Herein, we described an experimental model of high‐dose ethanol (EtOH) administration, able to induce in vitro impairment in macrophage phagocytic capacity, already observed at 24 h after the last EtOH administration. This phenomenon was characterized by enlarged time required for adhesion and internalization events. Parallel studies documented an overall impaired production of interleukin (IL)‐6 and nitric oxide (NO) production by peritoneal macrophages in EtOH‐treated mice following interferon (IFN)‐γ and lipopolysaccharide (LPS) stimuli. Although the impaired IL‐6 response could not be restored by any of the experimental conditions tested, the lower NO response to INF‐γ and LPS was overturned by simultaneous IFN‐γ/LPS stimuli. It was interesting to notice that high‐dose EtOH administration drives peritoneal macrophages towards long‐term impairment in phagocytosis capacity with slower adhesion time, but with no impact on the time required for internalization. Moreover, 30 days after the last EtOH administration, lower IL‐6 response to INF‐γ and impaired NO production were still observed in response to IFN‐γ/LPS stimuli, with the IL‐6 response to IFN‐γ being restored by IFN‐γ/LPS stimuli. Histological studies showed that high‐dose EtOH administration led to long‐term in vivo impairment of antigen‐clearance following OVA‐driven delayed‐type‐hypersensitivity induction, characterized by the presence of a large amount of unprocessed OVA surrounded by dermal inflammatory infiltrate, suggesting defective activity of antigen‐presenting cells. Together, these findings supported our hypothesis that the poor antigen clearance in vivo may be related to the impaired macrophage function in vitro. These observations in the murine experimental model may reflect some of the consequences of EtOH consumption by humans.