For dose–response analysis in quantitative microbial risk assessment (QMRA), the exact beta-Poisson model is a two-parameter mechanistic dose–response model with parameters math formula and math formula, which involves the Kummer confluent hypergeometric function. Evaluation of a hypergeometric function is a computational challenge. Denoting math formula as the probability of infection at a given mean dose d, the widely used dose–response model math formula is an approximate formula for the exact beta-Poisson model. Notwithstanding the required conditions math formula and math formula, issues related to the validity and approximation accuracy of this approximate formula have remained largely ignored in practice, partly because these conditions are too general to provide clear guidance. Consequently, this study proposes a probability measure Pr(0 < r < 1 | math formula, math formula) as a validity measure (r is a random variable that follows a gamma distribution; math formula and math formula are the maximum likelihood estimates of α and β in the approximate model); and the constraint conditions math formula for math formula as a rule of thumb to ensure an accurate approximation (e.g., Pr(0 < r < 1 | math formula, math formula) >0.99) . This validity measure and rule of thumb were validated by application to all the completed beta-Poisson models (related to 85 data sets) from the QMRA community portal (QMRA Wiki). The results showed that the higher the probability Pr(0 < r < 1 | math formula, math formula), the better the approximation. The results further showed that, among the total 85 models examined, 68 models were identified as valid approximate model applications, which all had a near perfect match to the corresponding exact beta-Poisson model dose–response curve.