Long‐Distance Dispersal and Accelerating Waves of Disease: Empirical Relationships

Classic approaches to modeling biological invasions predict a “traveling wave” of constant velocity determined by the invading organism’s reproductive capacity, generation time, and dispersal ability. Traveling wave models may not apply, however, for organisms that exhibit long‐distance dispersal. Here we use simple empirical relationships for accelerating waves, based on inverse power law dispersal, and apply them to diseases caused by pathogens that are wind dispersed or vectored by birds: the within‐season spread of a plant disease at spatial scales of <100 m in experimental plots, historical plant disease epidemics at the continental scale, the unexpectedly rapid spread of West Nile virus across North America, and the transcontinental spread of avian influenza strain H5N1 in Eurasia and Africa. In all cases, the position of the epidemic front advanced exponentially with time, and epidemic velocity increased linearly with distance; regression slopes varied over a relatively narrow range among data sets. Estimates of the inverse power law exponent for dispersal that would be required to attain the rates of disease spread observed in the field also varied relatively little (1.74–2.36), despite more than a fivefold range of spatial scale among the data sets.

[1]  D. Aylor,et al.  SPREAD OF PLANT DISEASE ON A CONTINENTAL SCALE: ROLE OF AERIAL DISPERSAL OF PATHOGENS , 2003 .

[2]  Denis Mollison,et al.  Spatial Contact Models for Ecological and Epidemic Spread , 1977 .

[3]  J. G. Skellam Random dispersal in theoretical populations , 1951, Biometrika.

[4]  A. Peterson,et al.  Migratory birds modeled as critical transport agents for West Nile Virus in North America. , 2003, Vector borne and zoonotic diseases.

[5]  A. Glaser West Nile virus and North America: an unfolding story. , 2004, Revue scientifique et technique.

[6]  F. Ferrandino,et al.  Dispersive epidemic waves. I: Focus expansion within a linear planting , 1993 .

[7]  F. Chapin,et al.  EFFECTS OF BIODIVERSITY ON ECOSYSTEM FUNCTIONING: A CONSENSUS OF CURRENT KNOWLEDGE , 2005 .

[8]  Andrew M. Liebhold,et al.  Allee effects and pulsed invasion by the gypsy moth , 2006, Nature.

[9]  P. Driessche,et al.  Dispersal data and the spread of invading organisms. , 1996 .

[10]  Janneke HilleRisLambers,et al.  ESTIMATING POPULATION SPREAD: WHAT CAN WE FORECAST AND HOW WELL? , 2003 .

[11]  C. Mundt,et al.  Velocity of spread of wheat stripe rust epidemics. , 2005, Phytopathology.

[12]  G. Viswanathan,et al.  Lévy flights and superdiffusion in the context of biological encounters and random searches , 2008 .

[13]  J. Rappole,et al.  Migratory birds and spread of West Nile virus in the Western Hemisphere. , 2000, Emerging infectious diseases.

[14]  Stephen R. Baillie,et al.  Modeling large-scale dispersal distances , 2002 .

[15]  B. Bolker,et al.  COMPARATIVE SEED SHADOWS OF BIRD‐, MONKEY‐, AND WIND‐DISPERSED TREES , 2005 .

[16]  H. Artsob,et al.  West Nile Virus in the New World: Trends in the Spread and Proliferation of West Nile Virus in the Western Hemisphere , 2009, Zoonoses and public health.

[17]  F. Ferrandino Length scale of disease spread : Fact or artifact of experimental geometry , 1996 .

[18]  James S. Clark,et al.  Invasion by Extremes: Population Spread with Variation in Dispersal and Reproduction , 2001, The American Naturalist.

[19]  J. Metz,et al.  Focus expansion in plant disease. 1. The constant rate of focus expansion. , 1988 .

[20]  S. Soubeyrand,et al.  Autoinfection in wheat leaf rust epidemics. , 2008, The New phytologist.

[21]  P. H. Gregory Interpreting Plant Disease Dispersal Gradients , 1968 .

[22]  H. Scherm On the velocity of epidemic waves in model plant disease epidemics , 1996 .

[23]  David A. Elston,et al.  Spatial asynchrony and periodic travelling waves in cyclic populations of field voles , 1998, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[24]  F van den Bosch,et al.  On the spread of plant disease: a theory on foci. , 1994, Annual review of phytopathology.

[25]  P. Daszak,et al.  Predicting the global spread of H5N1 avian influenza , 2006, Proceedings of the National Academy of Sciences.

[26]  Hal Caswell,et al.  DEMOGRAPHY AND DISPERSAL: CALCULATION AND SENSITIVITY ANALYSIS OF INVASION SPEED FOR STRUCTURED POPULATIONS , 2000 .

[27]  Charles Elmer Owens,et al.  Principles of plant pathology , 2022 .

[28]  J. McDonald,et al.  Radial dilution model for the distribution of toxaphene in the United States and Canada on the basis of measured concentrations in tree bark. , 2003, Environmental science & technology.

[29]  M. Shaw,et al.  Assembling spatially explicit landscape models of pollen and spore dispersal by wind for risk assessment , 2006, Proceedings of the Royal Society B: Biological Sciences.

[30]  Mark A. Miller,et al.  Synchrony, Waves, and Spatial Hierarchies in the Spread of Influenza , 2006, Science.

[31]  J. Harper Population Biology of Plants , 1979 .

[32]  Andrew M. Liebhold,et al.  Waves of Larch Budmoth Outbreaks in the European Alps , 2002, Science.

[33]  Laurence V. Madden,et al.  The study of plant disease epidemics , 2007 .

[34]  T. Gisiger Scale invariance in biology: coincidence or footprint of a universal mechanism? , 2001, Biological reviews of the Cambridge Philosophical Society.

[35]  Van der Plank Host-pathogen interactions in plant disease , 1982 .

[36]  W. Fry,et al.  Models for the spread of disease: model description , 1983 .

[37]  T. Geisel,et al.  The scaling laws of human travel , 2006, Nature.

[38]  S. Pimm,et al.  Dispersal of Amazonian birds in continuous and fragmented forest. , 2007, Ecology letters.

[39]  O. Bjørnstad,et al.  Travelling waves and spatial hierarchies in measles epidemics , 2001, Nature.

[40]  J. Schneider,et al.  Epidemiology of cercospora leaf spot on sugar beet: modeling disease dynamics within and between individual plants. , 2007, Phytopathology.

[41]  Bingtuan Li,et al.  Spreading speed and linear determinacy for two-species competition models , 2002, Journal of mathematical biology.

[42]  T. Laman Ficus seed shadows in a Bornean rain forest , 1996, Oecologia.

[43]  Caz M Taylor,et al.  The spatial spread of invasions: new developments in theory and evidence , 2004 .

[44]  R. Irizarry,et al.  Travelling waves in the occurrence of dengue haemorrhagic fever in Thailand , 2004, Nature.

[45]  P. Waggoner The Aerial Dispersal of the Pathogens of Plant Disease , 1983 .

[46]  P. Bourke Emergence of Potato Blight, 1843–46 , 1964, Nature.

[47]  F. van den Bosch,et al.  Spread of organisms: can travelling and dispersive waves be distinguished? , 2000 .

[48]  S. Savary,et al.  An epidemiological simulation model with three scales of spatial hierarchy. , 2004, Phytopathology.

[49]  J. Meece,et al.  Birds, migration and emerging zoonoses: west nile virus, lyme disease, influenza A and enteropathogens. , 2003, Clinical medicine & research.

[50]  C. Mundt,et al.  The effects of dispersal gradient and pathogen life cycle components on epidemic velocity in computer simulations. , 2005, Phytopathology.

[51]  C. Mundt,et al.  Effect of plot geometry on epidemic velocity of wheat yellow rust , 2009 .