Wide-bandgap semiconductor microcavities have attracted much attention in the research field of strong light-matter interaction in recent years owing to their potential to enhance and control the interaction between excitons and photons, which leads to cavity polaritons. This half matter-half light quasi-particle is characterized by the nature of Bose particles, including a very small in-plane effective mass and the lack of Pauli exclusion principle, resulting in the possible realization of room-temperature Bose-Einstein condensation in solids. Cavity polariton is expected to open the way for the development of a new generation of thresholdless polariton laser without the requirement of population inversion. In this thesis, we use ZnO-based and InGaN-based hybrid microcavities for the study of polariton lasing and electrically pumped polariton light-emitting diodes. We demonstrated a room-temperature polariton lasing with an extremely low threshold pumping density from the ZnO microcavity. The polariton relaxation mechanisms including polariton relaxation bottleneck effect and bosonic final state stimulation effect are experimentally demonstrated in this study as well. Furthermore, we present an electrically pumped InGaN-based polariton LED in strong coupling regime. Two different approaches including the temperature-dependent and angle-resolved electroluminescence spectra demonstrate an obvious polariton characteristic of anticrossing. These research results show that the wide-bandgap semiconductor microcavities are mostly adapted for the realization of a new generation of polariton emitters.