Numerical simulations of the interfacial flows have been a popular way to study a variety of fluid-world phenomena for a long time. In this dissertation, a mathematical model for interfacial flow problems (including the moving contact line problems) is demonstrated and an immersed boundary method is proposed for the simulation of two-dimensional fluid interfaces with insoluble surfactant. The governing equations are written in a usual immersed boundary formulation where a mixture of Eulerian flow and Lagrangian interfacial variables are used and the linkage between these two set of variables is provided by the Dirac delta function. The immersed boundary force comes from the surface tension which is affected by the distribution of surfactant along the interface. In particular, the unbalanced Young force should be applied in the moving contact line problems to derive the interface movement near moving contact lines. By tracking the interface in the Lagrangian manner, a simplified surfactant transport equation is derived. The numerical method involves solving the Navier-Stokes equations on a staggered grid by a semi-implicit pressure increment projection method where the immersed interfacial forces are calculated at the beginning of each time step. Once the velocity field and interfacial configurations are obtained, an equi-distributed technique of the Lagrangian markers is applied to force the markers to reach a uniform distribution in physical space. Meantime, the surfactant transport equation should be modified due to the effect of the tangential velocity arising from the equi-distributed process. Then the surfactant concentration is updated using the modified transport equation. The essential purpose of this dissertation is to study the effects of insoluble surfactants in the interfacial flow problems. Since it is important to maintain the insolubility of the surfactant concentration, the main contribution of this work is to propose a new symmetric discretization for the surfactant concentration equation such that the total mass of surfactant is conserved numerically. In numerical experiments, a bubble rises in a gravitational field, a vesicle deforms in a shear flow, and a hydrophilic or hydrophobic drop adheres to a solid substrate, are typical examples to observe the effects of the surfactant. To our best knowledge, the numerical method we propose here provides a wonderful chance to simulate moving contact line problems with insoluble surfactant.