Background Dry eye disease (DED) predominantly results from elevated tear film osmolarity, which can not only cause ocular inconvenience but may lead to visual impairments, severely compromising patient well-being and exerting substantial economic burdens as well. Astaxanthin (AST), a member of the xanthophylls and recognized for its robust abilities to combat inflammation and oxidation, is a common dietary supplement. Nonetheless, the precise molecular pathways through which AST influences DED are still poorly understood. Methods Therapeutic targets for AST were identified using data from the GeneCards, PharmMapper, and Swiss Target Prediction databases, and STITCH datasets. Similarly, targets for dry eye disease (DED) were delineated leveraging resources such as the Therapeutic Target Database (TTD), DisGeNET, GeneCards, and OMIM databases, and DrugBank datasets. Interactions among shared targets were charted and displayed using CytoScape 3.9.0. Gene Ontology and Kyoto Encyclopedia of Genes and Genomes pathway analyses were conducted to elucidate the functions of pivotal targets within the protein-protein interaction network. Molecular interactions between AST and key targets were confirmed through molecular docking using AutoDock and PyMOL. Molecular dynamics simulations were performed using GROMACS 2022.3. Viability of human corneal epithelial cells (hCEC) was assessed across varying concentrations of AST. A mouse model of experimental DED was developed using 0.1% benzalkonium chloride (BAC), and the animals were administered 100 mg/kg/day of AST orally for 7 days. The efficacy of the treatments was assessed through a series of diagnostic tests to evaluate the condition of the ocular surface after the interventions. The levels of inflammation and oxidative stress were quantitatively assessed using methods such as reverse transcription-polymerase chain reaction (RT-PCR), Western blot, and immunofluorescence staining. Results Network pharmacology suggests that AST may alleviate DED by influencing oxidation-reduction signaling pathways and reducing oxidative stress provoked by BAC. In vivo experiments demonstrated an improved overall condition in AST-administered mice in contrast to the control group. Immunofluorescence staining analyses indicated a decrease in Keap1 protein in the corneal tissues of AST-treated mice and a significant increase in Nrf2 and HO-1 protein. In vitro studies demonstrated that AST significantly enhanced cell viability and suppressed reactive oxygen species expression under hyperosmotic (HS) conditions, thereby protecting the human corneal epithelium. Conclusion AST is capable of shielding mice from BAC-induced DED, decelerating the progression of DED, and mitigating oxidative stress damage under HS conditions in hCEC cells. The protective impact of AST on DED may operate through stimulating the Keap1-Nrf2/HO-1 signaling pathway. Our research findings indicate that AST may be a promising treatment for DED, offering new insights into DED treatment.