To address the challenge of foodborne pathogens, we have developed an ultra-sensitive tri-modal detection and effective pathogen eradication strategy utilizing a “dandelion” magnetic bead-driven cerium dioxide doped with carbon dots (CDs@CeO2) multifunctional nanoplatform. Aptamer (Apt) modification CDs@CeO2 specifically recognizes and binds to the outer membrane proteins of Salmonella typhimurium (S. typhimurium). Concurrently, mannose-functionalized dandelion-like magnetic beads selectively recognize adhesins of S. typhimurium, avoiding competition with Apt for binding sites and leveraging the strong bacterial capture capability for high-sensitivity detection. The prepared CDs@CeO2 has been demonstrated to exhibit favourable fluorescence characteristics. In the presence of H2O2, CDs@CeO2 is capable of oxidising colourless 3,3',5,5'-tetramethylbenzidine (TMB) into blue oxide, displaying exceptional photothermal properties. CDs@CeO2 have the potential to generate •OH through a Fenton-like reaction, which could directly damage cells. Notably, coupling the photosensitizer Ce6 to CDs@CeO2 and subsequent illumination generates 1O2, which synergistically eradicates bacteria with •OH. Detection limits of the fluorescence, colorimetry, and photothermal methods were 3.85 cfu/mL, 9.44 cfu/mL, and 5.00 cfu/mL, respectively. The platform successfully achieves precise detection of S. typhimurium in actual pre-prepared food samples through fluorescence, colorimetry, and photothermal tri-modal signals, and effectively kills bacteria, achieving trace detection and source control.
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