In this thesis, we propose a new computational method to simulate elec- tronic dynamics coupled to a number of normal modes in complicated molec- ular systems. The method incorporates molecular dynamics into the driven Liouville von Neumann (DLvN) approach, and we refer to our method as the molecular dynamics-driven Liouville von Neumann (MD-DLvN) method. We also investigate time-dependent electron transport through a molecu- lar junction in the adiabatic limit at the density-functional tight-binding level using the MD-DLvN method. When electron transport involves nuclear dy- namics at finite temperature ( 70 K) within the NVE ensemble, we find that the steady-state current cannot be achieved even for a very short molecule (trans-fumaronitrile). Furthermore, to establish a relationship between elec- tric current fluctuations and molecular vibrations, we analyze the similarities and differences between the current noise spectra and the MD power spectra. Our simulations show that not all normal modes can result in current fluctu- ations. Moreover, when a normal mode satisfies a particular symmetry, the normal mode can lead to frequency doubling of current fluctuations. This study provides new directions for studying electronic dynamics in a nonequi- librium open quantum system.