Unsatisfactory dimensional control and defects are frequently seen in metal injection molded (MIM) parts, particularly after solvent debinding and thermal debinding. Most of these problems are related to the high amount of swelling of the binder components during solvent debinding and the cracking or blistering during the subsequent thermal debinding. The objective of this study was thus to eliminate the defect formation in metal injection molded parts during solvent and thermal debinding. In the first part of this work, the laser dilatometer analyses indicate that the amount of swelling during solvent debinding could be reduced by decreasing the binder content, adding coupling agent into the feedstock, adding swelling inhibitor into the solvent, and lowering the debinding temperature. Considering the productivity and the ease of implementation, adding coupling agents and swelling inhibitors are the two most effective methods. In the second part, a diffusion model was established to predict the binder distribution in the compact and the minimum amount of binder removal that is needed to create interconnected pore channels in the middle of the MIM specimen. The model agreed with the experimental data that were obtained using the soxhlet extraction method. The distributions of pore channels were also examined using bubble and dye penetration tests. The results show that when 62.0% of the soluble binder is removed, interconnected pores are formed in the middle of the 8.7, 6.0, and 3.0mm thick specimens. The total amount of pore in the core region equals to about 9.2%, which is close to the criterion when a sintered compact enters the final stage sintering and starts to close off the cylindrical pore channels. In the third part, the connected pores, which are formed after solvent debinding, are closed again due to the redistribution of soluble binders and backbone binders in the heating process. When decomposed gas molecules cannot escape easily to the ambient through the interconnected pores during thermal debinding, the pressure builds up at the core section and then causes cracking. Therefore, although the thicker specimen (>4.0 mm thickness) has higher than the minimum amount of binder removal, it can’t use normal heating rate (5℃/min) to do following thermal debinding process. Finally, the safe conditions of the two-stage debinding process for specimens with different thickness are determined by adjusting the solvent debinding completion and the heating rate of thermal debinding.