TWO-STAGE ADAPTIVE NEGATIVE BINOMIAL GROUP TESTING MODEL FOR ESTIMATING THE PREVALENCE OF A RARE TRAIT
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Date
2024-04
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Egerton University
Abstract
Group testing has been found to be an efficient and economical way of classifying observations
under study as defective or unsatisfactory depending on the test performed as well as estimating
the prevalence rate of a trait in a population. However, groups of appropriate sizes should be
used to realize these benefits. Adaptive schemes have been developed to counter the problems
brought about by inappropriate choice of group sizes. The available adaptive schemes have
been constructed using a binomial sampling model where the number of groups to be tested is
fixed, implying that all groups must be tested before recording the number of successes. But in
some situations, such as the case of infectious diseases, estimates need to be reported as soon
as detection is made, and for that case, the Negative Binomial (NB), sampling model is
preferred. Under NB model, the testing procedure stops immediately when the desired number
of successes, which is fixed prior, is attained. This study constructed a two-stage adaptive NB
group testing model for estimating the prevalence of a rare trait. The adaptation adjusts group
sizes from one stage to the next based on the estimate obtained from the previous stage. The
group size used in each stage was the optimal one that minimizes the variance of the estimate
of the prevalence rate in the previous stages. The maximum likelihood estimation method was
used to find the point estimate of the parameter of the developed model and its properties
investigated. The study further constructed the Wald confidence intervals, and its performance
was investigated using mean interval length. The developed model was compared to the non-
adaptive group testing model existing in the literature using relative mean squared error
(RMSE) and asymptotic relative efficiency (ARE) to identify the best model. R-programming
language version 4.1.2 was used for Monte Carlo simulation and analysis to verify the model.
The use of the two-stage adaptive NB model combined with MLE provided lower and precise
estimates. The comparative analysis highlighted the superiority of the adaptive model over the
non-adaptive model emphasizing the importance of incorporating adaptivity in group testing
procedures. The study highly recommends leveraging these findings to enhance the efficiency
and reliability of group testing methods across diverse applications, including disease screening
and surveillance of viral illnesses such as Covid-19. By incorporating these findings, the
effectiveness of this testing strategies can greatly be improved, leading to more accurate and
timely identification of infections, ultimately contributing to better public health outcomes.