Beta-Lactoglobulin (beta-Lg) is the major fraction of whey protein that comprises more than 65%. Therefore, denaturation of beta-Lg during drying can affect the protein functionality where the whey protein is used as an ingredient in food products. This study was carried out to understand the drying and denaturation kinetics of beta-Lg during the drying process. A convective drying environment was used to predict the moisture content and temperature kinetics of the drying droplets of beta-Lg using Reaction Engineering Approach (REA) models. The predicted values were then coupled with the first order reaction equation to determine the denaturation kinetics. Single droplets of beta-Lg (10% w/v; 1.5 +/- 0.1 mm initial diameter) were dried at two different temperatures (65 degrees C and 80 degrees C) at a constant air velocity (0.5 m/s) for 10 min. The real time denaturation of beta-Lg protein was quantified at different drying stages using a reversed phase HPLC. These experimental data from single droplet drier, and HPLC were used to validate the model predictions. The REA model predictions fitted well with the experimental data for moisture-time (5.70% error) and temperature-time (3.50% error) profiles. Similarly, the first order kinetics model was also able to predict the denaturation kinetics of beta-Lg protein with an average error of 6.00%. The conformation study by FTIR observed that the drying stress increased the secondary structural properties random coil and beta-sheet which was compensated by uncoiling of a-helix and transformation of beta-turn into beta-sheet. The morphology study found that initially beta-Lg droplet showed flexible nature but formed firm skin with increasing drying time.