This dissertation documents the development of an environmental framework for monitoring antimicrobial resistance gene (ARG) dissemination in the aquatic environment. The work opens with a review of the relevant literature and outlines the importance of an environmental framework for monitoring ARG dissemination as part of antimicrobial resistance risk assessments. The ability to interrogate sequencing data quickly and easily for the presence of ARGs is crucial in order to facilitate their monitoring in the environment. As current laboratory methods for the detection and surveillance of antimicrobial resistant bacteria in the environment were limited in their effectiveness and scope, the dissertation begins by describing the design and implementation of a Search Engine for Antimicrobial Resistance (SEAR), a pipeline and web interface for detection of horizontally-acquired ARGs in raw sequencing data. The suitability of metagenomic methods for monitoring the ARG content of effluents from faecal sources was then assessed via a pilot study of a river catchment. Novel metagenomes generated from effluents entering the catchment were interrogated for ARGs. The relative abundance of ARGs in effluents were determined to be higher relative to the background environment, as were sequences relating to human and animal pathogens and mobile genetic elements. Thus, effluents were implicated in the dissemination of ARGs throughout the aquatic environment. To determine if ARGs were potentially in use in the environment, the expression of ARGs within effluents was then evaluated across a series of longitudinal samples through the use of metatranscriptomics, and the presence of potential environmental antimicrobial selection pressures was examined. This demonstrated that the abundance of ARGs, as well as antimicrobial usage at the effluent source, was correlated with the transcription of ARGs in aquatic environments. The work described in this dissertation has also found that horizontally transmitted ARGs were present in pathogenic endospore-forming bacteria commonly found across the aquatic environment, potentially providing a mechanism for ARG persistence in the environment. Finally, these findings were integrated into a universal framework for monitoring ARG dissemination in aquatic environments and used to highlight the developments required to incorporate this framework into future environmental ARG research and to facilitate antimicrobial resistance risk assessments.