healthcare, environmental monitoring, and smart cities.

169 variety of applications from diagnostics to environmental monitoring, and studies will continue to m

170 gth thermal detectors for molecular sensing, environmental monitoring, and thermal imaging.

171 nstrate that decoherence can be mitigated by environmental monitoring, and validate the foundation of

172 g-distance propagation for communication and environmental monitoring, and would benefit elephants (E

173 uberculosis, etc.; significant problems with environmental monitoring; and of course serious challeng

174 iscuss their usage in various biomedical and environmental monitoring applications, from biosensors t

175 ng for direct quantification of phosphate in environmental monitoring applications.

176 the designed sensor array for diagnostic and environmental monitoring applications.

177 ture gas sensors is significant in low-power environmental monitoring applications.

178 agnostic tools for clinical, food safety and environmental monitoring applications.

179 Current environmental monitoring approaches focus primarily on c

180 Highly sensitive ammonia sensors for environmental monitoring are presented.

181 s in health, food safety, pharmaceutical, or environmental monitoring areas.

182 The sampler was developed for environmental monitoring as follows: (1) It is of very s

183 Health, infrastructure, and environmental monitoring as well as networking and defen

184 Biological environmental monitoring (BEM) is a growing field of res

185 t mixtures remains an essential component of environmental monitoring, bioactivity-based assessments

186 instance, they are essential in food safety, environmental monitoring, biomedical applications, and p

187 devices will find extensive applications in environmental monitoring, biomedical diagnostics, and fo

188 ould have broad applications in the areas of environmental monitoring, biomedical diagnostics, and ho

189 nes, including earth and planetary sciences, environmental monitoring, bioremediation, and the nuclea

190 In environmental monitoring campaigns for anthropogenic rad

191 ing high-resolution mass spectrometry within environmental monitoring campaigns.

192 the food, beverage and fragrance industries, environmental monitoring, chemical-purity and -mixture a

193 rm opening up the potential for food safety, environmental monitoring, clinical diagnostics and medic

194 applications such as food safety inspection, environmental monitoring, clinical diagnostics, and medi

195 curately and efficiently are required by the environmental monitoring community.

196 Environmental monitoring could provide vital information

197 offers a most valuable tool for distributed environmental monitoring data aggregation.

198 ditional studies with more recent and direct environmental monitoring data of multiple occupational e

199 sensitivity for a number of applications in environmental monitoring, defense, and homeland security

200 nexpensive, ink-jet printed, and large-scale environmental monitoring devices that can be deployed in

201 quired for the next generation of unattended environmental monitoring devices.

202 ghly critical to the advancement of accurate environmental monitoring, disease screening, and persona

203 of nutrient impact can be underestimated by environmental monitoring due to its diffuse and accumula

204 ic sensors have been vital in healthcare and environmental monitoring due to their high selectivity.

205 ortant for advancing medical diagnostics and environmental monitoring due to their high sensitivity a

206 ances (PFAS) remains a critical challenge in environmental monitoring due to their low light absorpti

207 Marine environmental monitoring efforts often rely on the bioac

208 r decentralized applications, such as remote environmental monitoring, electrochemical energy systems

209 ens in food processing facilities by routine environmental monitoring (EM) is essential to reduce the

210 rates or gas accumulation phases during long environmental monitoring experiments, gas leakage fluxes

211 otonics has enormous potential for real-time environmental monitoring, explosive detection, and biome

212 NT-based sensors to multiple areas including environmental monitoring, food and agriculture applicati

213 ethods of analysis to meet new challenges in environmental monitoring, food safety and public health.

214 emes and their applications in the fields of environmental monitoring, food safety, and clinical diag

215 sensing and have significant applications in environmental monitoring, food safety, biotechnology, ph

216 gnificant health risk, necessitating regular environmental monitoring for public safety.

217 es and applications in ecology, agriculture, environmental monitoring, forensics and defense.

218 ro diagnostics, food analysis, biosafety and environmental monitoring, forensics, and security, etc.

219 erse ares, such as nuclear nonproliferation, environmental monitoring, geophysics, and planetary scie

220 Expanding environmental monitoring globally presents challenges an

221 A potential application to environmental monitoring has been investigated.

222 In the history of manned spaceflight, environmental monitoring has relied heavily on archival

223 ad, cadmium, and zinc) in water for in-field environmental monitoring, (iii) sodium in urine for clin

224 The absence of well-executed environmental monitoring in the Athabasca oil sands (Alb

225 rous applications in biomedical sciences and environmental monitoring, including disease diagnostics,

226 replacing filtration in applications such as environmental monitoring, industrial cleaning processes,

227 ysis plays a vital role in applications like environmental monitoring, industrial hygiene, homeland s

228 NO detection, with potential applications in environmental monitoring, industrial safety, and medical

229 ection of nitric oxide (NO) is important for environmental monitoring, industrial safety, and medical

230 ar future, with applications in health care, environmental monitoring, infrastructure monitoring, nat

231 and recognition that involving the public in environmental monitoring is an effective way of increasi

232 cations and time periods are limited because environmental monitoring is largely reactive-i.e., pollu

233 The utility of this technique for environmental monitoring is limited, however, by the uti

234 one year, an enhanced, real-time method for environmental monitoring is necessary.

235 of nitroaromatics; a possible application in environmental monitoring is proposed.

236 one of the most challenging in the field of environmental monitoring, mainly due to disparate concen

237 eat promise for applications in food safety, environmental monitoring, medical diagnoses, and chemica

238 eland security, agriculture and food safety, environmental monitoring, medicine, pharmacology, indust

239 for highly sensitive, robust diagnostics and environmental monitoring methods has led to extensive re

240 pplied in many fields including biomedicine, environmental monitoring, national defense and analytica

241 al marker of exposure to carcinogens and for environmental monitoring of 1,2-dihaloethanes.

242 A convenient, visual detection system for environmental monitoring of amines and acyl-transfer rea

243 Environmental monitoring of Aspergillus spores in the ai

244 However, environmental monitoring of building plumbing systems of

245 cence and thus provide a rapid technique for environmental monitoring of DOC in lakes and rivers.

246 Our study focuses on environmental monitoring of European honey bees (Apis me

247 e isotope characterization would permit both environmental monitoring of extent of remediation and fo

248 ed two bacterial biosensors designed for the environmental monitoring of metals: Lumisens III and Lum

249 be widely used as the standard materials for environmental monitoring of NAs from various contaminati

250 esses in marine environments, and for marine environmental monitoring of off-shore industrial sites.

251 ntroduced and have successfully extended the environmental monitoring of organic micropollutants.

252 OC) diagnostics, in the medical industry and environmental monitoring of pathogenic threat agents.

253 (mu-TAS) and in DNA-array chips utilized for environmental monitoring of pathogens.

254 ations for a more comprehensive and reliable environmental monitoring of PFAS components at AFFF-impa

255 nded use of bioreporter-based microchips for environmental monitoring of space and planetary environm

256 Environmental monitoring of surfaces/equipment, using PC

257 nts in Thin films) as dynamic sensors in the environmental monitoring of trace metals is the influenc

258 ast and inexpensive analysis in the field of environmental monitoring, offering also the possibility

259 ing swift diagnosis of bacterial infections, environmental monitoring, or food-quality control.

260 isms as a dispersal strategy for purposes in environmental monitoring, population surveillance, patho

261 these advanced computational techniques into environmental monitoring practices offers a promising av

262 The Network employs a community-based environmental monitoring process in which the community

263 current good manufacturing practices (cGMP) environmental monitoring program at the NIH.

264 Routine environmental monitoring programs target predetermined c

265 s model species in toxicological studies and environmental monitoring programs: zebrafish (Danio reri

266 ded in several domains, like urban planning, environmental monitoring, public health, and humanitaria

267 in environmental and biological samples for environmental monitoring, radiological protection, and n

268 tial in addressing challenges in healthcare, environmental monitoring, remediation and agriculture, t

269 es but also expands the scope of the NTS for environmental monitoring, remediation, and risk assessme

270 ons in health diagnostics, food, safety, and environmental monitoring require rapid, simple, selectiv

271 r therapy products along with the associated environmental monitoring requirements for aseptic facili

272 ity have been released by us at the Carlsbad Environmental Monitoring & Research Center and confirmed

273 Targeted environmental monitoring reveals contamination by known

274 near-patient conditions, for food analysis, environmental monitoring, security, and safety applicati

275 loyed for a variety of applications, such as environmental monitoring, sensing in chemical processing

276 on plant health, biocatalysis, medicine and environmental monitoring serve as examples of the transf

277 lly be used in a point-of-care or continuous environmental monitoring setting.

278 The Rover Environmental Monitoring Station (REMS) instrument, whic

279 breaks directly affects the long-term marine environmental monitoring strategies.

280 Environmental monitoring studies provide key information

281 t precious metals are leading candidates for environmental monitoring technologies.

282 es of low-cost systems for health, food, and environmental monitoring that can democratize sensing ac

283 provides a rapid screening tool for on-site environmental monitoring that specifically monitors the

284 rnative and more comprehensive approaches to environmental monitoring that will improve our capacity

285 point-of-care diagnosis as well as food and environmental monitoring there is a high demand for reli

286 When applied to environmental monitoring, these "lab-on-chip" systems co

287 Hence the environmental monitoring through rapid and specific dete

288 Soil information is needed for environmental monitoring to address current concerns ove

289 utilized in a variety of fields ranging from environmental monitoring to clinical diagnostics.

290 equired by many applications, extending from environmental monitoring to drug discovery and industria

291 ls is critical for applications ranging from environmental monitoring to industrial fault detection.

292 multiple sources of uncertainty and leverage environmental monitoring to make inference about infecti

293 analysis accesses diverse applications from environmental monitoring to medical diagnostics.

294 These locations can then be used to inform environmental monitoring to proactively address environm

295 promised a non-invasive and non-destructive environmental monitoring tool.

296 Environmental monitoring using remote-sensed data can co

297 airing observations of mosquito ecology with environmental monitoring, we quantified longitudinal shi

298 SANs also show promise in environmental monitoring, where they have been utilized

299 ple, rapid, and cost-effective bioassays and environmental monitoring, which provide practically rele

300 design of EM programs, we developed EnABLe ("Environmental monitoring with an Agent-Based Model of Li