Biological interactions, toxicity, and environmental fate of engineered nanoparticles are affected by colloidal stability and aggregation. To assess nanoparticle aggregation, analytical methods are needed that allow quantification of individual nanoparticle aggregates. However, most techniques used for nanoparticle aggregation analysis are limited to ensemble measurements or require harsh sample preparation that may introduce artifacts. An ideal method would analyze aggregate size in situ with single-nanoparticle resolution. Here, we established and validated single-particle inductively coupled plasma mass spectrometry (SP-ICP-MS) as an unbiased high-throughput analytical technique to quantify nanoparticle size distributions and aggregation in situ. We induced nanoparticle aggregation by exposure to physiologically relevant saline conditions and applied SP-ICP-MS to quantify aggregate size and aggregation kinetics at the individual aggregate level. In situ SP-ICP-MS analysis revealed rational surface engineering principles for the preparation of colloidally stable nanoparticles. Our quantitative SP-ICP-MS technique is a platform technology to evaluate aggregation characteristics of various types of surface-engineered nanoparticles under physiologically relevant conditions. Potential widespread applications of this method may include the study of nanoparticle aggregation in environmental samples and the preparation of colloidally stable nanoparticle formulations for bioanalytical assays and nanomedicine. Graphical abstract.
Keywords: Aggregation; Colloidal stability; Elemental analysis; Nanoparticle; Single-particle ICP-MS; Surface chemistry.