This study combines the use of ozone system with High-Gravity Rotating Packed Bed (HGRPB) and conducts oxidation on solutions of lignin monomer and macromolecular compounds, in order to understand the viability for removal of water contaminants. The experimental samples include different molecular average weights of guaiacol, lignosulfonate and alkali lignin solutions. Controlling for different ozone dosages, HGRPB rotation speeds and pH levels, the COD, TOC, monomer concentrations and molecular average weights are measured and used to calculate the average reduction of contaminants per gram of ozone in the system. In the base case of 0.1 g/L of guaiacol solution, HGRPB is set at 5400 rpm and the reacting condition at pH 7. After 30 min of treatment time, 6 g/hr ozone dosage removes 13% more of COD, 12% more of TOC and 5% more of concentration than the standard 1 g/hr ozone dosage. This result indicates that the higher ozone dosage has the more contaminant removal. While controlling for higher HGRPB rotation speed at 7200 rpm yields 4% more of COD, 6% more of TOC and 6% more of concentration reduces. Higher rotation speed produces better removal results at the initial phase of treatment. 30 min of reaction under alkali conditions further reduce COD by 13%, TOC by 11% and the concentration by 5% more. Ozone is presumed to increase free radical under alkali condition and affects the oxidation of organic substances in water. Under identical condition, monomers with lower molecular average weights yield much higher reduction than the other two macromolecular compounds. The molecular average weights of the macromolecular compound solutions fluctuate with changes in COD and TOC. Under standard parameters, the molecular average weights of 0.1 g/L of lignosulfonate and alkali lignin solutions respectively reduce from 12030 to 1147 and from 60148 to 7093. Increasing ozone dosage, HGRPB rotation speed and alkali level yield more reduction of molecular average weights.