In this study, biocatalysis in continuous reactors is presented with a focus on enzyme-catalysed reactions. Continuous reactors offer sustainable and economically viable processes thanks to the possibility of multiple use of enzymes through immobilisation techniques. Enzyme immobilisation provides stability, easy separation from the reaction mixture, and reuse, thereby reducing costs and increasing efficiency. The study provides an overview of the basic types of continuous reactors, such as packed bed reactors, membrane reactors, and fluidised bed reactors. Methods of enzyme immobilisation, including adsorption, covalent binding, encapsulation, entrapment, and cross-linking, are also presented, describing how these methods improve enzyme stability and efficiency. Successful examples of the application of biocatalysis in continuous reactors are shown, such as the production of uridine diphosphate galactose, the synthesis of chiral amines, and the clarification of orange juice. These examples demonstrate the advantages of continuous processing, including reduced enzyme inhibition, easier handling of immobilised enzymes, optimisation of reaction conditions, and increased productivity. The study also compares continuous reactors with traditional batch reactors, highlighting higher conversion rates, better enzyme stability, and higher overall efficiency of continuous processes.