ライフサイエンスコーパス: population dynamics

1 be doxorubicin uptake and predict subsequent population dynamics.

2 ltiple demographic traits when understanding population dynamics.

3 s both regional continuity and interregional population dynamics.

4 magnitude larger than the area encompassing population dynamics.

5 in our population do not drive the observed population dynamics.

6 ter temperature and breeding density driving population dynamics.

7 n important driver of individual fitness and population dynamics.

8 of doxorubicin therapy shape subsequent cell population dynamics.

9 variance and thus the demographic rates and population dynamics.

10 nutrient availability and density-dependent population dynamics.

11 ss the condition mode when responses reflect population dynamics.

12 he influence of this phenotypic variation on population dynamics.

13 prevent lower-level responses from impacting population dynamics.

14 sic factors, with important implications for population dynamics.

15 on the lizard's survival rates and long-term population dynamics.

16 impacts of insect species that show outbreak population dynamics.

17 d the upholding of phenotypic variation, and population dynamics.

18 s important for our understanding of spatial population dynamics.

19 hing state Markov model to describe the cell population dynamics.

20 raphic rates (e.g. reproduction) and in turn population dynamics.

21 ges in labile characters, life histories and population dynamics.

22 ical systems, which plays important roles in population dynamics.

23 ify the influence of phenotypic variation on population dynamics.

24 iatal resting activity through two different population dynamics.

25 A virus to exhibition swine and study viral population dynamics.

26 methods could provide richer descriptions of population dynamics.

27 expression of life history traits as well as population dynamics.

28 may moderate the impact of predation on prey population dynamics.

29 ctices, and environmental change on elaterid population dynamics.

30 ty depends on understanding these historical population dynamics.

31 ns with their hosts affect soft scale insect population dynamics.

32 cipitation) can have major impacts on animal population dynamics.

33 nificant effects on immediate or longer term population dynamics.

34 sequences of seasonal fitness trade-offs for population dynamics.

35 gate the overall impact of predators on prey population dynamics.

36 entify the fingerprint of fisheries on their population dynamics.

37 ell competition affects stem cell and tissue population dynamics.

38 ey demography, acting together to shape prey population dynamics.

39 ifferences could have had a larger impact on population dynamics.

40 impacts of insect species that show outbreak population dynamics.

41 single neurons and delayed choice-predictive population dynamics.

42 strong regulatory mechanisms and impacts on population dynamics.

43 ulations with varying density dependence and population dynamics.

44 s' influence on deterministic and stochastic population dynamics.

45 an be robustly classified based on their WBC population dynamics.

46 the biologically relevant area encompassing population dynamics.

47 linked to carrying capacity, thus affecting population dynamics.

48 s that do not account explicitly for complex population dynamics.

49 to understanding life-history evolution and population dynamics.

50 equences of these changes for both trait and population dynamics.

51 le migratory variability can play in shaping population dynamics.

52 uggesting that climate was a major driver of population dynamics 30-13 ky ago.

53 s striking consistency in the inferred human population dynamics across different regions of Britain

54 and how demographic parameters contribute to population dynamics across species is largely based on a

55 The model shows promise for predicting population dynamics after multiple disturbance events an

56 sfer, serve as a selection force to modulate population dynamics after such gene transfer has occurre

57 ability of dominant species and asynchronous population dynamics among the coexisting species.

58 ) lymphocytes exhibited greater variation in population dynamics among tissues and cell populations o

59 Population dynamics analysis of the most successful line

60 s revealed additional aspects of minor virus population dynamics and antiviral-resistance mutations.

61 Viruses play important roles in population dynamics and as drivers of evolution in singl

62 e viruses are key drivers of host diversity, population dynamics and biogeochemical cycling and contr

63 nding has implications for genetic dynamics, population dynamics and conservation metrics of these hi

64 tal variability is critical to predator-prey population dynamics and could be exploited in pest-manag

65 Such modifications can impact population dynamics and could lead to changes in life cy

66 th validated theoretical models of Wolbachia population dynamics and demonstrated that this is a viab

67 We propose that transient population dynamics and differences in longevity and beh

68 derstand how phenotypic variation influences population dynamics and discuss in which life histories

69 pacts of these global drivers on N. lapillus population dynamics and dispersal parameters.

70 links between environmental changes, traits, population dynamics and ecological interactions, that un

71 tackle challenging questions related to past population dynamics and evolution of weaning practices i

72 y and reactivity of the relationship between population dynamics and food availability.

73 tive versatility manifests in the collective population dynamics and function of cerebral cortex rema

74 d apply the model to predict M. tuberculosis population dynamics and heterogeneity within granulomas.

75 ded important contributions to the fields of population dynamics and invasion biology.

76 ut the extent to which predators impact prey population dynamics and it is often poorly predicted by

77 ture, is key to understanding and predicting population dynamics and life-history evolution.

78 thways, unintentional release events and the population dynamics and local anthropogenic dispersal th

79 , which produces computer simulations of the population dynamics and major metabolites of microbial c

80 ition site selection is essential for vector population dynamics and malaria epidemiology.

81 uniquely characterized by scale-free ongoing population dynamics and moderate correlations, in line w

82 arine populations is key to predicting local population dynamics and optimizing networks of marine pr

83 for future work investigating the drivers of population dynamics and persistence.

84 n and variation, providing a window into the population dynamics and potential functions of these com

85 ow nonbreeders affect realized and estimated population dynamics and potentially impeding projection

86 nservation efforts in the context of overall population dynamics and provides a framework for doing s

87 ed a unique opportunity to study low-density population dynamics and quantify Allee effects with empi

88 y reflecting differences among lifestyles in population dynamics and spatial distribution.

89 xplore the effect of a defensive symbiont on population dynamics and species extinctions in an experi

90 Population dynamics and species persistence are often me

91 these regimes has important consequences for population dynamics and stability, which depend on the p

92 ination of its constituent components toward population dynamics and stability.

93 the foundation for investigations of complex population dynamics and the ability to examine ecologica

94 igration and have important implications for population dynamics and the conservation of migratory sp

95 ent (IPM) makes decisions using knowledge of population dynamics and threshold insect densities.

96 on can occur quickly enough to influence the population dynamics and thus future selection.

97 The proposed model effectively captures population dynamics and translates well to a predictive

98 ncer therapies, and mathematical modeling of population dynamics and treatment responses can be appli

99 n neuroscience modeling: greater emphasis on population dynamics and, where possible, a move toward d

100 te measured abundances to predict accurately population dynamics, and benchmark our population model'

101 ulations, to investigate the genetic legacy, population dynamics, and tempo of the Indian Ocean slave

102 s the connection between maternal stress and population dynamics, and the importance of understanding

103 type of resources affect the phenotype, the population dynamics, and the susceptibility to predation

104 etween populations, and how these may affect population dynamics are central questions in the field o

105 climate warming on herbivore vital rates and population dynamics are hard to predict, given that the

106 At small population sizes, population dynamics are primarily driven by environment-

107 s for a quantitative understanding of T cell population dynamics, are not clear.

108 ndocrine-related alterations in myeloid cell population dynamics as a key mediator of CTRA transcript

109 te, which may have profound consequences for population dynamics as the climate changes.

110 potential to alter both short- and long-term population dynamics as well as community- and ecosystem-

111 ntially impacted model parameters describing population dynamics, as did temporal environmental varia

112 ic processes, fluid chemistry, and microbial population dynamics at and below the seafloor and increa

113 not embrace the whole range of variation in population dynamics at the small spatiotemporal scale, o

114 entification of likely processes influencing population dynamics at Wexford and among 70 other Greenl

115 MPMs project population dynamics based on the reproduction, survival

116 hastic numerical simulations of naive T cell population dynamics, based on experimental parameters, s

117 ographic processes is an important aspect of population dynamics, but a comprehensive examination of

118 vation is dependent on adequate estimates of population dynamics, but age-specific demographics are g

119 otic factors and species interactions affect population dynamics, but are rarely linked with experime

120 in direct consequences on their fitness and population dynamics, but doing so in a context-dependent

121 ong populations, is a fundamental feature of population dynamics, but many aspects of synchrony remai

122 s critical effects on behaviour, ecology and population dynamics, but the causes of variation in ASRs

123 re likely to have important consequences for population dynamics by amplifying sex-specific differenc

124 plex species could disproportionately affect population dynamics by destabilizing social structure an

125 lable tools to detect the regulation of prey population dynamics by predation are limited, partly bec

126 models have demonstrated that predator-prey population dynamics can depend critically on age (stage)

127 imate-demographic functions makes range-wide population dynamics challenging to predict.

128 From the perspective of classical population dynamics, competition for resources seems to

129 Monitoring bacterial population dynamics could therefore provide an informati

130 Here we use data from the Global Population Dynamics Database to determine the statistica

131 Invasive species may not exhibit different population dynamics despite considerable variation in ab

132 ittle is known about its influence on animal population dynamics, despite the relevance of such infor

133 We explored the genealogical signature of population dynamics detected from both sampling schemes

134 pic plasticity and prediction of longer-term population dynamics difficult.

135 ignificantly, periodicity in host-parasitoid population dynamics disappeared in the High-variance mic

136 d indicates that other factors, such as host population dynamics, drive MARV maintenance in nature.

137 rica, is an ideal region to study historical population dynamics due to its geographic location and d

138 Yet remarkably little is known about human population dynamics during colonization, subsequent expa

139 ons (STAMP) for characterization of pathogen population dynamics during infection.

140 d the identification of intrinsic drivers of population dynamics (e.g. density dependence).

141 iving changes at the community level and the population dynamics (e.g., extinction or colonization) r

142 Thus, invariant ongoing population dynamics emerge from intrinsically unstable a

143 isperse widely is critical for understanding population dynamics, evolution, and biogeography, and fo

144 Unexpectedly, MSN population dynamics exhibited two distinct coherent stat

145 roduction of realistic seasonality in vector population dynamics facilitates gene drive success compa

146 vailing effects make it difficult to predict population dynamics following disturbance events.

147 A viruses have inspired the investigation of population dynamics for these species, and recent data n

148 s possible to model spatially explicit human population dynamics from the pre-LGM at 30 ky ago throug

149 We find that population dynamics generally leads to the coexistence o

150 s, we interpreted them in the context of its population dynamics, growth rate, and light adaptation,

151 sic (density-dependent) mechanisms influence population dynamics has become increasingly urgent in th

152 ibutions of fishing vs. natural processes on population dynamics has been difficult because of the se

153 dividual's perspective, and the influence of population dynamics has been underappreciated.

154 The effects of asymmetric interactions on population dynamics has been widely investigated, but th

155 offspring phenotypes, and thereby affecting population dynamics has not been studied in the well-con

156 disease dynamics and the time scale of host population dynamics, highlights the importance of accoun

157 our store of methods to properly understand population dynamics if we wish to build an evidence base

158 bacteria (AOB) drive nitrification and their population dynamics impact directly on the global nitrog

159 nteraction models are likely to misrepresent population dynamics important for the spread of disease

160 y importance of alternative hosts to plasmid population dynamics in an ecologically relevant environm

161 he same study, we investigated memory B cell population dynamics in blood, bone marrow, and rectal ti

162 manifest as dramatic changes in the state of population dynamics in cerebral cortex.

163 ng efforts have reaffirmed the importance of population dynamics in cultural and linguistic evolution

164 rbance ecology to create a general model for population dynamics in disturbance-prone systems.

165 proof of principle, we tracked the bacterial population dynamics in ectopic syngeneic colorectal tumo

166 served associations between climate and flea population dynamics in India.

167 l Nino Southern Oscillation (ENSO) influence population dynamics in many species, including marine to

168 s investigating the impact of competition on population dynamics in mixed communities in the anode ar

169 Further, our results suggest that neural population dynamics in motor cortex are invariant to the

170 t approach to monitor the native moso bamboo population dynamics in native Chinese fir and evergreen

171 [11C]GV1-57 monitored native OSN population dynamics in rodents, detecting OSN generation

172 ence of unmeasured individual differences on population dynamics in roe deer.

173 making in the sensorimotor system has shown population dynamics in the beta band, corresponding to t

174 s essential for understanding and predicting population dynamics in the face of global change.

175 we report a model of pre- and post-Columbian population dynamics in the Jemez Province.

176 The population dynamics in the native range and invaded rang

177 To better understand microbial growth and population dynamics in the proximal colon, the primary r

178 for histone H3 proteins, characterizes cell population dynamics in the root developmental compartmen

179 whereas knowledge on their distribution and population dynamics in ticks remains meager.

180 The lysis strain exhibits pulsatile population dynamics in vivo, with mean bacterial lumines

181 population of trypanosomes and monitored VSG population dynamics in vivo.

182 perform differently, or experience different population dynamics, in their introduced range compared

183 role of consumers in density-dependent plant population dynamics is a long-standing goal in ecology.

184 Additionally, when the population dynamics is assumed to follow the classic Gen

185 g the relationship of climate with long-term population dynamics is critical for wildlife conservatio

186 erstanding how migratory strategy influences population dynamics is hindered by a lack of predictive

187 ld and domestic ungulates, but its impact on population dynamics is not well understood.

188 distribution, where differences in growth or population dynamics may result in range expansions or co

189 However, the processes governing population dynamics may vary greatly among species.

190 cond time-resolved ARPES (tr-ARPES) show how population dynamics measured using tr-ARPES can be used

191 Our methodology is based upon a population dynamics model of mutation accumulation and s

192 A population dynamics model parameterized by our measureme

193 Using a population dynamics model parameterized with these exper

194 To address this, we fit a Bayesian population dynamics model that includes process and obse

195 ture for C. botulinum Group I type A1 into a population dynamics model, to build the very first compu

196 isting methods require assuming a particular population dynamics model, which is not known a priori.

197 action types without assuming any particular population dynamics model.

198 esence/absence was combined with analyses of population dynamics, modelling and analyses of host (Par

199 ggests the importance of extending classical population dynamics models to include such eco-evolution

200 goals of this study were to investigate how population dynamics models with and without spatial stru

201 and intra- and inter-species interactions in population dynamics models, are largely host-independent

202 haplotype frequency distribution to several population dynamics models, we found that the best fit w

203 Here, we demonstrate that the population dynamics of a long-lived, wide-ranging marine

204 periment we tested the effect of ALAN on the population dynamics of a plant-aphid-parasitoid communit

205 rojected climate change can negatively alter population dynamics of a sentinel alpine species and pro

206 study provides significant insights into the population dynamics of a small mammal at a large geograp

207 In this study, we followed the population dynamics of ammonia oxidizing organisms and r

208 ed effects of native insect herbivory on the population dynamics of an exotic thistle, Cirsium vulgar

209 and mean temperature in February, while the population dynamics of armyworms is significantly relate

210 microbial communities, and specifically the population dynamics of cable bacteria, can also induce s

211 on understanding the factors associated with population dynamics of cereal aphids and armyworms feedi

212 he factors most strongly associated with the population dynamics of cereal aphids are fertilizer inpu

213 how these impacts translate into changes in population dynamics of communities with multiple trophic

214 We investigated the population dynamics of exogenous Lactobacillus plantarum

215 lts showed that the high density and regular population dynamics of FLEs-Hd appeared in female ovarie

216 er explore the function of the symbiont, the population dynamics of FLEs-Hd at each developmental sta

217 ulf, this situation has already occurred and population dynamics of four widespread corals (Acropora

218 We explored the population dynamics of genetically diverse GC responses

219 The role of climate forcing in the population dynamics of infectious diseases has typically

220 Understanding the underlying population dynamics of influenza A viruses in commercial

221 The performance and population dynamics of insect herbivores depend on the n

222 ultiple, often synergistic, stressors on the population dynamics of long-lived species is becoming in

223 uccess could potentially be important to the population dynamics of many organisms.

224 Understanding the population dynamics of megafauna that inhabited the mamm

225 Here, we physically model the population dynamics of microbes that compete for steadil

226 previous models used to analyze and predict population dynamics of microbes.

227 for refuelling during migration, affects the population dynamics of migratory species.

228 We address this question by studying the population dynamics of Mycobacterium tuberculosis within

229 wever, the precise mechanisms regulating the population dynamics of neoblasts remain largely unknown.

230 Here we investigate the population dynamics of Neolithization across Europe usin

231 d by cellular mechanisms that quantifies the population dynamics of neutrophil, lymphocyte, and monoc

232 nown about effects of parasites on long-term population dynamics of non-host species or about whether

233 s in 2012 relates to long-term trends in the population dynamics of pandemic viruses recently introdu

234 The impact of breeder loss on the population dynamics of social species remains poorly und

235 ) to determine strain relatedness and assess population dynamics of Staphylococcus aureus isolates fr

236 The population dynamics of such sequential acquisition of (e

237 Here we present a method of studying the population dynamics of T cells in mice over timescales o

238 evaluate local and global factors affecting population dynamics of the black-throated blue warbler (

239 Population dynamics of the chimpanzees inhabiting Gombe

240 ervations inform a mathematical model of the population dynamics of the gut microbiota.

241 d hence unlikely to contribute to the cyclic population dynamics of the host.

242 y provide an incomplete understanding of the population dynamics of the infection process.

243 We examined the long-term population dynamics of the invasive common wasp, Vespula

244 day field mesocosm experiment to measure the population dynamics of the non-native cladoceran zooplan

245 this review, we describe the topography and population dynamics of the respiratory tract, both in he

246 Several features of the population dynamics of these neurons and their circular

247 We inferred the historical population dynamics of this epidemic for all five gene r

248 e metabolic efficiency, activity levels, and population dynamics of this species, particularly in its

249 pplied to study the within- and between-host population dynamics of viruses.

250 e performance in wild populations, models of population dynamics often focus on mean demographic rate

251 to determine whether they impact micro-algal population dynamics on a global scale.

252 havioral strategies to illuminate effects of population dynamics on risk-taking.

253 cological processes (e.g. growth, selection, population dynamics) or imperfect observation of biologi

254 d for any epistasis between antigens driving population dynamics, or redundancy between functionally

255 microbial consortia act as cartels, whereby population dynamics pins down resource concentrations at

256 ess effect will have important influences on population dynamics, population age structure, and the e

257 609 animal populations after accounting for population dynamics (productivity, density dependence, a

258 However, many models of population dynamics provide no understanding of the infl

259 s; intrinsic and extrinsic factors affecting population dynamics; provided insights into senescence a

260 tal stochasticity is an important concept in population dynamics, providing a quantitative model of t

261 augments the decoder by incorporating neural population dynamics remembered from an earlier point in

262 Examining climatic effects on wild animal population dynamics requires ability to trap, observe or

263 endocrine disrupting compounds (EDCs) affect population dynamics requires tracking males and females

264 teins homeostasis are coupled with realistic population dynamics simulations.

265 However, a gap exists for data on population dynamics spanning the rich diversity of the a

266 ange incorporate shifting ecological niches, population dynamics, species interactions, spatially exp

267 treatment efficacy has a clear impact on the population dynamics: sufficient drug pressure bears a cl

268 tion of such floods may be more important to population dynamics than mean measures of sea level.

269 tive pressure with phenotype matters more to population dynamics than the strength of this selection.

270 sequencing for surveillance of pneumococcal population dynamics that could give a prospect on the co

271 hosts and, consequently, may influence host population dynamics that may, in turn, feed back to path

272 g inter-specific variation in the drivers of population dynamics that ultimately scale up to determin

273 how that the coupling between ecological and population dynamics through quorum sensing can induce ph

274 ntitatively hydrological drivers to distinct population dynamics through specific density feedbacks,

275 role of CD8(+) cells in viral evolution and population dynamics throughout the duration of infection

276 l differences impacted parameters describing population dynamics to a much smaller extent once indivi

277 ta patchiness has challenged efforts to link population dynamics to key drivers.

278 re we use evolutionary game theory and multi-population dynamics to model the coevolution of social b

279 sitivity of ecosystem productivity and plant population dynamics to water balance and long-lasting ef

280 stimulation, adaptation tunes the collective population dynamics towards a special regime with scale-

281 Our framework is important for understanding population dynamics under a changing climate and has dir

282 oral scales, with potential implications for population dynamics under climate warming.

283 a statistical artifact and not dependent on population dynamics under conditions that we specify exa

284 results emphasize fundamental differences in population dynamics under different assumptions on cell

285 sent a mathematical model of intrahost viral population dynamics under the condition of a complex CR

286 mate can have direct and indirect effects on population dynamics via changes in resource competition

287 em and that the virus' effect on the overall population dynamics was negligible when the three specie

288 No evidence of cyclic population dynamics was observed.

289 y on offspring stress axis, reproduction and population dynamics were studied in root voles (Microtus

290 M) levels, offspring reproduction traits and population dynamics were tested following repeated live-

291 s are maintained requires knowledge of their population dynamics, which are typically quantified over

292 mutant is an important measure of stochastic population dynamics, widely studied in ecology and evolu

293 at measurement of genomically defined clonal population dynamics will be highly informative for funct

294 of response typically assume that effects on population dynamics will occur, perhaps fallaciously.

295 xts where IPMs could strengthen inference of population dynamics, with examples of host species rangi

296 on stochastic Markovian models of bacterial population dynamics within and among organs.

297 We develop a rate equation to describe the population dynamics within territorial competition.

298 turbation of communities can drive bacterial population dynamics within the gut, and it reveals a new

299 tributed to cortico-basal ganglia loops, yet population dynamics within these loops during resting an

300 in a pool of billions can strongly influence population dynamics, yet their survival is highly depend