SUMMARY This Bachelor thesis deals with the topic of graphene, its properties, synthesis methods and applications, with a special emphasis on graphene-reinforced metal composites. The first part of this thesis provides an overview of the history of the discovery of graphene, from the first knowledge of the layered structure of graphite to the laboratory isolation of graphene in 2004, which enabled scientists to conduct more detailed research and applications. The physical and chemical properties of graphene are analyzed in detail, including mechanical, electrical, thermal and optical properties that make graphene an effective material for various applications. Graphene synthesis methods are described in this paper, which include mechanical exfoliation, chemical synthesis, epitaxial growth and chemical vapour deposition (CVD). Special emphasis is placed on graphene-reinforced metal composites, which combine the superior properties of graphene with metal matrices of aluminum, copper, magnesium and titanium. The production methods of these composites are presented, such as ball milling, powder metallurgy, selective laser melting, friction stir processing and electro-coating, and their potential industrial applications in the automotive, aerospace, construction and biomedical sectors are presented. The paper explores the challenges and possibilities of commercializing graphene-reinforced metal composite materials, as well as their impact on the environment and health. The potential of graphene as the "material of the future" is still the subject of much intensive research, and its widespread application will potentially lead to a revolution in technology and thus to industrial progress.