Micro- and nanoplastics (MNPs) are increasingly recognized as emerging intestinal toxicants. This scoping review maps and integrates evidence from 56 studies (47 primary and 11 review articles, 2000–mid-2025) on how nanoplastics, particularly ≤100 nm polystyrene, disrupt gut homeostasis. The evidence consistently supports a three-stage mechanistic cascade: 1. Oxidative-stress initiation—Nanoplastics generate reactive oxygen species (ROS) and suppress antioxidant defenses, producing redox imbalance in intestinal tissue and commensal bacteria. 2. Barrier dysfunction—Resulting oxidative injury reduces tight-junction proteins, depletes mucus-secreting goblet cells, and activates inflammatory signaling (NF-κB, TLR4). 3. Microbiome reconfiguration—The altered intestinal microenvironment favors Gram-negative expansion and depletion of Gram-positive commensals, observed as decreases in the Firmicutes/Bacteroidetes (F/B) and Gram+/Gram− ratios. High-dose nanoplastic exposures reproducibly induced these effects in mice and zebrafish, whereas environmentally realistic, low-dose PET fragments produced minimal dysbiosis. Functionally important taxa—short-chain-fatty-acid producers (Faecalibacterium, Roseburia) and mucin degraders (Akkermansia muciniphila)—were consistently reduced, linking microbial shifts to epithelial injury and inflammatory tone. Together, these findings define an oxidative–barrier–microbiome axis as the dominant pathway of nanoplastic-induced intestinal disruption. Future work should emphasize environmentally relevant exposures, multi-omics functional endpoints, and mechanistic models that integrate oxidative stress, epithelial pathology, and microbiome ecology to guide realistic human-health risk assessment.
Steven C. Sutton (Sat,) studied this question.