ライフサイエンスコーパス: virology

1 anded our understanding of the principles of virology.

2 f the most intriguing topics in the field of virology.

3 rus maturation is a cornerstone principle in virology.

4 iral therapy development in the field of HCV virology.

5 heir study represents an important branch of virology.

6 populations is of fundamental importance to virology.

7 e of the most poorly understood phenomena in virology.

8 needs and unsolved problems of computational virology.

9 arious titers is beneficial for the field of virology.

10 beginning of an exciting era in human tumor virology.

11 core component of fundamental discoveries in virology.

12 ine 100 years ago, opened the field of tumor virology.

13 ants of viruses is of critical importance in virology.

14 hape paradigms in both molecular biology and virology.

15 are an important step forward in diagnostic virology.

16 remains a technical challenge in structural virology.

17 fungi will contribute to progress in fungal virology.

18 not in biochemistry but in cell biology and virology.

19 and 9000 full-text articles from Journal of Virology.

20 ften unexpected, developments in biology and virology.

21 ins of biology, including immunogenomics and virology.

22 maging, pathological features, and molecular virology.

23 ly expand our knowledge in basic and applied virology.

24 aining and expanding much-needed research in virology.

25 ught unprecedented attention to the field of virology.

26 new levels of sensitivity and throughput for virology.

27 d cellular biology-and increasingly physical virology.

28 an excellent model that can be exploited in virology.

29 en fatal and highlighted gaps in fundamental virology.

30 niello for the 513th session of This Week in Virology.

31 l infection play an especially large role in virology.

32 further characterize the role of PIKfyve in virology.

33 novel mechanism reaches beyond the field of virology.

34 mosaic virus, paved the way for the field of virology.

35 ays, and applied double-stranded RNA (dsRNA) virology.

36 ems available to study tropism and molecular virology.

37 ns for viral evolution, are open problems in virology.

38 ses is an intriguing mystery in evolutionary virology.

39 sequencing to validate standards in clinical virology.

40 areas of biochemistry, cellular biology, and virology.

41 d, particularly in the areas of oncology and virology.

42 ad readership from the fields of oncology to virology.

43 viruses, have been a research focus in plant virology.

44 midst diverse host RNAs is a key question in virology.

45 a major goal and challenge for the field of virology.

46 ese enzymes to the spotlight in the field of virology.

47 re conceptual approach of stoichiometries in virology a much higher number of antibodies is required

48 jor advancements in our understanding of HBV virology along with better understanding of immunopathog

49 Post hoc virology analyses were performed for participants identi

50 Post hoc virology analysis indicated that genotypic patterns obse

51 tial applications as a reagent for serology, virology and as an immunogen.

52 sen to accommodate this rapid advancement in virology and associated requirements for efficiency, spe

53 erve as a single template for both molecular virology and bacteriology, with a RISA PCR rapidly detec

54 The work could be of broad interest in virology and beyond.

55 The data reported here are important to both virology and cancer biology.

56 th viruses infect hepatocytes, the molecular virology and cellular biology of their respective replic

57 number of firsts in the field of structural virology and contributed to the field at the national an

58 diagnostics and highlights aspects of basic virology and epidemiology that pertain to viral detectio

59 gly, the CytoFLEX can be of great benefit to virology and EV research, and will help to expand the us

60 unique resource for studies of HCV molecular virology and for studies of pathogenesis, protective imm

61 vided new insights into central questions of virology and host cell biology.

62 technology and basic knowledge of molecular virology and immunology have engendered novel approaches

63 erable human and financial resources on both virology and immunology, resulting in the generation of

64 onsequent recognition of their importance in virology and immunology.

65 ed new frontiers in the study of fundamental virology and infectious disease.

66 re enabling systems epidemiology and systems virology and making it possible to respond rapidly to em

67 reisman in medicine and Charles Weissmann in virology and microbiology, I found that understanding wh

68 ys and mass spectrometry quantification with virology and microscopy, we monitor the temporal formati

69 iological processes in immunology, oncology, virology and neuroscience.

70 s from the classical conceptual framework in virology and opens an alternative possibility (at least

71 hould increase our efforts to understand the virology and pathogenesis of HCV genotype 3, aiming at b

72 research that emphasizes mucosal immunology, virology and pathogenesis studies at each anatomic site

73 A/Indonesia/05/2005) and were examined using virology and pathology.

74 uses has facilitated new discoveries in both virology and plant biology.

75 d host defenses both informs basic molecular virology and promotes the development of host- and virus

76 he method is appropriate for use in clinical virology and reference laboratories for the typing of en

77 cation of novel bioactive compounds to basic virology and the development of new antiviral agents.

78 ntinues to be involved in various aspects of virology and to assist and annoy journal editors and oth

79 with expertise spanning infectious diseases, virology and transfusion medicine was assembled to rende

80 We obtained weekly virology and underlying cause-of-death mortality time se

81 d (Smadel being one of the deans of American virology) and to meet several times with Carleton Gajdus

82 ive PCR is a diagnostic mainstay of clinical virology, and accurate quantitation of viral load among

83 have been used primarily in cancer biology, virology, and basic cell biology, but they have rarely b

84 be useful for studies of tropism, molecular virology, and characterization of virus-host interaction

85 fferent fields including mammalian genetics, virology, and CRISPR engineering is advancing epigenome

86 one institution and describe the hematology, virology, and cytokine findings.

87 made to our understanding of immunology and virology, and future directions in medical and basic res

88 e to several fields, including cell biology, virology, and gene delivery for therapeutic purposes.

89 CFs prospectively to study the epidemiology, virology, and genetic host factors of naturally occurrin

90 ith potential implications for cell biology, virology, and host-targeted antiviral design.

91 ation to track multiple clinical, pathology, virology, and immunology outcomes.

92 urveillance and research in disease ecology, virology, and immunology.

93 new opportunities in transcriptome analysis, virology, and other fields.

94 for clinicians, in particular epidemiology, virology, and pathogenesis, diagnostic testing including

95 rology conferences, the American Society for Virology Annual Meeting (ASV), the International Herpesv

96 ture microdissection-driven unbiased systems virology approach, we isolated and transcriptionally pro

97 mbined molecular dynamics, biochemistry, and virology approaches.

98 Readers of the Journal of Virology are doubtless aware of the fundamental advances

99 Curriculum guidelines for virology are needed to best guide student learning due t

100 Genomics and virology are unquestionably important, but complex, doma

101 Virology as a discipline has depended on monitoring cyto

102 virology research, vaccine development, and virology as a whole.

103 icles have significant importance and use in virology as tools for studying the biology of highly pat

104 dvancement of our understanding on the basic virology as well as the urgently necessitated drug devel

105 g to have significant impact in the field of virology, as they are helping us understand how viruses

106 mpounds, several virus strains, and detailed virology assays resulted in the identification of five s

107 , super-resolution microscopy, and molecular virology assays, we compare infections with lab-adapted

108 who is Director of Medical Microbiology and Virology at Texas Children's Hospital, has extensive exp

109 Hastings et al., Virology (Auckl) 494:248-256, 2016, ).

110 He had an extensive work-up including virology, autoimmune, and metabolic profiles in addition

111 My independent career in structural virology began at Warwick University, England, working o

112 1918 epidemic is beyond the reach of modern virology but, based on seroarcheology, appears to have b

113 as revolutionized the field of environmental virology by allowing the exploration of viral communitie

114 provides a new system for exploring archaeal virology by examining host-virus interactions and the un

115 sparked the first intense interest in tumor virology by suggesting the possibility of a similar caus

116 Experimental virology can inform strategic monitoring for new viruses

117 uted major concepts to immunology, genetics, virology, cancer, and cell biology.

118 In addition to its significance for virology, capsid-related research has implications for b

119 of biomedical research areas such as cancer, virology, circadian rhythms, and behavioural neuroscienc

120 The Virology Committee of the AIDS Clinical Trials Group in

121 ensive resource specific to the needs of the virology community, with an emphasis on the description

122 urce specific to the needs of the structural virology community, with an emphasis on the description

123 ion of learners and promote belonging in the virology community.

124 nts have a foundational understanding of key virology concepts, and the importance in being able to c

125 ted speaking positions at the four prominent virology conference series we have followed since the 19

126 now provide records profiling four prominent virology conferences over the years 1982 to 2017 with th

127 st 35 years for four prominent international virology conferences, the American Society for Virology

128 here how several other lines of research in virology converged during the last 2 decades with the di

129 Advances in molecular virology coupled with improvements in diagnostic methods

130 course content features viruses; stand-alone virology courses are infrequently offered to undergradua

131 Advances in molecular virology--creating deleterious gene mutations, altering

132 ted to 14 seasons of weekly consultation and virology data in England and Wales.

133 , mechanistic model that integrates in vitro virology data, pharmacokinetics, and viral response to a

134 tivation, which was documented with detailed virology data.

135 nalyses reported in this issue of Journal of Virology demonstrate that the apparent presence of HPV18

136 Data on the virology, detection, epidemiology, clinical features, an

137 My career trajectory into virology did not involve much if any advance planning bu

138 e outline some of the major advances made in virology during this period, particularly in light of th

139 nces in our understanding of West Nile virus virology, ecology, clinical disease, diagnosis, and deve

140 ology educators and the American Society for Virology Education and Career Development Committee, are

141 An understanding of current virology education may improve pedagogical approaches fo

142 Learning goals and content in graduate virology education place additional emphasis on skill bu

143 Such guidelines, developed by virology educators and the American Society for Virology

144 Virology encompasses a broad spectrum of topics touching

145 Pharmacokinetic, safety, and virology endpoints were also assessed.

146 ked by comparing the results with Journal of Virology entries in two existing manually curated databa

147 logy, chemistry, biochemistry, microbiology, virology, environmental and chemical carcinogenesis, imm

148 great important and interest to the field of virology, especially to those who use TMEV as a murine m

149 and numerous applications of this theory in virology, experimental results have provided evidence fo

150 CMV) antigens is widely employed in clinical virology for rapid diagnosis of HCMV-related infections.

151 tracts in eight U.S. cities, and we analyzed virology for the groups randomized to treatment with gui

152 tems have long been the mainstay in clinical virology for the growth and identification of viruses fr

153 This report is of importance to the field of virology for three reasons.

154 s B virus (HBV) is a singular case in animal virology for which no consensus evolutionary explanation

155 organisms represents an opportunity to push virology forward in useful and hard to predict ways.

156 me Trust in 2012 and the other by the Global Virology Foundation in 2013, assembled academic, public

157 These features challenge several virology foundations and could apply to other multicompo

158 future efforts to develop in vitro tools for virology from non-model organisms and these C. perspicil

159 Combining technologies including genetics, virology, genomic enhancers, and RNA sensing, these tool

160 ique and valuable resource for the fields of virology, genomics, and human disease genetics.

161 ironmental samples suggest that the field of virology has explored less than 1% of the extant viral d

162 Better understanding of HDV virology has led to the development of several therapeut

163 tury since its inception, the field of tumor virology has provided groundbreaking insights into the c

164 Across a rich 70-year history, single-cell virology has revealed the impact of host and pathogen he

165 During the last century, basic studies in virology have focused on developing a molecular mechanis

166 we sought to use transcriptional profiling, virology, histology, and echocardiograms to investigate

167 and compared parameters of clinical disease, virology, host responses, and pathology/histopathology w

168 diversity, molecular epidemiology, molecular virology, immunity and pathogenesis, virus structure, th

169 ty remains regarding critical aspects of its virology, immunology and epidemiology.

170 f bridging the gap between the fields of bat virology, immunology, and disease ecology, we hosted a s

171 different HIV clades, combining advances in virology, immunology, human host genetics and bioinforma

172 Their use to study HIV-1 biology, virology, immunology, pathogenesis and therapeutic devel

173 demonstrate the ubiquity of DVGs in clinical virology.IMPORTANCE Defective viral genomes (DVGs) can h

174 ward the understanding of various aspects of virology in general.

175 dan ebolavirus by the National Institute for Virology in Johannesburg, South Africa, a temporary diag

176 s Senior Research Fellow at the Institute of Virology in Wurzburg, Germany.

177 future applications of tissue engineering to virology, including current challenges and potential sol

178 the continuous and ever-increasing volume of virology information, the need to ensure that undergradu

179 rivate partnerships to translate fundamental virology into a licensed VSV-vectored Ebola vaccine.

180 One of the important puzzles in virology is how viruses assemble the protein containers

181 re ecologically important, yet environmental virology is limited by dominance of unannotated genomic

182 Greater understanding of AAV's molecular virology is needed to underpin needed improvements in ef

183 A central paradigm within virology is that each viral particle largely behaves as

184 A founding paradigm in virology is that the spatial unit of the viral replicati

185 An important question in virology is the mechanism(s) by which persistent viruses

186 cell culture.IMPORTANCE A major challenge in virology is the study of viruses that cannot be grown in

187 med by the University of Washington Clinical Virology Lab (UW Virology Lab), we evaluated assays usin

188 sity of Washington Clinical Virology Lab (UW Virology Lab), we evaluated assays using seven different

189 however, is difficult even in well-equipped virology laboratories or is unobtainable in the field un

190 gnostics into their clinical microbiology or virology laboratories, the CMV PC-PCR offers a relativel

191 creasing importance of subtyping by clinical virology laboratories.

192 N Veris System) was evaluated at 10 European virology laboratories.

193 gnostics system was evaluated at 10 European virology laboratories.

194 sted at the Yale New Haven Hospital Clinical Virology Laboratory (New Haven, CT, USA).

195 iagnostic samples referred to the Specialist Virology Laboratory (SVL) at the Royal Infirmary of Edin

196 rived from samples submitted to a diagnostic virology laboratory and one derived from samples collect

197 patients that were submitted to the clinical virology laboratory at the Emory University Hospital.

198 lar methods, and Laurent Kaiser, head of the Virology Laboratory at the University of Geneva Hospital

199 le-blood specimens submitted to the Clinical Virology Laboratory at Vanderbilt University Medical Cen

200 I established the first veterinary virology laboratory at Wallaceville Animal Research Stat

201 ersity of Washington Medical Center clinical virology laboratory became one of the first clinical lab

202 samples that were received at our diagnostic virology laboratory between May, 1994, and May, 1996, by

203 The experience of a public hospital virology laboratory during a springtime 2009 outbreak of

204 DFA; SimulFluor respiratory screen) when the virology laboratory opened.

205 luid (CSF) samples submitted to a diagnostic virology laboratory.

206 Here, we describe clinical features, virology, longitudinal cellular, and cytokine immune pro

207 e symposium at the 2024 American Society for Virology meeting.

208 irology Society (AVS) holds premier biennial virology meetings that foster multidisciplinary research

209 Here, we integrate molecular virology, metabolic assays, quantitative proteomics, and

210 In combination with traditional virology methods, droplet microfluidics should prove a p

211 ecific symptoms, viral symptoms, or positive virology might have lowered suspicion of bacterial infec

212 ledge and perspectives on MERS epidemiology, virology, mode of transmission, pathogenesis, diagnosis,

213 al host populations is a fundamental goal of virology, molecular biology, and disease ecology.

214 V, demonstrating the powerful combination of virology, molecular biology, enzymology, and protein str

215 , biochemistry, molecular biology, molecular virology, molecular genetics, epigenetics, genomics, pro

216 , biochemistry, molecular biology, molecular virology, molecular genetics, epigenetics, genomics, pro

217 The study of the epidemiology and virology of animal influenza viruses is key to understan

218 Here, we present the molecular virology of coronavirus infection, including its entry i

219 Here, we review the virology of EBV, mechanisms underlying disease pathogene

220 Further understanding of the basic virology of HCV and the exact mechanisms of viral persis

221 Recent progress in the molecular virology of HCV has come about due to the definition of

222 Increased understanding of the molecular virology of HDV will identify novel therapeutic targets

223 n this review, we will discuss the molecular virology of HEV, mode of transmission in industrialized

224 The conclusion drawn is that the virology of HIV has been pursed at the cost of understan

225 biology, immunology, structural biology, and virology of influenza virus is invaluable for developmen

226 cs system can be used to study the molecular virology of RVFV, assess current vaccine candidates, pro

227 Alongside investigations into the virology of SARS-CoV-2, understanding the fundamental ph

228 there is limited knowledge on the molecular virology of SFTS virus.

229 However, many aspects of the basic virology of species D HAdV, including their basic recept

230 se studies increase our understanding of the virology of the earliest stages of HIV-1 infection and p

231 nherent limitations in trying to outline the virology of the future, we hope this article will help i

232 res thus provide insights into the molecular virology of the influenza virus.

233 edge of fundamental aspects of the molecular virology of this important human pathogen, we foresee th

234 efforts in the field that focus on the basic virology of vector development will undoubtedly reap gre

235 numerous biological processes in immunology, virology, oncology, and neuroscience.

236 CMV enteritis, diagnosed by histopathology, virology, or both.

237 For the virology outcome estimates were calculated using a gener

238 s also seen an upsurge in research on dengue virology, pathogenesis, and immunology and in developmen

239 ge gained over the past three decades on the virology, pathogenesis, and immunology of HIV-1 infectio

240 Imaging data were supported by standard virology, pathology, and immunology findings.

241 The virology, pathophysiology, and treatment of the varicell

242 Bristol-Myers Squibb Virology, Patterson Trust, and National Institute on Dru

243 ed to gain-of-function research (immunology, virology) predicts public support better than specializi

244 Only experimental virology provides a path to identifying animal viruses w

245 dly expanding knowledge regarding SARS-CoV-2 virology provides a significant number of potential drug

246 s using proficiency panel samples from NIAID Virology Quality Assurance (VQA) program.

247 validation testing and submitted data to the Virology Quality Assurance program (VQA) for analysis.

248 metagenomic studies to address questions in virology rarely considered ecological, which can change

249 y, and the Pan American Society for Clinical Virology recognize that the FDA is committed to protecti

250 achieved in clarifying basic immunology and virology relating to UIV, several important questions re

251 NPHV natural history and molecular virology remain largely unexplored, however.

252 ere enrolled at the University of Washington Virology Research Clinic (WA, USA).

253 al history studies (University of Washington Virology Research Clinic) and HIV prevention trials (HIV

254 HSV shedding at the University of Washington Virology Research Clinic, Seattle, and Westover Heights

255 available without charge as a service to the virology research community to help facilitate the devel

256 es on priorities for revised rules governing virology research in the US.

257 Safety in virology research is paramount and oversight frameworks

258 Starting work in a virology research laboratory as a new technician, gradua

259 ulation, or spinoculation, is widely used in virology research to enhance viral infection.

260 It is also invaluable in virology research, diagnostics, and antiviral therapeuti

261 es by synthesizing knowledge from decades of virology research, eco-evolutionary theory and recent te

262 These results have implications for future virology research, vaccine development, and virology as

263 have specialized training and participate in virology research.

264 ation complex is a major frontier in current virology research.

265 Recent advances in virology, RNA medicines and nanotechnology have catalyse

266 of bovine diarrhea samples submitted to the Virology Section of the Diagnostic Center for Population

267 With the advance of HBV virology, several viral factors have been found to be as

268 The Australasian Virology Society (AVS) holds premier biennial virology m

269 iverse fields of biomedical research such as virology, stem cells, and developmental biology, and pro

270 rs after the discovery of HIV, its molecular virology still fails to explain the clinical immunology

271 ant infections and discussing the promise of virology studies as a venue to reveal the uncharted biol

272 E With the increasing number of evolutionary virology studies examining both intrahost and interhost

273 In vitro cell virology studies revealed clouds of phage virions disper

274 ental results from developmental biology and virology studies.

275 ucing (SI) phenotype, were determined in 391 virology substudy participants in AIDS Clinical Trials G

276 Fortunately, virology taught to undergraduates includes foundational

277 ortant historical trends: the study of basic virology, the development of genomic technologies, the i

278 Beyond virology, this approach is readily transferable to other

279 ears, I have applied what I learned in tumor virology to human cancer.

280 eek in Virology (TWiV) podcast seek to bring virology to new audiences through two different approach

281 ionally, we utilized techniques in molecular virology to temporally link events in virus replication

282 Molecular virology tools are critical for basic studies of the sev

283 We combined molecular virology tools with oxLDL serum measurements in differen

284 pose it was the merging of technologies with virology tools, which occurred in three defined steps di

285 gricultural/veterinary sector for those with virology training.

286 ucation (PHIRE) program and the This Week in Virology (TWiV) podcast seek to bring virology to new au

287 e discussions among experts of all topics in virology (TWiV).

288 airman of the newly established Institute of Virology, University of Erlangen-Nurnberg, in a similar

289 to act as an independent infectious unit in virology, until the recent discovery of vesicle-cloaked

290 genetic queries for functional genomics and virology (vectors 3.0).

291 s with regard to its epidemiology, molecular virology, virus-host interactions, immunological respons

292 overview of recent developments in "chemical virology." Viruses, as materials, provide unique nanosca

293 Virology was the highest funded category ( pound1 billio

294 hniques in electron tomography and molecular virology, we defined an early period in virus-infected m

295 ve been a scientist during the golden age of virology, when new techniques were being introduced into

296 emains a daunting challenge, particularly in virology where rapid sequence evolution and database exp

297 These findings reveal a new theme in virology wherein many different virus families encode pr

298 ave enabled an improved understanding of HCV virology, which has led to development of many new direc

299 This rich history promises that tumor virology will continue to contribute to our understandin

300 nt years, there has been a paradigm shift in virology with the realization that extremely large virus