Nano/microparticles are widely used as vaccine adjuvants to improve antigen stability and enhance immune response. Conformational stability of a given protein was normally assessed using differential scanning calorimetry (DSC) for the optimization of formulation and for ensuring antigen stability in vaccine products. Here, a higher throughput version, namely the microtiter plate-based differential scanning fluorimetry (DSF) method was developed and optimized for assessing the protein thermal stability in the particulate adjuvant-adsorbed form. Using recombinant human papillomavirus (HPV) vaccine antigens, along with several model proteins, enhanced sensitivity and correlation to the well-established differential scanning calorimetry were demonstrated. Higher throughput and much smaller sample consumption (1/10 ∼ 1/20 of the amount needed as compared to DSC) make the plate-based DSF a method of choice for formulation development, particularly during the early developmental phase of a project where the sample amount is usually quite limited.
Keywords: Conformational stability; Differential scanning fluorimetry; Particulate adjuvant; Protein antigen; Vaccine formulation.
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