Abstract
Raman spectroscopy is an analytical method capable of detecting various microorganisms and small particles. Here, we used 25-1000 nm polystyrene particles in aqueous suspensions, which are comparable in size to viral particles and viral aggregates, to determine the limit of detection (LOD) of a confocal Raman microscope. We collected Raman spectra using a 785 nm wavelength laser with a power of 300 mW and a 10 s exposure time with a 5× objective lens. We detected the most prominent peak of the polystyrene particles at 1001 cm(-1), corresponding to the ring breathing mode. We established the minimum and maximum LOD (LOD(min) and LOD(max)) using a Kernel partial least-squares model. The LOD of the smallest size of 50 nm was identified as 1.80 × 10(12)-8.31 × 10(12) particle/mL, and for the largest size of 1000 nm, 5.11 × 10(8)-2.53 × 10(9) particle/mL. We demonstrated that Raman spectroscopy was nondestructive under these conditions by comparing the particle size before and after collecting Raman spectra using dynamic light scattering. Due to their size similarity to viral particles and viral aggregates, this systematic characterization of polystyrene particles provides detailed information on their Raman spectral signatures in aqueous suspensions. These findings establish a foundation for using Raman spectroscopy for the detection of small particles in aqueous suspensions and highlight its potential as a tool for real-time monitoring in vaccine manufacturing.