ライフサイエンスコーパス: disease outbreak

1 ical interactions affect pathogen growth and disease outbreak.

2 ological assays in the face of an infectious disease outbreak.

3 ems in the context of an emerging infectious disease outbreak.

4 g to explore samples from a recent Theiler's disease outbreak.

5 acteristics of this novel infection during a disease outbreak.

6 urveillance and/or emergency management of a disease outbreak.

7 ontain bioterrorism or a naturally occurring disease outbreak.

8 the causal relationship between feed and the disease outbreak.

9 empts to track and control future infectious disease outbreaks.

10 l-being, including an increase in infectious disease outbreaks.

11 s is a powerful tool for understanding viral disease outbreaks.

12 onent of contingency planning and control of disease outbreaks.

13 be key drivers of the dynamics of infectious disease outbreaks.

14 of environmental and climate data to predict disease outbreaks.

15 immunologically naive population at risk for disease outbreaks.

16 isease and have been implicated in foodborne disease outbreaks.

17 the formal epidemiological investigation of disease outbreaks.

18 ing to predict variation in the magnitude of disease outbreaks.

19 (NoV) is the predominant cause of foodborne disease outbreaks.

20 se control as well as the emergence of human disease outbreaks.

21 ing analytical tool for ensemble modeling of disease outbreaks.

22 tance in order to prevent or suppress costly disease outbreaks.

23 to rapidly investigate potential infectious disease outbreaks.

24 ries models for the prediction of infectious disease outbreaks.

25 bacteria in food can cause serious foodborne disease outbreaks.

26 to transmission can reveal new insights into disease outbreaks.

27 ehavior spread in predicting and controlling disease outbreaks.

28 volves avoiding risks associated with costly disease outbreaks.

29 ributing to vaccine hesitancy, refusals, and disease outbreaks.

30 d high precision investigation of infectious disease outbreaks.

31 of patients affected by emerging infectious disease outbreaks.

32 ich may increase the spread and intensity of disease outbreaks.

33 re now frequently cited agents of waterborne disease outbreaks.

34 forecast national annual rates of infectious disease outbreaks.

35 ex evolutionary history that predates recent disease outbreaks.

36 ial step in the prediction and prevention of disease outbreaks.

37 st important steps for effective response to disease outbreaks.

38 terrorism and as a natural cause of sporadic disease outbreaks.

39 t of carriers are crucial for the control of disease outbreaks.

40 in real time for investigations of bacterial disease outbreaks.

41 but frequently observed cause of food-borne disease outbreaks.

42 from California sea lions during unexplained disease outbreaks.

43 s to enhance our ability to detect foodborne disease outbreaks.

44 e analysis of genetic data in the context of disease outbreaks.

45 ther cross-species transmissions and ensuing disease outbreaks.

46 invasive disease burden and sometimes cause disease outbreaks.

47 hold the key to interpreting the patterns of disease outbreaks.

48 of highly transmissible pathogen strains and disease outbreaks.

49 d by typing 40 isolates from four food-borne disease outbreaks.

50 prevent adenovirus-related acute respiratory disease outbreaks.

51 ified protozoan parasites causing waterborne disease outbreaks.

52 entifying, tracking, and intervening against disease outbreaks.

53 ful new tool for investigation of infectious disease outbreaks.

54 data on large-scale bioterrorist attacks and disease outbreaks.

55 n epidemiologic investigations of infectious-disease outbreaks.

56 or high- resolution epidemiologic studies of disease outbreaks.

57 and provides evidence for a 2-year cycle of disease outbreaks.

58 ntify and assess the potential of infectious disease outbreaks.

59 e response to public health emergencies from disease outbreaks.

60 es of introduction have occurred causing new disease outbreaks.

61 agnostic tools is very important to mitigate disease outbreaks.

62 rol and Prevention to identify meningococcal disease outbreaks.

63 igenic variants continue to emerge and cause disease outbreaks.

64 m critical decision-making during infectious disease outbreaks.

65 s designed to track the origin and spread of disease outbreaks.

66 gen that causes numerous food and waterborne disease outbreaks.

67 ropping systems that favor destructive viral disease outbreaks.

68 omplex, nonlinear dynamics during infectious disease outbreaks.

69 omes more and more routine during infectious disease outbreaks.

70 , disease forecasting, and adaption to other disease outbreaks.

71 for both preventative healthcare and during disease outbreaks.

72 so cause a structural delay to the spread of disease outbreaks.

73 eas deemed high risk for vaccine-preventable disease outbreaks.

74 tics are crucial in mitigating the effect of disease outbreaks.

75 ective behaviours and their vulnerability to disease outbreaks.

76 unities in the course of several respiratory disease outbreaks.

77 the impact of network dynamics on potential disease outbreaks.

78 ighly valuable in controlling and preventing diseases outbreaks.

79 iated with impacts on vaccine programmes and disease outbreaks; 1726 (21%) with beliefs, awareness, a

80 ssistance investigations were for infectious disease outbreaks (86%), with a relatively limited numbe

81 Following the detection of a disease outbreak, a response in proportion to the severi

82 zed to be the most common cause of foodborne disease outbreaks, accounting for 41% of all confirmed f

83 network dynamics on the predicted size of a disease outbreak across several groups of Verreaux's sif

84 rban raccoon population, the likelihood of a disease outbreak affecting the majority of the populatio

85 In the months before the Ebola virus disease outbreak, all three maternal indicators showed a

86 There have been infectious disease outbreaks among highly immunized populations, al

87 Exploring the sublethal effects of disease outbreaks among natural populations is challengi

88 ns about the resurgence of large respiratory disease outbreaks among US military basic trainees.

89 Disease outbreaks among wildlife have surged in recent d

90 hat has been applied to Ebola and Zika virus disease outbreaks, among others, and is currently being

91 aris corals during a concurrent white plague disease outbreak and bleaching event.

92 n for the 2001 United Kingdom foot and mouth disease outbreak and compare the efficacy of different c

93 ased connectance reduces the likelihood of a disease outbreak and decreases variance in prevalence am

94 t allows for models to be created prior to a disease outbreak and has the ability to handle large dat

95 d seabass before, during and after a natural disease outbreak and subsequent antibiotic treatment wit

96 However, the investigation of unusual disease outbreaks and allegations of use are highly diag

97 pathogen genomes facilitate the tracking of disease outbreaks and allow relationships between strain

98 ts were presented with one of 7 hypothetical disease outbreaks and asked how they would respond.

99 nd clinical research can be conducted during disease outbreaks and can help inform the outbreak respo

100 a consortium in order to assess triggers of disease outbreaks and devise appropriate monitoring tool

101 oughout the world and helping to investigate disease outbreaks and epidemics.

102 pidemiologically related isolates during GAS disease outbreaks and facilitate understanding and contr

103 en from military recruits during respiratory disease outbreaks and for follow up surveillance at seve

104 finfish are more frequently associated with disease outbreaks and host switches compared to domestic

105 historically used to investigate Ebola virus disease outbreaks and how new technologies allow for rap

106 enus are already widely distributed, causing disease outbreaks and population declines worldwide.

107 reater attention in assessing risks of prion disease outbreaks and prospects for their control in bot

108 ntial and challenges for vaccines to control disease outbreaks and protect the older population, toge

109 the main cause of serogroup C meningococcal disease outbreaks and sporadic meningococcal disease in

110 onsidered to be a significant contributor to disease outbreaks and subsequent crop loss.

111 tial for identifying and tracking infectious disease outbreaks and to improve our knowledge of the po

112 Toxic spills, hypoxia, disease outbreaks and toxin-producing algal blooms are a

113 alysis for studying evolutionary hypotheses, disease outbreaks and transmission events.

114 ding additional characteristics that predict disease outbreaks and uncovering landscape factors relat

115 enic worms, indicating the age dependency of disease outbreak, and sharing intriguing parallels to di

116 traits of the primary case of an infectious disease outbreak, and the circumstances for their aetiol

117 ts of natural resource shortages, infectious disease outbreaks, and migration.

118 vironmental drivers is necessary to forecast disease outbreaks, and to predict future changes in cora

119 f choice for the analysis of densely sampled disease outbreaks, and will form a rigorous framework fo

120 lamblia, the most common cause of waterborne disease outbreaks; and the large group of spore-forming

121 ional EPEC and EHEC isolates incriminated in disease outbreaks are actually E. albertii Metagenomic s

122 Case fatality rates of filovirus disease outbreaks are among the highest reported for any

123 Accurate forecasts of disease outbreaks are critical for effective public heal

124 Coral bleaching and disease outbreaks are often inter-related phenomena, sin

125 s), which contribute to the emergence of new disease outbreaks, are unclear.

126 iruses, and torradoviruses has led to global disease outbreaks as well as multiple paradigm shifts.

127 ysis of populations of pathogenic species in disease outbreaks, as well as for large-scale diversity

128 Ebola virus (EBOV) disease outbreaks, as well as the ability of EBOV to per

129 ing to emerging infectious and noninfectious disease outbreaks, assisting in disaster response, and e

130 ial, temporal and species-level variation in disease outbreaks associated with extreme weather events

131 Following a meningococcal disease outbreak at a U.S. college, we profiled the orop

132 ed during a well-characterized meningococcal disease outbreak at the University of Southampton, Unite

133 ween socioeconomic inequality and infectious disease outbreaks at the population level globally.

134 S/SIGNIFICANCE: Draft genomes of isolates of disease outbreak bacteria enable high throughput primer

135 ine industry may be vulnerable to infectious disease outbreaks because of the small-world structure o

136 ant parameter in the management of filovirus disease outbreaks because viral load correlates with sev

137 ributable to mass coral bleaching events and disease outbreaks, both of which are linked to anthropog

138 ing the role of locally produced inoculum in disease outbreaks, but evidence suggests multiple source

139 investigations were responses to infectious disease outbreaks, but the proportion of investigations

140 tion preceded the Devil Facial Tumor Disease disease outbreak by at least 100 y.

141 d the usefulness of characterizing foodborne disease outbreaks by epidemiologic criteria and also con

142 suggested to augment the risk of infectious disease outbreaks by extending the seasonal window for p

143 Disease outbreaks can once again increase perceptions of

144 The occurrence and magnitude of disease outbreaks can strongly influence host evolution.

145 tive agent in drinking water associated with disease outbreaks, can be harbored by and released from

146 experimental candidates against a potential disease outbreak caused by other members of the genus Eb

147 asion) may account for the rarity of natural disease outbreaks caused by B. thuringiensis.

148 t epidemiologic investigations of food-borne-disease outbreaks caused by C. perfringens.

149 The current strategy to control disease outbreaks caused by the intentional release of b

150 virus infection occurred, and only one other disease outbreak (caused by Mycobacterium species) was r

151 Disease outbreaks continue to reduce coral populations w

152 five datasets on densely sampled infectious disease outbreaks, covering a wide range of epidemiologi

153 stem to monitor health conditions and detect disease outbreaks; creation and implementation of 6 envi

154 ons surrounding how to control an infectious disease outbreak currently rely on a subjective process

155 individual becomes infected in an infectious disease outbreak depends on many interconnected risk fac

156 The disease outbreak directly followed a high temperature co

157 A disease outbreak due to Ebola virus (EBOV), suspected to

158 countermeasures in preparation for a future disease outbreak due to SUDV.

159 We analyzed patterns of some disease outbreaks during the strong 2015-2016 El Nino ev

160 behavior spreads has a very strong effect on disease outbreak dynamics.

161 Thus, by modulating disease outbreaks, ecological context (productivity and

162 Infectious disease outbreaks emerged across the globe during the re

163 oduced the 3 largest arboviral neuroinvasive disease outbreaks ever recorded in the United States.

164 irus is endemic and continues to cause major disease outbreaks every year.

165 ries, urbanisation, and health crises due to disease outbreaks, extreme weather, and conflict.

166 A mean of >/= 1000 foodborne disease outbreaks (FBDOs) causing >/= 20,000 illnesses a

167 easingly being identified in produce-related disease outbreaks, fresh produce is a rarely recognized

168 ferring 'who infected whom' in an infectious disease outbreak from densely sampled case data, with mo

169 vidual level could change our perspective on disease outbreaks from one based on public health to one

170 EBOV.IMPORTANCE The most recent Ebola virus disease outbreak, from 2014 to 2016, resulted in approxi

171 but are sufficiently general to forecast any disease outbreak, given incidence or case count data.

172 The December, 2019 coronavirus disease outbreak has seen many countries ask people who

173 enome sequence data to investigate bacterial disease outbreaks has been keenly anticipated in many qu

174 sequencing methods to investigate historical disease outbreaks has provided us with an unprecedented

175 Breeding phenology and disease outbreaks have been associated with warming temp

176 Although lethal human disease outbreaks have been confined so far to sub-Sahar

177 Supporting this, no Bombali virus-associated disease outbreaks have been reported, although Bombali v

178 Recent infectious disease outbreaks have further highlighted the need for

179 yping methods for the detection of foodborne disease outbreaks have limitations that reduce their use

180 l deployed to remote areas during infectious disease outbreaks have limited access to mechanical and

181 Mass mortalities due to disease outbreaks have recently affected major taxa in t

182 During disease outbreaks, however, the absence of saturation ef

183 epidemiology of Salmonella and investigating disease outbreaks; however, production and quality contr

184 ignificantly declined during the Ebola virus disease outbreak in 2014.

185 se to a university serogroup B meningococcal disease outbreak in 2015.

186 er, only a single genotype was detected in a disease outbreak in a previously uninfected herd.

187 irus was identified as the cause of a severe disease outbreak in commercial laying chicken farms in M

188 from hemorrhagic fever cases during a large disease outbreak in East Africa in 1997 and 1998.

189 During the ongoing Ebola virus disease outbreak in parts of Western Africa, most assays

190 firmed using unpassaged isolates from a 1999 disease outbreak in Puerto Rico.

191 KV-141, isolated during a febrile disease outbreak in Sudan, was identified as another iso

192 demic remains the single greatest infectious disease outbreak in the past century.

193 nuary 2016, a novel H7N8 HPAI virus caused a disease outbreak in turkeys in Indiana, USA.

194 The Ebola virus disease outbreak in west Africa has prompted significant

195 After the detection of an Ebola virus disease outbreak in west Africa in 2014, one of the elem

196 The Ebola virus disease outbreak in west Africa is pivotal for the world

197 The 2013-16 Ebola virus disease outbreak in west Africa was associated with unpr

198 The Ebola virus disease outbreak in West Africa was unprecedented in bot

199 The magnitude of the 2013-2016 Ebola virus disease outbreak in West Africa was unprecedented, with

200 e being assessed during the 2014 Ebola virus disease outbreak in west Africa.

201 s a mosquito-borne zoonotic pathogen causing disease outbreaks in Africa and the Arabian Peninsula.

202 ss or pollution) in initiating sudden deadly disease outbreaks in amphibian populations with detectab

203 ve been identified as the cause of explosive disease outbreaks in amphibians worldwide and can be tra

204 is knowledge should aid in the prevention of disease outbreaks in captive macaques and supports the g

205 health officials when addressing Ebola virus disease outbreaks in countries and seasons where malaria

206 ndemic of Yersinia pestis caused devastating disease outbreaks in Europe for almost 400 years.

207 history, with two events resulting in severe disease outbreaks in human populations.

208 predicting and controlling the emergence of disease outbreaks in human populations.

209 The frequent occurrence of disease outbreaks in humans caused by group A Streptococ

210 iciviruses as the leading cause of foodborne disease outbreaks in Minnesota.

211 Disease outbreaks in multiple El Nino-connected regions

212 Foot-and-mouth disease outbreaks in non-endemic countries can lead to l

213 trasting the ecology of two different recent disease outbreaks in North America caused by West Nile v

214 ns and in mice to evaluate the potential for disease outbreaks in poultry and humans.

215 ian influenza H7N9 viruses have been causing disease outbreaks in poultry and humans.

216 aviridae) associated with high case fatality disease outbreaks in regions of Africa, Europe, and Asia

217 lemented at scale in response to Ebola virus disease outbreaks in rural settings.

218 terinary premises for the early detection of disease outbreaks in small animals.

219 Ebola is a deadly virus that causes frequent disease outbreaks in the human population.

220 s globally, the principal cause of foodborne disease outbreaks in the United States, a key health car

221 T-24) causing most serogroup C meningococcal disease outbreaks in the United States.

222 are of these children, suggesting infectious disease outbreaks in these detainment centers, delays in

223 es comparable to those recently reported for disease outbreaks in wild populations are not sustainabl

224 Understanding the behavior of emerging disease outbreaks in, or ahead of, real-time could help

225 mobility patterns for modeling vector-borne diseases outbreaks in cities.

226 L database that captures metadata useful for disease outbreak investigations, and scripts for downloa

227 h mortality of corals affected suggests this disease outbreak is arguably one of the most lethal ever

228 ncing pathogen samples during a communicable disease outbreak is becoming an increasingly common proc

229 erence of who infected whom in an infectious disease outbreak is critical for the delivery of effecti

230 When a disease outbreak is detected, identifying the contaminat

231 The largest ever Ebola virus disease outbreak is ravaging West Africa.

232 analysis of these studies during infectious disease outbreaks is complicated by statistical, ethical

233 ping, and vaccine matching of FMD virus from disease outbreaks is critical for enabling the implement

234 in the arsenal to prevent and control viral disease outbreaks is disinfection of equipment and surfa

235 nt to which media interest during infectious disease outbreaks is indicative of trends of reported in

236 Optimal intervention for disease outbreaks is often impeded by severe scientific

237 uch relationships during naturally occurring disease outbreaks is rare, and identifying causal links

238 The size of the west African Ebola virus disease outbreak led to the urgent establishment of Ebol

239 can increase the risk of vaccine-preventable disease outbreaks like measles.

240 eef degradation predates coral bleaching and disease outbreaks linked to anthropogenic climate change

241 uman survivor of the 1995 Kikwit Ebola virus disease outbreak maintained circulating antibodies again

242 ure regimes have been implicated in emergent disease outbreaks, making it a critical environmental fa

243 everal Xanthomonas spp. and implications for disease outbreaks, management strategies and breeding fo

244 tegies for containing an emerging infectious disease outbreak must be nonpharmaceutical when drugs or

245 reported in the World Health Organization's Disease Outbreak News from 1996 to 2008.

246 we analyzed the entire WHO public record of Disease Outbreak News reports from 1996 to 2009 to chara

247 For instance, many bacterial plant disease outbreaks occur after periods of high humidity a

248 In 1996, a disease outbreak occurred at a captive breeding facility

249 Zika virus (ZIKV) disease outbreaks occurred in French Polynesia in 2013-2

250 ble faster, more precise responses to future disease outbreaks of bacterial origin, and help to mitig

251 on, Legionnaires' disease continues to cause disease outbreaks of public health significance.

252 Foodborne disease outbreaks of recent years demonstrate that due t

253 o test this approach, we introduce simulated disease outbreaks of varying shapes, magnitudes, and dur

254 Modelling disease outbreaks often involves integrating the wealth

255 ssential for several reasons: (i) infectious disease outbreaks often originate from wild fauna; (ii)

256 etwork by its own spreading dynamics or by a disease outbreak on a contact network, but that the dise

257 s encountered the largest Ebola virus (EBOV) disease outbreak on record, and Sierra Leone is the wors

258 By simulating disease outbreaks on a collection of empirical and synth

259 lly observed systems representing infectious disease outbreaks, online discussions, and software deve

260 In the post-Ebola virus disease outbreak period, vaccination coverage for polio,

261 d of warming and an increasing occurrence of disease outbreaks, posing a significant threat to marine

262 morbidity or mortality risk assessment, (3) disease outbreak prediction and surveillance, and (4) he

263 lue of information methods can be applied to disease outbreak problems such as FMD in order to invest

264 ntroduction of pathogens and discovering new disease outbreaks quickly, and discussing why a plant pa

265 y vaccination may be effective in preventing disease outbreaks, reaching and sustaining high immunisa

266 Infectious disease outbreaks recapitulate biology: they emerge from

267 Our approach is the first tool for disease outbreak reconstruction from genetic data widely

268 rically associated with community-associated disease outbreaks recovered from cultures in both hospit

269 Control of Legionnaires' disease outbreaks relies on rapid ascertainment of descr

270 e method using data from multiple infectious disease outbreaks reported in the United States of Ameri

271 In nature, many foliar bacterial disease outbreaks require high humidity, rain, or storms

272 ning for the Horn of Africa that facilitated disease outbreak response and mitigation activities.

273 nto decision-making processes for infectious disease outbreak response.

274 computational resources to simulate a set of disease outbreak scenarios, tracing billions of stochast

275 associations, suggesting that community-wide disease outbreaks should be more likely to occur when ma

276 lent NDV isolates and those recovered during disease outbreaks since the 1970s are phylogenetically d

277 can be implemented with ease in a filovirus disease outbreak situation.

278 thened, obstacles to the timely reporting of disease outbreaks still exist.

279 Disease outbreaks such as SARS, MERS, Swine Flu, Ebola,

280 isms inform how people respond to widespread disease outbreaks, such as the severe acute respiratory

281 FBDOs reported to CDC Foodborne Disease Outbreak Surveillance System during 2003-2008 wi

282 coral condition might play a larger role in disease outbreaks than is currently thought.

283 limited the 2014 Nigerian Ebola virus (EBOV) disease outbreak to 20 reported cases and 8 fatalities.

284 Compared with pre-Ebola virus disease outbreak trends, significant decreases occurred

285 versity is therefore necessary to understand disease outbreaks under changing environments.

286 Disease outbreaks usually involve sternal wound infectio

287 n level when delivered during an Ebola virus disease outbreak via a ring vaccination strategy.

288 This respiratory disease outbreak was due to multiple pathogens, includin

289 ulation collected before, during and after a disease outbreak was investigated.

290 he 2013-2016 West African Ebola virus (EBOV) disease outbreak was the largest filovirus outbreak to d

291 ch genomic data can help us understand viral disease outbreaks, we aim to provide a resource that wil

292 nd swine are key intermediate hosts of human disease outbreaks, we synthetically resurrected a recomb

293 A key public health question during any disease outbreak when limited vaccine is available is wh

294 ype STEC and accurately identify clusters of disease outbreak when no STEC isolate is available for t

295 ect the need for STI-related research during disease outbreaks where sexual transmission can have a k

296 urately detect and identify pathogens during disease outbreaks, whether they are natural or engineere

297 Ebola virus and Marburg virus cause serious disease outbreaks with high case fatality rates.

298 mportant food-borne pathogen responsible for disease outbreaks worldwide.

299 sporidium parvum are associated with massive disease outbreaks worldwide.

300 hich have demonstrated potential for natural disease outbreaks, yet no licensed vaccines are availabl