In the strong coupling regime, a new quasi-particle termed cavity –polariton with bosonic characteristics is created from the mixing of photons and excitons. It has very small effective mass as well as controllable dispersion curves, so that semiconductor microcavities (MCs) have been widely investigated due to the enhanced control of light-matter interaction in solid-state systems. In the thesis, we focus the strong coupling regime between cavity photon and exciton in two wide bandgap semiconductor microcavities- ZnO based hybrid microcavity and InGaN/GaN multiple-quantum-well microcavity. First of all, we investigate high-reflectivity blue-violet distributed Bragg reflectors (DBRs) based on AlN/GaN quarter-wave layers for the hybrid ZnO-based MCs. The 20-pairs AlN/GaN DBRs achieve peak reflectivity of 97.2% at 440 nm together with a stopband width of 36.6 nm. Furthermore, the growth of 20-pair AlN/GaN DBR will suffer significant influence of GaN absorption when the designed DBR wavelength is shorter than about 380 nm. The experimental reflectivity spectra are modeled by transfer matrix theory including the effect of GaN absorption to compare the experimental and theoretical results. For bulk ZnO-based microcavity with 1.5λ optical thickness, we observed a vacuum Rabi-splitting as large as 68 meV at RT based on the angle-resolved photoluminescence and reflectivity experiments. It is found that the upper polariton branch (UPB) is blurred in both experiments due to the absorption from scattering states. Furthermore, we present in detail the possible physical mechanisms leading to the broadening of UPBs for different designs of MCs by numerical simulations based on GaAs, GaN and ZnO materials. The calculated results show that the UPBs of the GaN- and ZnO-based MCs will become indistinct when the thickness of optical cavity is larger than  and 0.25, respectively, mainly attributed to the larger product of the absorption coefficient and the active layer thickness. In wide-bandgap materials, it would be relatively easier to observe the UPB in the case of negative exciton-photon detuning due to the exciton-like UPB and lower absorption of scattering states. In addition, the inhomogeneous broadening would be an important factor causing the invisible UPB in wide-bandgap semiconductor MCs. We demonstrate that in a ZnO/ZnMgO multiple-quantum-well MCs, the UPB could be well-defined due to the large 2D exciton binding energy and the small product of absorption coefficient and active layer thickness. These results show that the UPBs can be properly defined in wide-bandgap semiconductor MCs by appropriate design of MC structures. In the last of the thesis, we report the strong coupling regime in electrically pumped InGaN-based microcavity. Through the temperature-dependent electroluminescence (EL) spectra, there is a Rabi-splitting about 6 meV at a temperature of 280 K. Moreover, the angle-resolved EL spectra at 180 K show the 7-meV Rabi-splitting at 7.4, and the splitting value between lower polariton and upper polariton decreases with the increase of current density, which further evidence the strong coupling regime in electrically pumped InGaN-based microcavity.