Ibuprofen ranks as one of the most frequently detected pharmaceutical pollutants in water across many countries. Previous studies identified conditions for actinobacterial degradation of ibuprofen and developed a chromatographic analysis technique, enabling the measurement of residual ibuprofen levels during bio-degradation. However, the impact of a complex interplay of factors on the dynamics of ibuprofen biodegradation remains insufficiently explored. The objective of this study was to enhance the biodegradation process of ibu-profen through a multifactorial experiment that controled key parameters and to predict changes in substance content and the time needed for process optimization using kinetic modeling. As a result of this study, varying the concentrations of glucose, n-hexadecane, inoculum, and pH values has enabled a remarkable reduction in the biodegradation process duration for ibuprofen (0.1 g/L), from 10 days to just 2 days when employing cosub-strates in quantities of 1.0 g/L, 10.0 ml/l, and adhering to the turbidity standard NTU-5, along with pH stabiliza-tion at 6.5. By applying the kinetic equation of the first-order derivative, dx/dt = –k x-1, we determined the pa-rameter ‘k’ for the ibuprofen biodegradation rate to be 138.88÷146.84%2/h. The half-life (t1/2) was calculated as 25.54÷27.00 hours, and the process’s endpoint, t1/100, was refined to 34.05÷36.00 hours under the optimized conditions.