ライフサイエンスコーパス: disease transmission

1 tion and dispersal are considered central to disease transmission.

2 NPs and other factors controlling infectious disease transmission.

3 blood meal; if there is no bite, there is no disease transmission.

4 eractions and develop interventions to block disease transmission.

5 oice, parental care, territoriality and even disease transmission.

6 t effective route of between-farm infectious disease transmission.

7 gs have impact on our current concept of CWD disease transmission.

8 problems, such as antibiotic resistance and disease transmission.

9 by social structure such as information and disease transmission.

10 mally the limited information into models of disease transmission.

11 hite blood cells (WBC) resulted in efficient disease transmission.

12 s to generalizable scientific insights about disease transmission.

13 in species interaction and so a lowering of disease transmission.

14 he tsetse vector is being explored to reduce disease transmission.

15 hole blood has an apparent 100% efficacy for disease transmission.

16 cted a multistate investigation to interrupt disease transmission.

17 rtunities to reduce mosquito populations and disease transmission.

18 to reduce the tsetse's vector competence and disease transmission.

19 sources have provided new means of studying disease transmission.

20 the population-scale dynamics of infectious disease transmission.

21 f environmental and physiological drivers of disease transmission.

22 ective treatment and subsequent reduction in disease transmission.

23 to their hosts, and are thus responsible for disease transmission.

24 roorganisms in streams enables long-distance disease transmission.

25 ble approach toward understanding infectious disease transmission.

26 host protein, PrP(C), plays a major role in disease transmission.

27 ome infections by changing the landscape for disease transmission.

28 r bioaerosols in order to reduce the risk of disease transmission.

29 -infected people as a new risk of increasing disease transmission.

30 addition of these glycans may play a role in disease transmission.

31 d therapeutic intervention and prevention of disease transmission.

32 the relative roles of badgers and cattle in disease transmission.

33 ariation by linking multiple host species to disease transmission.

34 against higher morbidity and a real risk of disease transmission.

35 matic infections may play a critical role in disease transmission.

36 in order to mitigate the risk of human prion disease transmission.

37 evaluations for donors at increased risk for disease transmission.

38 s of pandemics, particularly animal-to-human disease transmission.

39 or climate change to have a marked impact on disease transmission.

40 , particularly those that involve infectious disease transmission.

41 ycle, ensuring both infection chronicity and disease transmission.

42 r secretory tissues is necessary for natural disease transmission.

43 erica, including pollination, herbivory, and disease transmission.

44 understanding of how floral traits influence disease transmission.

45 his host trafficking factor in microsporidia disease transmission.

46 dynamics affect local patterns of diarrheal disease transmission.

47 hes, and identified potential "hotspots" for disease transmission.

48 they wish to screen based on the dynamics of disease transmission.

49 e potential to improve cure rates and reduce disease transmission.

50 the fecal-oral route being a common mode of disease transmission.

51 suggest that climate affects mosquito-borne disease transmission.

52 of current and future temperature regimes on disease transmission.

53 linking resistance selection with changes in disease transmission.

54 estock, and pets from pest insect attack and disease transmission.

55 lar aggregates believed to play key roles in disease transmission.

56 vironmental change will increase or decrease disease transmission.

57 om the development of mathematical models of disease transmission.

58 of vectorial capacity and the likelihood of disease transmission.

59 pulation mixing, gene flow, and pathogen and disease transmission.

60 petitors can reduce vector density and hence disease transmission.

61 c technologies are essential for controlling disease transmission.

62 ounting for rainfall as a driver of enhanced disease transmission.

63 ito control and prevention of mosquito-borne disease transmission.

64 ble on the incidence of allograft-associated disease transmission.

65 arries some, largely unquantifiable, risk of disease transmission.

66 vity that are likely to contribute to facile disease transmission.

67 odiversity could either increase or decrease disease transmission.

68 f the social network relevant for infectious disease transmission.

69 ial data to interrupt and control infectious disease transmission.

70 that biodiversity loss frequently increases disease transmission.

71 ctions suitable for modelling mosquito-borne disease transmission.

72 e of the possible approaches for controlling disease transmission.

73 to intercohort interactions, leading to more disease transmission.

74 ty in secreta is a crucial concern for prion disease transmission.

75 spersal has a particularly important role in disease transmission.

76 s implemented containment measures to reduce disease transmission.

77 del the duration of travel in the context of disease transmission.

78 adult behaviors to influence mosquito-borne disease transmission.

79 a or viruses during infection and involve in disease transmission.

80 creasingly considered to be a likely mode of disease transmission.

81 particularly with respect to mosquito-borne disease transmission.

82 r distribution, and socioeconomic factors on disease transmission.

83 e in demand for facemasks to protect against disease transmission.

84 ons and do not reflect the true intensity of disease transmission.

85 to understand the dynamics of mosquito-borne-disease transmission.

86 the hosts' reproductive organs to facilitate disease transmission.

87 ronmental Salmonella in ways that can affect disease transmission.

88 the need for alternative methods to prevent disease transmission.

89 imely public health interventions to prevent disease transmission.

90 a in order to evaluate intra- and interclass disease transmission.

91 prevent and control MERS-CoV or new emerging disease transmission.

92 rgans per year, despite the very low risk of disease transmission.

93 r, is commonly used to understand infectious diseases transmission.

94 berculosis, the major cause of mortality and disease transmission(1,2).

95 erations and Safety Committee, the OPTN/UNOS Disease Transmission Advisory Committee (DTAC) and the c

96 The Ad Hoc Disease Transmission Advisory Committee (DTAC) reviewed

97 The Disease Transmission Advisory Committee (DTAC) was creat

98 The Organ Procurement Transplant Network Disease Transmission Advisory Committee (DTAC), a multid

99 high vaccination rates can potentially halt disease transmission altogether.

100 is discussed in relation to short coat hair, disease transmission and blood loss.

101 We analyse two models describing disease transmission and control on regular and small-wo

102 levance of these applications for infectious disease transmission and control, and potential sources

103 igm shift in our understanding of infectious disease transmission and control.

104 play an important role in endemic diarrheal disease transmission and could be an important focus for

105 equate treatment leads to worsening disease, disease transmission and drug resistance.

106 ogen not only provide valuable insights into disease transmission and dynamics but can also guide man

107 itical to understanding the linkages between disease transmission and environmental factors.

108 mportant for identifying the main sources of disease transmission and evaluating the risk of drug-res

109 understanding the role of prion shedding in disease transmission and for diagnosis.

110 for the risk assessment of blood-borne prion disease transmission and for refining the target perform

111 for the risk assessment of blood-borne prion disease transmission and for refining the target perform

112 red from mobile phone data are predictive of disease transmission and improve significantly on standa

113 is nowadays important for the prevention of disease transmission and in the future - hopefully - for

114 ased on a parsimonious mathematical model of disease transmission and only requires data collected th

115 Disease transmission and outbreak intensity, measured as

116 ckness parasite, Trypanosoma brucei, impacts disease transmission and pathogenesis.

117 ypotheses on the influence of temperature on disease transmission and pathogenicity.

118 ental reservoirs are important to infectious disease transmission and persistence, but empirical anal

119 mechanisms accounting for the differences in disease transmission and phenotype between affected fema

120 s made identifying the mechanisms underlying disease transmission and progression extremely difficult

121 osure of health care and recovery teams, (5) disease transmission and propagation, and (6) hospital r

122 l surveillance can be a sensitive measure of disease transmission and provide a more objective testin

123 ntact transmission route in some respiratory disease transmission and providing data for risk analysi

124 lts with interaction-based network models of disease transmission and show that superspreading, when

125 ate change is already affecting vector-borne disease transmission and spread, and its impacts are lik

126 ass gatherings, which may act as hotspots of disease transmission and spread.

127 From the perspectives of disease transmission and sterility maintenance, the worl

128 young children are of primary importance in disease transmission and that the initial postvaccine pe

129 to review and classify reports of potential disease transmission and use this information to inform

130 Differences between disease transmission and waterfowl migration directions

131 graphs imposing a local structure to allowed disease transmissions and (2) by fitting the model to th

132 h (for example, in the detection of possible disease transmission), and as part of divide-and-conquer

133 ability, "imported" infections, asymptomatic disease transmission, and age-specific adherence to soci

134 ct the probability of respiratory infectious disease transmission, and also help explain the existenc

135 ionary time, due to chance, changes in local disease transmission, and parasite population structurin

136 rces required for food security, patterns of disease transmission, and processes of carbon sequestrat

137 acts sporulation, a key step in C. difficile disease transmission, and these results are consistently

138 Snail abundance fosters disease transmission, and thus the dynamics of snail pop

139 ment include donor site morbidity, potential disease transmission, and variable graft quality.

140 Contact patterns play a key role in disease transmission, and variation in contacts during t

141 research that can use the pediatric model of disease, transmission, and immunity to develop preventiv

142 esults suggest that anthropogenic effects on disease transmission are complex, and highlight the need

143 f the complex interplay of factors affecting disease transmission are needed to assist with efforts a

144 well as their direct effect on vector-borne disease transmission are needed to evaluate its potentia

145 r, the aphid-virus interactions required for disease transmission are poorly understood.

146 ary hosts and vectors, with implications for disease transmission as well as ecology.

147 a vaccination programmes result in continued disease transmission, as evidenced by recent large outbr

148 imulations of susceptible-infected-recovered disease transmission, as well as traditional non-network

149 lity to ascertain culpability for infectious disease transmission at a nearly individual level could

150 cape factors, as well as forces facilitating disease transmission at fine scales.

151 Wildlife disease transmission, at a local scale, can occur from i

152 data in settings with high, medium, and low disease transmission based on clinical disease.

153 reduce some of the potential for contact and disease transmission between badgers and cattle.

154 es that influence diverse ecology, including disease transmission between conspecifics and courtship

155 her global warming will increase or decrease disease transmission between individuals remains far fro

156 Here we develop a model for vector-borne disease transmission between mosquitoes and humans in a

157 Disease transmission between these two species is bidire

158 Cross-species disease transmission between wildlife, domestic animals

159 sting a novel approach to control infectious disease transmission by controlling mosquito behavior.

160 ng how host immune defenses indirectly alter disease transmission by influencing vector behavior has

161 y, development of novel strategies to reduce disease transmission by targeting these pathogens in the

162 n of the role of individual heterogeneity in disease transmission can contribute further in this rega

163 ue highlight how differences in the route of disease transmission can enhance the lethality of an alr

164 e is stronger, since we assume that enhanced disease transmission can only be achieved at the cost of

165 d out of jail and sexual contacts (including disease transmission) can provide useful information.

166 ication of natural stochastic differences in disease transmission, can give rise to persistent oscill

167 tus of the host can have profound effects on disease transmission, changing host susceptibility and i

168 mics and the development of novel vector and disease transmission control strategies, but also will e

169 within populations, thus directly affecting disease transmission cycles.

170 d meal, a key event in both reproduction and disease transmission cycles.

171 The bottleneck governing infectious disease transmission describes the size of the pathogen

172 hropod-vertebrate interactions and potential disease transmission during the Mesozoic.

173 st parasites are important for understanding disease transmission dynamics and for the development of

174 of individual variation of infection load on disease transmission dynamics and how this influences th

175 illance systems tailored to setting-specific disease transmission dynamics and surveillance needs, an

176 Linkage analysis is useful in investigating disease transmission dynamics and the effect of interven

177 Understanding disease transmission dynamics in multihost parasite syst

178 The high-resolution view of infectious disease transmission dynamics offered by analyzing whole

179 Host extinction can alter disease transmission dynamics, influence parasite extinc

180 systematically evaluate their effects on the disease transmission dynamics.

181 more likely to have contact, which may drive disease transmission dynamics.

182 cination may reduce pathogen load, affecting disease transmission dynamics.

183 pact of different intervention strategies on disease transmission dynamics.

184 he thermostability of PrP(Sc) aggregates and disease transmission efficiency makes inconsistent the p

185 Establishment of a donation service area disease transmission evaluation service is a valuable pr

186 iewed the records of potential donor-derived disease transmission events (PDDTE) to describe donor ch

187 g dynamic feedbacks involving the ecology of disease transmission, evolutionary processes, and their

188 ative perspective on plague's ecology (i.e., disease transmission exacerbated by alternative hosts) a

189 he role of ventilation, aerosol transport in disease transmission for humans and other animals, and y

190 thogens, originate from animals, and ongoing disease transmission from animals to people presents a s

191 egies to reduce both the biting nuisance and disease transmission from bed bugs.

192 o assessment of whether masks could decrease disease transmission from mask wearers to others.

193 ta in these contaminants and (4) the risk of disease transmission from patients to dental healthcare

194 tter, as an efficacious measure to interrupt disease transmission from uncontrolled spills in Ebola o

195 In Venezuela, active Chagas disease transmission has been reported, with seroprevale

196 importance of the environment in infectious disease transmission has grown, so too has interest in p

197 The significant risk of disease transmission has selected for effective immune-d

198 he dynamics of within- and between-community disease transmission have distinct components but are al

199 anistic hypotheses about airborne infectious disease transmission have traditionally emphasized the r

200 istically modelling individual-to-individual disease transmission in a landscape with heterogeneous p

201 ormed experimental studies of foot-and-mouth disease transmission in cattle and estimated this fracti

202 must be implemented to minimize the risk of disease transmission in dialysis facilities, including e

203 lication of social network analysis to study disease transmission in healthcare settings.

204 This increases the risk of disease transmission in highly vaccinated populations.

205 n effect with a general trait-based model of disease transmission in multi-host communities.

206 To examine the effects of temperature on disease transmission in the field, we manipulated baculo

207 e present a mathematical model of infectious disease transmission in which people can engage in publi

208 e the dynamics of post-disaster vector-borne disease transmission, in the context of conducive/favour

209 pares to other treatment options relative to disease transmission, including its influence on antibio

210 l incorporates an SIS compartmental model of disease transmission into a game theoretic model of stra

211 To prevent disease transmission into commercial pig herds, it is th

212 es (MRT) circumventing mother-to-child mtDNA disease transmission involve replacement of oocyte mater

213 However, disease transmission involves complex nonlinear interact

214 o accept a kidney labeled increased risk for disease transmission (IRD) accept a low risk of window p

215 Endemic disease transmission is an important ecological process

216 Infectious disease transmission is an inherently spatial process in

217 , particularly in those attending CCCs where disease transmission is common.

218 ironmental heterogeneities involved in local disease transmission is crucial to capturing the spatial

219 When infectious disease transmission is density-dependent, the risk of i

220 Disease transmission is difficult to prevent and outbrea

221 Identifying the major sources of risk in disease transmission is key to designing effective contr

222 c virus genomes, yet evidence for waterborne disease transmission is lacking.

223 The interplay between civil unrest and disease transmission is not well understood.

224 A major concern in prion disease transmission is the spread of the disease agent

225 t structure, a critical driver of infectious disease transmission, is not completely understood and c

226 ing, and transfer, and inherent freedom from disease transmission, make it a promising substrate for

227 'i Plateau suggest that predicted changes in disease transmission may be occurring.

228 e role of mental health in the prevention of disease transmission may help fight continuing and futur

229 hosts) has transformed our understanding of disease transmission mechanisms and capacity to predict

230 an epidemic by employing an individual-based disease transmission model and a coalescent process taki

231 inland China, we use a global metapopulation disease transmission model to project the impact of trav

232 pare two movement models coupled to the same disease transmission model using network analyses.

233 Here we introduce an SIR-type multi-strain disease transmission model with perfect cross immunity w

234 ad, which we demonstrated using a stochastic disease transmission model.

235 A key feature for disease transmission modeling and vector control plannin

236 analysis, economic analysis, statistical and disease transmission modelling - we aimed to explore the

237 e conclude that movement models coupled with disease transmission models can affect disease transmiss

238 Environmentally mediated infectious disease transmission models provide a mechanistic approa

239 These results should be combined with disease transmission models to predict the impact of cha

240 ailed movement models have been coupled with disease transmission models.

241 Where genetic change and disease transmission occur on comparable timescales addi

242 lindness, anaphylactic reaction, or terminal disease transmission occurred.

243 for effective treatment and interruption of disease transmission of tuberculosis (TB).

244 Infectious disease transmission often depends on the contact struct

245 Vaccination dramatically disrupts disease transmission on a contact network, and indeed, h

246 We present a model of disease transmission on a regular and small world networ

247 It is unclear how this may affect disease transmission or affect other efforts to control

248 in reproductive mode associated with either disease transmission or hybridization.

249 ng mosquitoes with individuals refractory to disease transmission, or bringing about population suppr

250 ens themselves but also the immune response, disease transmission, or even just the symptoms.

251 ber Rt is important for detecting changes in disease transmission over time.

252 roving statistical methodologies to estimate disease transmission parameters from these data.

253 mic in Asia, with live bird trade as a major disease transmission pathway.

254 ates empirically that small perturbations in disease transmission patterns can fundamentally alter th

255 capture early reports of unknown infectious disease transmission prior to official laboratory confir

256 which explore vector population genetics and disease transmission probabilities and show that using e

257 show that it is possible to characterize the disease transmission process under these conditions.

258 the host reproduction rate, or the baseline disease transmission rate, is reduced, and the parasite

259 These new Wolbachia strains may be affecting disease transmission rates of infected mosquito species,

260 nd services, making them a natural basis for disease transmission rates over distance.

261 equence of this aggregation can be increased disease transmission rates.

262 pendent on effective vector control reducing disease transmission rates.

263 on have a significant impact on vector-borne disease transmission, resulting in more severe outbreaks

264 with disease transmission models can affect disease transmission results and should be carefully con

265 have been no comprehensive studies to assess disease transmission risks between domestic cats and for

266 HCV landscape in Spain's prisons considering disease transmission, screening, treatment, and prison-c

267 Past patterns of infectious disease transmission set the stage on which modern epide

268 d to correlate model simulation results with disease transmission simulations.

269 period parameter have a non-linear effect on disease transmission, so a greater understanding of the

270 o a lack of knowledge over the mechanisms of disease transmission; some strains of TSE are able to cr

271 ng our ability to understand high-resolution disease transmission, sometimes even down to the host-to

272 of bacterial strain diversity and infectious disease transmission studies largely assume a dominant,

273 ich also takes into account other drivers of disease transmission such as rainfall, is applied to the

274 ltiple infectious disease traits influencing disease transmission, such as the frequently modeled pro

275 impact physiological mechanisms involved in disease transmission, suggesting its potential as a new

276 athematical model was adapted for infectious disease transmission that estimated a distribution for o

277 ission model of HIV and sexually transmitted disease transmission that was parameterised and fitted t

278 aches ignore a crucial feature of infectious disease transmission-that future cases are intrinsically

279 . difficile spore formation is essential for disease transmission, the regulatory pathways that contr

280 tensively studied in the context of epidemic disease transmission, the role of gatherings in incidenc

281 in infectivity substantially contributes to disease transmission, then breeding designs which explic

282 can be induced by a prion-like mechanism of disease transmission through propagation of protein misf

283 tor of infectivity in terms of prevention of disease transmission through selective isolation policy

284 l contact networks and for the simulation of disease transmission through such networks.

285 ance systems to assess and analyze risks for disease transmission through the transfer of organs, tis

286 d data have been proven useful for inferring disease transmission to a more refined level than previo

287 disposal of feces by one household prevents disease transmission to households nearby.

288 recognize blood is the basis of vector-borne disease transmission to millions of people worldwide.

289 ecently used for the modelling of infectious disease transmission to model evolutionary game dynamics

290 (Tg) mice expressing cognate PrP(C) Although disease transmission to only a subset of infected TgEq i

291 -like system restores oocyst development and disease transmission to rodent hosts.

292 weak colonies facilitate mite dispersal and disease transmission to stronger and healthier colonies.

293 to examine how increased temperatures affect disease transmission using the crop-defoliating pest, th

294 Disease transmission was concentrated along rivers in th

295 Remarkably, disease transmission was effective when infected mice we

296 ay play an important role in climate change, disease transmission, water and soil contaminants, and g

297 ng a modified Wells-Riley model for airborne disease transmission, we estimated the risk of tuberculo

298 ch we present allows the study of infectious disease transmission when data linking cases to each oth

299 V infection, it is unlikely that subclinical disease transmission will occur.

300 ncorporating contact patterns and estimating disease transmission within and across groups.