ライフサイエンスコーパス: microbiology

1 tions are honored in this issue of Molecular Microbiology.

2 yphimurium has just been published in Nature Microbiology.

3 biological bile cultures revealed a positive microbiology.

4 one of paramount importance in the field of microbiology.

5 d protein therapies of relevance to clinical microbiology.

6 nd qualitative composition of the associated microbiology.

7 ectrophysiological studies into the field of microbiology.

8 e commonly used for kinetic analysis in food microbiology.

9 ad use of droplet technologies in analytical microbiology.

10 functional evolution and other subfields of microbiology.

11 n metagenomics methods that have transformed microbiology.

12 s opened many new avenues of research within microbiology.

13 bation represents an essential challenge for microbiology.

14 ea that escape routine detection in clinical microbiology.

15 ting and to evaluate its effects on clinical microbiology.

16 technologies are transforming public health microbiology.

17 vances have changed the practice of clinical microbiology.

18 ion of unique applications in hematology and microbiology.

19 uture development of this important field of microbiology.

20 tional approach in the practice of molecular microbiology.

21 een discovered and studied since the dawn of microbiology.

22 ment in the fields of mucosal immunology and microbiology.

23 studies and are widely used in environmental microbiology.

24 , and implement in order to improve clinical microbiology.

25 proteins is one of the fundamental tasks of microbiology.

26 re Jules Bordet studied and was Professor of Microbiology.

27 Microbiology 159, 565-579 (2013)) should have been cited

28 aper by Li et al. in this issue of Molecular Microbiology adds Cupriavidus FisR to an expanding reper

29 primary and secondary efficacy, safety, and microbiology analyses on the full analysis population, w

30 ichia coli is an important model organism in microbiology and a prominent member of the human microbi

31 Microbiology and AMR patterns are likely to reflect inst

32 We analyzed electronically captured microbiology and antibiotic use data from a network of U

33 However, the relationship between airway microbiology and asthma phenotype is poorly understood.

34 cantly contribute to the field of analytical microbiology and biochemistry.

35 his study examined the relationships between microbiology and chemistry in groundwater wells located

36 ntified in IVCM images by a grader masked to microbiology and clinical outcome (defined as good: heal

37 a large-scale epidemiological study of oral microbiology and dental caries in children from a locali

38 be useful in engineering, synthetic biology, microbiology and genetics.

39 In fields, such as ecology, microbiology and genomics, non-Euclidean distances are w

40 Professor at Dartmouth in the Department of Microbiology and Immunology working on immune homeostasi

41 Recent evidence from the fields of microbiology and immunology, as well as a small number o

42 is approach may find diverse applications in microbiology and in biomedical and forensic studies of h

43 as a faculty member in the NYU Department of Microbiology and in the Department of Molecular Biology

44 specimens were analyzed at the Department of Microbiology and Infection Control, Statens Serum Instit

45 European Society of Clinical Microbiology and Infectious Diseases (ESCMID) Research G

46 America (IDSA), European Society of Clinical Microbiology and Infectious Diseases (ESCMID), Swedish,

47 e relationship between CFTR activity, airway microbiology and inflammation, and lung function in subj

49 communities has broad applications in basic microbiology and medicine, but remains a grand challenge

50 Despite these observations are well known in microbiology and molecular biology, the mathematical mod

51 Microbiology and polymerase chain reaction (PCR) techniq

52 This review outlines the microbiology and preclinical studies of omadacycline, in

53 d nose/throat swabs provided by the Clinical Microbiology and Public Health Laboratory, Addenbrooke's

54 ce profiles of bacterial strains in hospital microbiology and public health settings.

55 er something for almost anyone interested in microbiology and represent an excellent example of field

56 ion across states characterized by different microbiology and that their trajectory is not uniform.

57 re carefully characterized (including airway microbiology) and followed for a median of 84 months.

58 ntext of biofluid, histopathology, cytology, microbiology, and biomarker discovery frameworks.

59 mpared to qPCR, its applications in clinical microbiology, and considerations for implementation of t

60 tional detail on biogeography, environmental microbiology, and exemplary species.

61 Natural product chemistry, microbiology, and food, human, and plant metabolomics re

62 nostic requirements in the field of clinical microbiology, and it can be utilized for typing of other

63 various applications in clinical proteomics, microbiology, and molecular biology.

64 describe temporal changes in the incidence, microbiology, and outcomes of infective endocarditis and

65 he international infectious disease, medical microbiology, and public health communities because S. p

66 de a historical background on the discovery, microbiology, and recognition of M. genitalium as a path

67 lcium phosphate chemistry related to saliva, microbiology, and the role of saliva in maintaining oral

68 be the characteristics, severity of disease, microbiology, and treatment of patients with bronchiecta

69 metabolomic analyses together with in vitro microbiology approaches and whole-genome sequencing of M

70 Traditional cultivation approaches in microbiology are labor-intensive, low-throughput, and yi

71 theses, and strengthens the position of oral microbiology as a model system for microbial ecology in

72 iologist members of the American Society for Microbiology (ASM) concerning detailed verification stra

73 As part of the American Society for Microbiology (ASM) Evidence-Based Laboratory Medicine Pr

74 ntinue to work with the American Society for Microbiology (ASM) in meeting the future challenges face

75 nts from mice were analyzed by culture-based microbiology assays.

76 o investigate changes in water chemistry and microbiology at a green building following a transition

77 g with Bernard Horecker in the Department of Microbiology at New York University (NYU), she embarked

78 rom 15 patients at the Department of Medical Microbiology at St.

79 ratories suggest the necessity for continued microbiology-based understanding of biosafety practices,

80 In this issue of the Journal of Clinical Microbiology, Bautista-Lopez et al. provide characteriza

81 f DNA and has become the method of choice in microbiology, bioengineering, and molecular biology.

82 y integrating ecology, evolutionary biology, microbiology, bioinformatics, and clinical expertise.

83 These models can offer insights into microbiology, both in understanding natural systems and

84 ple, engineering, chemistry, mineralogy, and microbiology) can be applied to further understand the m

85 In this editorial, the American Society for Microbiology Clinical and Public Health Microbiology Com

86 edge has deep implications for environmental microbiology, clinical anti-bacterial therapy, and indus

87 for Microbiology Clinical and Public Health Microbiology Committee's Subcommittee on Laboratory Prac

88 al theories of the membrane potential to the microbiology community and discuss the needs to revise t

89 Therefore, a key challenge for the clinical microbiology community is to clearly articulate the valu

90 racterization of bacterial methylomes by the microbiology community.

91 In 2016, the American Academy of Microbiology convened a colloquium to examine point-of-c

92 Furthermore, a subset of samples with unique microbiology corresponded with unique chemical signature

93 From 2008, microbiology data and associated outcomes adjusted for p

94 infections after elective surgeries based on microbiology data are limited.

95 in decided to compare the empirical clinical microbiology data from our institution with estimates an

96 Clinical and microbiology data were reviewed, and associations with v

97 Microbiology database records were retrospectively revie

98 er understand temporal trends and sources of microbiology delivered to taps, these treatment plants a

99 urveillance involved 130 pediatric wards and microbiology departments throughout France.

100 For traditional microbiology departments, opportunities for improvement

101 tem cell transplantation, rapid and accurate microbiology diagnostics are essential to the practice o

102 ied from IE hospitalizations to describe the microbiology distribution and temporal trends among hosp

103 iscussions recurring on American Society for Microbiology Division C and ClinMicroNet listservs.

104 oral cavity have long been a major focus of microbiology due to their influence on host health and i

105 Microbial electrochemistry merges microbiology, electrochemistry and electronics to provid

106 he state of current knowledge concerning the microbiology, epidemiology, clinical manifestations of i

107 work in a growing field at the interface of microbiology, evolution, and ecology that combines multi

108 In this issue of Molecular Microbiology, Ferla et al. describe examples of enzymes

109 atory and, therefore, less contributory to a microbiology-focused biosafety risk assessment than info

110 aboratories completed a questionnaire-based, microbiology-focused biosafety risk assessment.

111 analyses, including applications in clinical microbiology for bacteria differentiation and in surgica

112 y (MALDI-TOF MS) has revolutionized clinical microbiology for isolate identification and has the poss

113 l role in establishing the field of cellular microbiology, founded in part by Dr.

114 assess the effect of azithromycin on sputum microbiology from participants of the AMAZES (Asthma and

115 Here, we combine experimental microbiology, genomic analyses, and Earth system modelin

116 Molecular Microbiology, Hajduk et al. provide new insight into thi

117 Clinical microbiology has long relied on growing bacteria in cult

118 ndred years, groundbreaking research in oral microbiology has provided a broad and deep understanding

119 In the last decade, diagnostic microbiology has seen a shift toward culture-independent

120 Medicine and clinical microbiology have traditionally attempted to identify an

121 ities in typhoid-endemic settings, including microbiology, histopathology, and radiology, the etiolog

122 In this issue of the Journal of Clinical Microbiology, Horn et al. (E.

123 This article is part of the special issue "Microbiology: how to bridge mechanisms and phenomenology

124 In environmental microbiology, however, the functions of a majority of mi

125 rts in metabolic engineering, biotechnology, microbiology, human health, and cell culture.

126 ions including rapid mucosal diagnostics for microbiology, immune responses, and biochemistry.

127 e review recent findings at the interface of microbiology, immunology, and nutrition, with an emphasi

128 se biomedical fields such as cancer biology, microbiology, immunology, hematology, and stem cell biol

129 s and Truepera); elucidate the ways in which microbiology impacts mineralogy and vice versa; and reve

130 nd periods as a postdoc at the Institute for Microbiology in Dusseldorf and the Virus Laboratories of

131 This issue of Molecular Microbiology includes a paper by Korshunov et al. in whi

132 Basic sciences, microbiology, infectious diseases, and public health con

133 becoming an important component of clinical microbiology informatics.

134 a new set of assumptions about how clinical microbiology is practiced here.

135 A classic problem in microbiology is that bacteria display two types of growt

136 A fundamental challenge in medical microbiology is to characterize the dynamic protein-prot

137 The Journal of Clinical Microbiology (JCM) herein presents its biannual report s

138 In this issue of the Journal of Clinical Microbiology, Karlowsky et al. report the results of an

139 ional Journal of Systematic and Evolutionary Microbiology Knowledge of designations involving clinica

140 In this issue of the Journal of Clinical Microbiology, L.

141 lab turnaround time (TAT) at a tertiary care microbiology lab.

142 lution was compared to results from clinical microbiology laboratories (Etest) and to polymyxin resis

143 result of using culturomics in our clinical microbiology laboratories (including amoeba co-culture a

144 Public health microbiology laboratories (PHLs) are on the cusp of unpr

145 ny limitations to the use of NGS in clinical microbiology laboratories are being overcome with decrea

146 ing for this virus, the majority of clinical microbiology laboratories are dependent on commercially

147 and commercial laboratory settings, clinical microbiology laboratories are likely unfamiliar with the

148 he most important results issued by clinical microbiology laboratories because they routinely guide c

149 Clinical microbiology laboratories face challenges with workload

150 The number of onsite clinical microbiology laboratories in hospitals is decreasing, li

151 Louis Children's Hospital microbiology laboratories in St.

152 outbreak has had a major impact on clinical microbiology laboratories in the past several months.

153 ed to Public Health England (PHE) by all the microbiology laboratories included in the national surve

154 Ten microbiology laboratories throughout the United States c

155 and discuss practical solutions for clinical microbiology laboratories to address these public health

156 (WGS) is now routinely performed in clinical microbiology laboratories to assess isolate relatedness.

157 be implemented in public health and clinical microbiology laboratories to further discern the mechani

158 The ability of clinical microbiology laboratories to reliably detect carbapenema

159 13) and Leeds (July 2012 through April 2013) microbiology laboratories underwent culture and whole-ge

160 Furthermore, some clinical microbiology laboratories will resist the mandate to req

161 ide range of infectious diseases in clinical microbiology laboratories worldwide.

162 ing pharmacies, continues to impact clinical microbiology laboratories, as evidenced by the numerous

163 pants included representatives from clinical microbiology laboratories, industry, and the government,

164 identified by phenotypic methods in clinical microbiology laboratories.

165 ass spectrometers commonly found in clinical microbiology laboratories.

166 of Gram-negative bacilli tested at two U.S. microbiology laboratories.

167 of CRO while reducing the burden on clinical microbiology laboratories.

168 ere tested by three different hospital-based microbiology laboratories.

169 this method is impractical for most clinical microbiology laboratories.

170 MIC determination are available to clinical microbiology laboratories.

171 aceae (CPE) represents a major challenge for microbiology laboratories.

172 s is standard of care (SOC) in many clinical microbiology laboratories.

173 ng services (41.3% reduction, P = .01) and a microbiology laboratory (82.8% reduction, P = .02) were

174 omes at a time when advances in the clinical microbiology laboratory (CML) provide more-precise and -

175 ls can be easily implemented in any clinical microbiology laboratory and could help to optimize thera

176 e often collected off-site from the clinical microbiology laboratory and require transport, we assess

177 notypic study performed at a single clinical microbiology laboratory assessed isolates growing in the

178 Time-series analysis was performed on microbiology laboratory data.

179 s Hopkins biosafety level 3 (BSL-3) clinical microbiology laboratory designed and validated waste-han

180 time make it suitable for use in the routine microbiology laboratory for CPE detection.

181 Fecal samples submitted to our clinical microbiology laboratory from patients in the Philadelphi

182 Automation of the clinical microbiology laboratory has become more prominent as lab

183 ent practiced in institutions where the core microbiology laboratory has been moved offsite, and an a

184 The Aga Khan University clinical microbiology laboratory identified an outbreak of ceftri

185 itive patients were identified in a clinical microbiology laboratory in England over a period of 2 we

186 The Mahosot Hospital Microbiology Laboratory in Vientiane, Laos, routinely pe

187 genomes - now a staple of the public health microbiology laboratory in well-resourced settings - can

188 lights the possible shortcomings of standard microbiology laboratory methods and underscores the impo

189 , disease epidemiology, and routine clinical microbiology laboratory operations.

190 non-Escherichia coli isolates in a clinical microbiology laboratory remains problematic.

191 Based on clinical microbiology laboratory testing data of cerebrospinal fl

192 gly considered due to growth patterns in the microbiology laboratory that were more consistent with t

193 ong-read sequencing approach in the clinical microbiology laboratory using the Oxford Nanopore Techno

194 luded: (i) direct specimen submission to the microbiology laboratory via the pneumatic tube system an

195 y, to assess its suitability for the routine microbiology laboratory, and to compare it to the Xpert

196 reduced by direct specimen submission to the microbiology laboratory, autoverification, and processin

197 for pathogen identification in the clinical microbiology laboratory, but the impact on patient care

198 ds to detect these organisms in any clinical microbiology laboratory, including those in resource-lim

199 in an anaerobic holding jar in the clinical microbiology laboratory, where anaerobic plates were pre

200 from cerebrospinal fluid (CSF) in a licensed microbiology laboratory.

201 dents reported interacting with the clinical microbiology laboratory.

202 of implementation planning for NAATs in the microbiology laboratory.

203 n important new tool for use in the clinical microbiology laboratory.

204 ST) is a fundamental mission of the clinical microbiology laboratory.

205 the Accelerate Pheno system in the clinical microbiology laboratory.

206 ining financial resources, and utilizing the microbiology laboratory.

207 n the definitive method used in the clinical microbiology laboratory.

208 d can be readily implemented in any clinical microbiology laboratory.

209 s for species identification in the clinical microbiology laboratory.

210 y medicine, infectious diseases and clinical microbiology, laboratory medicine, and patient advocacy.

211 Although microbiology labs historically use manual processes, the

212 espite an extensive use in food industry and microbiology, little is known about the drying kinetics

213 In this issue of the Journal of Clinical Microbiology, M.

214 Microbiology, management, and clinical outcomes data fro

215 In this issue of the Journal of Clinical Microbiology, Manak et al. demonstrate the impact of ant

216 This special issue of Molecular Microbiology marks the 25(th) anniversary of the discove

217 In this issue of Molecular Microbiology, McDaniels and colleagues add yet another m

218 antly lower with mRDT than with conventional microbiology methods (odds ratio [OR], 0.66; 95% confide

219 e sentinel site laboratory with conventional microbiology methods and subsequently with molecular ana

220 rce, in part due to limitations of classical microbiology methods and the inability of most molecular

221 relations between conventional and molecular microbiology methods that indicate faecal contamination.

222 nical outcomes between mRDT and conventional microbiology methods.

223 the value of quantitative methods in making microbiology more predictable.

224 In this issue of the Journal of Clinical Microbiology, N.

225 In this issue of the Journal of Clinical Microbiology, Nguyen et al. (M.

226 ional Journal of Systematic and Evolutionary Microbiology Noteworthy discussion centers around descri

227 dy index test performed at the Department of Microbiology, Odense University Hospital, Denmark, from

228 A better understanding of the microbiology of bloodstream infections could improve out

229 The microbiology of gastroenteritis in MSM has not been exam

230 reef-systems available for understanding the microbiology of healthy coral reefs and their surroundin

231 The differences in the microbiology of IE hospitalizations suggest that SUDs ar

232 eans, LA, U.S.A. were sampled to compare the microbiology of independent systems that treat the same

233 um specimens and artworks and better control microbiology of industrial fermentations.

234 We sought to study the epidemiology and microbiology of SSTIs in a population of 8597 patients f

235 ugh, much research has been conducted on the microbiology of such engineered systems at lab and field

236 es being compiled by the Journal of Clinical Microbiology on a biannual basis, this compendium summar

237 with true infections included presence of a microbiology order, billing codes for surgical site infe

238 zing the frequency of modeling approaches in microbiology over time.

239 cle in this issue of the Journal of Clinical Microbiology (P.

240 ramifications to several disciplines such as microbiology, pharmacology, agriculture, and pathogenesi

241 e was the expected per-patient cost savings (microbiology, pharmacy, and indirect hospital costs) wit

242 t of blood culture contamination in terms of microbiology, pharmacy, and wider indirect hospital impa

243 there have been many studies addressing the microbiology, physiology, and impacting environment fact

244 Clinical microbiology practices for retention of clinical isolate

245 2014 were identified and linked to national microbiology, prescribing, and morbidity and mortality d

246 We demonstrate that forensic microbiology provides a useful tool for linking a perpet

247 try, food engineering, food technology, food microbiology, quality control, and sensory analysis.

248 ase in this issue of the Journal of Clinical Microbiology (R.

249 In this issue of the Journal of Clinical Microbiology, R.

250 We examined microbiology records of adult patients at the University

251 last decade have revolutionized the field of microbiology, redrawing the landscape, and entirely rede

252 gh the British Paediatric Surveillance Unit, microbiology reference laboratories, and national public

253 together results in significant decreases in microbiology report TATs.

254 hinders basic, synthetic, and translational microbiology research and development beyond a few model

255 view of network methods, rather to introduce microbiology researchers to (semi)-unsupervised data-dri

256 010-6/30/2015 at hospitals (N=181) reporting microbiology results in the Premier Healthcare Database

257 We describe how one contributing microbiology RI determined the most relevant skills.

258 In this issue of Molecular Microbiology, Rued et al. show that in pneumococci GpsB

259 In this issue of the Journal of Clinical Microbiology, S.

260 that trended higher within the general (not microbiology-specific) laboratory for core activities, s

261 of applying ecological concepts of scale to microbiology, specifically examining their application t

262 ill allow for more streamlined processing of microbiology specimens.

263 ature and the direct observation of pharmacy/microbiology staff.

264 xample analysis using FT-MS data from a soil microbiology study demonstrates the core functionality o

265 information from aquatic systems and medical microbiology suggests the potential for viral influences

266 pharmacists, infectious disease, and medical microbiology teams), rationalized, and policy-informed,

267 vide an effective and economical solution to microbiology techniques that rely on enrichment, thereby

268 Advanced microbiology technologies are rapidly changing our abili

269 In this issue of Molecular Microbiology, Terry, Jiang, and colleagues in Per Bullou

270 a colloquium to examine point-of-care (POC) microbiology testing and to evaluate its effects on clin

271 ementation, oversight, and evaluation of POC microbiology testing.

272 the hospital and reduced the number of other microbiology tests performed.

273 Emerging POC microbiology tests, especially nucleic acid amplificatio

274 ers to cover and hospitals to adopt advanced microbiology tests.

275 Large data sets within clinical microbiology that are amenable to the development of AI

276 d represent an excellent example of field of microbiology that has benefitted hugely by advances acro

277 eutrophilic asthma is associated with airway microbiology that is significantly different from that s

278 sease remains controversial: is this altered microbiology the driving agent of disease or merely a co

279 the annotation of experimental conditions in microbiology, the available annotations are not based on

280 tive biology that are of growing interest to microbiology, the challenges associated with the innate

281 contributions to clinical and public health microbiology, the interpretation of whole-genome sequenc

282 st unique as a group of bacteria to study in microbiology: they are genomically, phylogenetically and

283 Longitudinal samples indicated microbiology to have stability both spatially and tempor

284 cluding clinical diagnosis and environmental microbiology, to understand the contribution of metaboli

285 alkalinity, and disinfectant byproducts) and microbiology (total cell counts, plate counts, and oppor

286 founders, including age, sex, race, baseline microbiology, treatment with CFTR modulator, and CTFR ge

287 In this issue of the Journal of Clinical Microbiology, Truong et al. report significant reduction

288 ted in this issue of the Journal of Clinical Microbiology underscore the limitations of pneumococcal

289 eae In this issue of the Journal of Clinical Microbiology, V.

290 While a number of existing games touch on microbiology, very few consider the beneficial (as oppos

291 Microbiology was done on bronchoalveolar lavage fluid fr

292 Source water microbiology was most divergent from tap water, and each

293 Airway microbiology was significantly less diverse (P = .022) a

294 Phenotypic predictors of airway microbiology were identified by using multivariate linea

295 focal microscopy and molecular and classical microbiology were used to investigate microaspiration an

296 de, gynecologists and nurses, not trained in microbiology, were mostly able to identify E. coli and n

297 f molecules into bacteria and on advances in microbiology, which enable us to identify and access att

298 irst discuss some recent history of clinical microbiology within ASM and then some current challenges

299 the first study of coupled geochemistry and microbiology within the PPR and demonstrates how the con

300 In this issue of the Journal of Clinical Microbiology, Y.