Using aquatic invertebrate assemblages for bioassessment of streams and rivers is a fast and cost-effective approach to studying the  impact of environmental stressors in aquatic ecosystems. The use of aquatic invertebrates is premised on their predictable responses to  environmental stressors. Assemblage structure is not, however, only influenced by environment, but also neutral processes and temporal  variation. This study quantified the relative roles of the environment (niche processes), space (neutral processes) and temporal  factors in structuring mayfly and blackfly assemblages at family and species levels. Asymmetric eigenvector maps in conjunction with  canonical redundancy analysis and variation partitioning were used to explore the relative roles of these three factors in structuring  macroinvertebrate assemblages. At a species level, flow and water temperature were more important in explaining assemblage structure  than at the family level. At the family level, space was more important than temporal and environmental factors. Unexplained  variation at species and family level was more than 50%. This suggests (i) caution in using family-level rapid assessments to infer the role  of the environment in structuring aquatic macroinvertebrate assemblages, as neutral processes are also dominant; and (ii) that the  importance of stochastic processes, such as dispersal, should not be underestimated in rapid assessments.