The continuous development of semiconductor packaging technology and miniaturization and integration of semiconductor devices have markedly increased heat generation, highlighting the growing importance of efficient thermal management. Thermally conductive composites are widely employed in semiconductor packaging for heat dissipation; however, interfacial thermal resistance (ITR) at filler-matrix and fillerfiller interfaces severely limit their heat transfer performance. This review provides a comprehensive overview of recent strategies to reduce ITR. Among these, surface modification of fillers using silane, titania, and epoxy-based coupling agents, as well as plating and deposition techniques, has been shown to strengthen interfacial bonding and improve phonon spectrum matching. In addition, interfacial structural design approaches help eliminate voids and enlarge the effective contact area, thereby enhancing heat flow. Filler network design and hybridization enable the formation of continuous heat conduction pathways, while processing variables such as pressure, vacuum, and sintering promote densification and suppress pore formation. These strategies are individually effective, but when applied complementarily, they lead to far greater improvements.