A generic population model for the African tick Rhipicephalus appendiculatus

S. E. RANDOLPH; D. J. ROGERS

doi:10.1017/S0031182097001315

Abstract

We present a simulation population model for the African tick Rhipicephalus appendiculatus, based on previous analyses of the mortality factors most closely correlated with observed population changes at 11 sites in equatorial and South Africa. The model incorporates temperature-dependent rates of egg production and development, climate-driven density-independent mortality rates, particularly during the adult-larval stage, and density-dependent regulation of both nymphs and adults. Diapause is also included for tick populations in southern Africa. The model successfully describes both the seasonality and annual range of variation in numbers of each tick stage observed at each of 4 test sites in Uganda, Burundi and South Africa. Sensitivity analysis showed that the final version of the model is robust to 4-fold variation in most parameter values (that were per force based on informed guesses), but is more sensitive to the regression coefficients determining density-dependent interstadial mortality (that were derived from analysis of field data). The model is able to predict the seasonality of ticks from a site in Kenya where a full prior population analysis was not possible because only adults and nymphs had been counted. The model is potentially applicable to other species of ticks, both tropical and temperate, to predict tick abundance and seasonality as risk factors for tick-borne diseases.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Hay, S.I Snow, R.W and Rogers, D.J 1998. From Predicting Mosquito Habitat to Malaria Seasons Using Remotely Sensed Data: Practice, Problems and Perspectives. Parasitology Today, Vol. 14, Issue. 8, p. 306.

Cumming, G.S. 1998. Host preference in African ticks (Acari: Ixodida): a quantitative data set. Bulletin of Entomological Research, Vol. 88, Issue. 4, p. 379.

Randolph, S.E. 1998. Ticks are not Insects: Consequences of Contrasting Vector Biology for Transmission Potential. Parasitology Today, Vol. 14, Issue. 5, p. 186.

Labuda, Milan and Randolph, Sarah E. 1999. Survival strategy of tick-borne encephalitis virus: Cellular basis and environmental determinants. Zentralblatt für Bakteriologie, Vol. 289, Issue. 5-7, p. 513.

Randolph, Sarah 1999. Epidemiological uses of a population model for the tick Rhipicephalus appendiculatus. Tropical Medicine & International Health, Vol. 4, Issue. 9,

Cumming, G.S. 1999. Host distributions do not limit the species ranges of most African ticks (Acari: Ixodida). Bulletin of Entomological Research, Vol. 89, Issue. 4, p. 303.

CHOWN, STEVEN L. and GASTON, KEVIN J. 1999. Exploring links between physiology and ecology at macro‐scales: the role of respiratory metabolism in insects. Biological Reviews, Vol. 74, Issue. 1, p. 87.

Randolph, S.E. 2000. Remote Sensing and Geographical Information Systems in Epidemiology. Vol. 47, Issue. , p. 217.

Cumming, Graeme S. 2000. Using between‐model comparisons to fine‐tune linear models of species ranges. Journal of Biogeography, Vol. 27, Issue. 2, p. 441.

Rogers, D.J. 2000. Remote Sensing and Geographical Information Systems in Epidemiology. Vol. 47, Issue. , p. 129.

Robinson, T.P. 2000. Remote Sensing and Geographical Information Systems in Epidemiology. Vol. 47, Issue. , p. 81.

Estrada-Peña, Agustı́n 2001. Forecasting habitat suitability for ticks and prevention of tick-borne diseases. Veterinary Parasitology, Vol. 98, Issue. 1-3, p. 111.

Randolph, S.E Green, R.M Hoodless, A.N and Peacey, M.F 2002. An empirical quantitative framework for the seasonal population dynamics of the tick Ixodes ricinus. International Journal for Parasitology, Vol. 32, Issue. 8, p. 979.

Cumming, G. S. 2002. COMPARING CLIMATE AND VEGETATION AS LIMITING FACTORS FOR SPECIES RANGES OF AFRICAN TICKS. Ecology, Vol. 83, Issue. 1, p. 255.

Estrada-Peña, Agustin 2002. A simulation model for environmental population densities, survival rates and prevalence of Boophilus decoloratus (Acari: ixodidae) using remotely sensed environmental information. Veterinary Parasitology, Vol. 104, Issue. 1, p. 51.

Rogers, David J. Randolph, Sarah E. Snow, Robert W. and Hay, Simon I. 2002. Satellite imagery in the study and forecast of malaria. Nature, Vol. 415, Issue. 6872, p. 710.

Randolph, Sarah 2002. Quantitative Ecology of Ticks as a Basis for Transmission Models of Tick-Borne Pathogens. Vector-Borne and Zoonotic Diseases, Vol. 2, Issue. 4, p. 209.

Speybroeck, N. Madder, M. Brandt, J. Chungu, H. Van Den Bossche, P. Mbao, V. and Berkvens, D. 2003. Questing activity of Rhipicephalus appendiculatus (Acari: Ixodidae) nymphs: a random process?. Physiological Entomology, Vol. 28, Issue. 4, p. 356.

Rosà, Roberto Pugliese, Andrea Norman, Rachel and Hudson, Peter J. 2003. Thresholds for disease persistence in models for tick-borne infections including non-viraemic transmission, extended feeding and tick aggregation. Journal of Theoretical Biology, Vol. 224, Issue. 3, p. 359.

Olwoch, J. M. Rautenbach, C. J. de W. Erasmus, B. F. N. Engelbrecht, F. A. and Van Jaarsveld, A. S. 2003. Simulating tick distributions over sub‐Saharan Africa: the use of observed and simulated climate surfaces. Journal of Biogeography, Vol. 30, Issue. 8, p. 1221.

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A generic population model for the African tick Rhipicephalus appendiculatus

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A generic population model for the African tick Rhipicephalus appendiculatus

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