The objectives of this dissertation is to apply the GPQ approach to constructing the upper confidence limit of the linearized criteria based on second moments for evaluation of the in vitro bioequivalence, heritability testing and biosimilar drug product. Some locally acting products are not intended to be absorbed into the bloodstream. The in vitro bioequivalence studies based on machinery experiments are suggested to measure these products whether the two drug products provide the same therapeutic effect (FDA, 2003). However, the linearized criterion recommended in the draft FDA guidance does not take in consideration different sources of variation. Therefore, we apply the modified large sample (MLS) and generalized pivotal quantities (GPQ) methods to derive the (1-α)100% upper confidence limit for the linearized criterion for evaluation of in vitro bioequivalence with consideration of different sources of variation under the two-stage nested random-effect model. The heritability is defined as the ratio of additive genetic variance to phenotype variance. The hypothesis of interest is to evaluate whether the ratio is greater than some pre-specified value. As results, the same methodology for evaluation of in vitro bioequivalence can be used for assessment of heritability. Due to some fundamental differences between small molecule generics and large molecule biological products, the standard methods for bioequivalence assessment of small molecule drug products cannot be directly applied to assessing biosimilarity of biosimilar products. We proposed to assess biosimilarity by constructing a (1-α)100% upper confidence bound for the Individual bioequivalence (IBE) criterion based on the method of GPQ under a 2×3 extra-reference crossover design. Simulation studies were conducted to evaluate the performance of these proposed methods in terms of size and power under various scenarios. Numerical examples illustrate the application of in vitro bioequivalence, nested random-effect model, modified large sample method proposed methods.