This study presents a computational assessment of antiviral liquid particle deposition in realistic human respiratory airways, comparing the actual inhalation cycle of a chronic obstructive pulmonary disease (COPD) patient to an ideal and healthy subject. Antiviral drugs are inhaled as fine droplets or mist, forming a thin liquid film along the airway walls of critical areas where respiratory viruses initially reside. The method employs an Eulerian-Lagrangian discrete phase model (DPM) to track individual droplet trajectories, and combines with an Eulerian wall film (EWF) model to predict the formation of the liquid coating upon droplet impact. This strategy overcomes the limitations of previous investigations that relied solely on DPM and ignored post-impact drug behavior. The patient-specific analysis focuses on airflow dynamics, deposition efficiency, and surface coverage for 1-10 m particle sizes. It has been found that the large particles (10 m) deposit primarily in the upper airways due to inertial impaction, while smaller particles (1-3 m) reach deeper zones. The short and forceful breathings of COPD patients create complex asymmetric velocity distribution. As a result, even higher depositions are noticed along the upper airways (~5.28%) than the lower ones (~2.52%), limiting the drug penetration into deeper lung areas. For 10 m particles, the maximal area coverage for the ideal (55.2%) and healthy (63.5%) profiles is on the left lower lobe, while in COPD, coverage shifts toward the carina (71.5%). These findings signify optimization efforts, such as breath-actuated inhalers and pursed-lip breathing for COPD patients to enhance drug delivery efficacy. The study illustrates the importance of patient-specific airway geometry and dynamic breathing profiles in enhancing respiratory treatment efficacy.