Many data and network applications for mobile and wireless networks cause disruptions in communications where traditional Internet architectures fail to ensure end-to-end connections due to intermittent connectivity, limited transmission range and low nodal density. The delay-tolerant networking (DTN) technology is introduced to deal with these problems. Contrary to traditional computer networks and MANETs, the message forwarding in delay-tolerant networks adopts the store-carry-and-forward approach to send messages to destinations when nodes have any opportunistic contacts with others in a network. Among the approaches for routing protocols in DTNs, the strategy of deploying the stationary relay nodes called “thrown boxes” is considered for increasing message delivery probability and reducing the message overhead efficiently. Till now, few studies have provided comprehensive analysis models and routing solutions for thrown-box-based network paradigms in the DTN research field. This thesis addresses the efficiency on message forwarding over heterogeneous nodes in DTNs. The technical content of this thesis includes three parts. Firstly, this study considers the deployment of thrown boxes that can assist in message delivery in delay-tolerant networks. A utility-based algorithm is applied to make the message forwarding decision between two nodes whenever they are in contact. Secondly, this study introduces the adaptation of absorbing Markov chain to develop an analytical framework to quantify and predict the performance of the proposed algorithm. Specifically, this framework is able to map an optimization problem over the presence of thrown box into a Markov chain over the relevant solution space. The contact between two nodes can dictate the chain transition probability and be used to advance the finding of an optimal solution by following neighboring solutions in chain. Finally, this study runs simulations to evaluate the proposed scheme in terms of the message overhead ratio and message delivery probability. Performance results show that the proposed algorithm performs better than other popular algorithms.