Modified theories of gravity have been generally regarded as a promising research direction in modern theoretical physics. Generically, they are required to reproduce all the successful cosmological and astrophysical predictions made by Einstein’s General Relativity (GR). In addition, they are motivated to resolve problems which by now cannot be well explained by GR, such as the strong observational evidences hinting towards the existence of dark energy and dark matter, the troublesome spacetime singularities which indicate the incompleteness of GR itself, and the potential conflict between GR and the quantum theory. Since there is still no firmly established quantum theory of gravity so far, modified theories of gravity can be treated as effective theories of such a fundamental yet unknown quantum theory of gravity from phenomenological perspectives. Furthermore, these theories of gravity can in principle be tested by the latest observations such as cosmic microwave background, gravitational lensing, black hole shadows, type Ia supernovae, baryon acoustic oscillations, gravitational waves, and measures of the Hubble parameter. By understanding better the physical implications of these modified theories of gravity and what their observational predictions are, it is believed that we can get more hints towards the fundamental nature of our Universe. In this thesis, we consider some interesting modified theories of gravity and study their cosmological and astrophysical implications. We first focus on the theories with Born-Infeld inspired structures and investigate the cosmological solutions of these theories at the classical level. In the so-called mimetic Born-Infeld gravity, we pay additional attention to its black hole solutions since significant differences from GR of the interior structure are expected. Then we consider two different approaches towards quantum gravitational effects of the so-called Eddington-inspired-Born-Infeld gravity (EiBI). The first approach is the quantum geometrodynamics based on solving the Wheeler-DeWitt equation which describes the quantum dynamics of the Universe as a whole. Within this approach we investigate the quantum avoidance of spacetime singularities in the EiBI gravity. In the second approach we investigate the O(4)-symmetric instantons which describe quantum tunneling processes in the EiBI gravity. The singular and regular instantons are studied and several interesting outcomes absent in GR are obtained, such as the avoidance of singular poles and the formation of Lorentzian wormholes. We then turn our consideration to the possibility of testing modified gravity theories through gravitational waves emitted by perturbed black holes. This research direction has become an interesting arena recently. In this thesis, we investigate the quasi-normal modes (QNMs) for black hole solutions in the following modified gravity theories: the Palatini-f (R) gravity, the EiBI gravity, and a class of nonsingular black holes which can be treated as the vacuum solution of a family of conformal gravity theories. The master equations describing the QNMs are derived, and the QNM frequencies are evaluated with the Wentzel-Kramers-Brillouin (WKB) method. As expected, the QNM spectra of these modified black holes would deviate from their GR counterparts, indicating the possibility of testing these black hole solutions with the help of future gravitational wave detections. In principle, there could be infinitely many ways to modify GR. Each of them stems from different theoretical grounds and gives distinct predictions. With future developments of observations, most modified theories of gravity can be tested or even falsified, revealing a much clearer picture of how our Universe should be comprehended.