NP-hard time complexity of model checking algorithms for TCTL properties in dense time is one of the obstacles against using model checking for the analysis of real-time systems. Alternatively, a polynomial time algorithm is suggested for model checking of discrete time models against TCTL ≤ , ≥ properties (i.e. TCTL properties without U = c modalities). The algorithm performs model checking against a given formula Φ for a state space with V states and E transitions in O ( V ( V + E ) ⋅ | Φ | ) . In this work, we improve the model checking algorithm of TCTL ≤ , ≥ properties, obtaining time complexity of O ( ( V lg V + E ) ⋅ | Φ | ) . We tackle the model checking of discrete timed actors as an application of the proposed algorithms. We show how the result of the fine-grained semantics of discrete timed actors can be model checked efficiently against TCTL ≤ , ≥ properties using the proposed algorithm. This is illustrated using the timed actor modeling language Timed Rebeca. In addition to introducing a new efficient model checking algorithm, we propose a reduction technique which safely eliminates instantaneous transitions of transition systems (i.e. transition with zero time duration). We show that the reduction can be applied on-the-fly during the generation of the original timed transition system without a significant cost. We demonstrate the effectiveness of the reduction technique via a set of case studies selected from various application domains. Besides, while TCTL ≤ , ≥ can be model checked in polynomial time, model checking of TCTL properties with U = c modalities is an NP-complete problem. Using the proposed reduction technique, we provide an efficient algorithm for model checking of complete TCTL properties over the reduced transition systems.