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Title: Sin ttulo de diapositiva


1
Estimation of Death Rates in Apis mellifera
(HymenopteraApidae) Colonies exposed to Varroa
destructor (MesostigmataVarroidae), using a
Recurrence Data Approach
  • Dulce M. Bustamante1, José D. Villa2 and Luis A.
    Escobar1.
  • Department of Experimental Statistics, Louisiana
    State University, Baton Rouge, LA
  • USDA-ARS Honey Bee Breeding, Genetics and
    Physiology Laboratory, Baton Rouge, LA
  • INTRODUCTION
  • Observations of unmanaged or feral honey bee
    colonies established and observed through time
    generate data structures which are not very
    compatible with standard survival analyses
    because colonies are founded by swarms in
    different months. An additional complexity arose
    from the movement of the parasitic mite, Varroa
    destructor, into the area at the end of the third
    year of observations, increasing the potential
    risk to surviving colonies at different points in
    their life span.
  • The present study was conducted to explore a new
    approach to analyze survival data of honey bee
    colonies and to describe the possible effects
    that the appearance of V. destructor had in the
    mortality rates of the colonies.
  • METHODS HONEY BEE COLONIES
  • The field study was conducted in southeastern
    Louisiana. One hundred and four (104) swarms
    were established during nine swarming seasons
    (Spring) from 1990 to 2000.
  • Swarms originated from an undetermined
    combination of feral and managed colonies in East
    Baton Rouge and Iberville parishes. After the
    arrival of parasitic mites an effort was made to
    avoid swarms from colonies artificially selected
    for resistance to V. destructor and most swarms
    were captured in St. Tammany and Tangipahoa
    parishes, in areas with little or no beekeeping.
  • Colonies were monitored regularly to determine
    their status (life or death). Colonies received
    no management and no treatment to control mites
    was applied, trying to emulate feral conditions
    (Figure 1). Observations were recorded until
    September 2004.
  • Using maximum likelihood methods to compare the
    adjustment of one single curve versus two curves
    to the non-parametric estimate, it was determined
    that two HPP described the curve better than a
    single HPP (Likelihood Ratio Test 14.75, 1 df,
    p0.00012) (Figure 4).
  • The inverse of the maximum likelihood parameters
    from the two HPP curves provided the death rates
    of the two discrete sets of colonies.
  • These maximum likelihood parameters can also be
    interpreted as the scale parameters of
    exponential distributions. This implies that the
    inverse value is also the probability that a
    colony will die in the next interval of time.
  • The death rates (or probability of death) for the
    two sets of colonies were
  • - NoEarly Varroa 0.087 deaths per month
    per colony
  • - Late Varroa 0.037 deaths per month per colony
  • DISCUSSION AND CONCLUSIONS
  • Recurrence-data methods provided a satisfactory
    framework to address the problem of staggered
    entries in estimating death rates of honey bee
    colonies and are recommended for similar studies.
  • There was a reduction in the mortality rates of
    the studied colonies five years after the arrival
    of V. destructor from 0.087 to 0.037 deaths per
    month per colony. Other factors can not be ruled
    out and future analysis of this data set should
    investigate the contribution of environmental
    variables in explaining the observed mortality
    rates.
  • The results suggest the possible emergence of
    resistance to V. destructor in honey bee
    populations in the U.S., or the development of
    reduced virulence in the mite populations (Oldroy
    1999 Seeley 2004).

Figure 1. Unmanaged honey bee colony emulating
feral conditions. (Photo by J. Villa)
  • Figure 2. Life times in months of 104 honey bee
    colonies.
  • Each horizontal line represents a colony. The
    beginning of the line is the date when the colony
    was established and the end of the line is the
    date of death or censoring of the colony (time
    zero is March of 1990).
  • The symbol x indicates colonies that died and the
    symbol - correspond to the censored colonies.
  • For instance, the first colony is represented by
    the first horizontal line, it was established in
    March of 1990 and died in February 1993, which
    corresponds to a life time of 35 months.
  • Varroa destructor appeared in the Fall of 1992
    (after month 30).
  • The plot emphasizes the staggered entry of the
    sets of colonies into the study at different
    times.
  • METHODS DATA STRUCTURE AND ITS COMPATIBILITY
    WITH RECURRENCE DATA
  • The data obtained from the experiment were the
    life times (in months) of each of the 104 honey
    bee colonies
  • 97 seven exact life times (start and end time of
    the colony is known)
  • 7 right censored times (colonies that were alive
    at the end of the experiment)
  • The colonies entered the study in a staggered
    manner, with colonies being established from
    swarms in different months and years throughout
    the 10 years of the study (Figure 2).
  • Recurrent events include, for instance,
    recurrence of parasitic infestations in an animal
    after being cured. One can study the
    distribution of time between events and the rate
    at which events occur as a function of time
    (Nelson 1998).
  • Some recurrent events are recorded only in
    observation windows of time with gaps between
    the windows, even though the underlying process
    is continuous over time (Zuo et al. 2004).
  • Observation windows and the gaps between them can
    have random length and there is no requirement
    for the observation windows to have the same
    beginning or ending points for different
    observational units (Zuo et al. 2004), meaning
    they can enter the study in a staggered way.
  • Based on the window structure, the honey bee
    colony data addressed here can be interpreted as
    follows
  • The data set consists of 104 independent units
    (colonies) each unit was observed in a single
    window with
  • random length equal to its life time.
  • For 97 of the units, only one event (death)
    occurred at the end point of the window. The
    other 7
  • Figure 3. Non parametric estimate of the mean
    cumulative number of deaths and parametric fit
    using a Homogeneous Poisson Process.
  • The step like curve is the non parametric
    estimate. Notice that its slope becomes less
    steep after month 91 (March 1997).
  • The dashed line represents the parametric fit.
    It is evident that it is not a very good fit.
  • Figure 4. Parametric fit using a Homogeneous
    Poisson Process for the periods NoEarly (before
    1997) and Late Varroa (after 1997).
  • Compare with Figure 3, and notice the improved
    fit to the non parametric estimate when
    considering these periods separately instead of a
    single fit.
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