Inherent resistance of professional phagocytes for drug delivery has long been considered as one of the major barriers for development of immunocellular therapy. To overcome this challenge, a novel in vitro molecular delivery approach to macrophages using ultrasound standing wave field (USWF) associated with microspheres made by poly(lactic-co-glycolic acid) (PLGA) as drug carrier was explored.In this study, fluorescent compound of Calcein-AM was employed as the model drug and the Calcein-AM-loaded PLGA microspheres (CAPMs) were fabricated by organic solvent evaporation method. The mean size and surface charge of the CAPMs was 2.23 m and -91.8  2.82 mV detected using static and dynamic light scattering techniques, respectively. The CAPMs-internalized cells (canine macrophage DH82 cells) may continuously exhibit fluorescent expression for 72 h while most of cells treated with free Calcein-AM molecules lose fluorescence after 48 h, indicating that the encapsulated substance (e.g., Calcein-AM) can be protected from degradation by PLGA microcarriers and constantly released into cytoplasm for at least 72 h. After determining the optimal USWF parameters of 1-MHz frequency, 10-W acoustic output energy and 10-min exposure time, the efficiency of CAPMs internalization by DH82 cells (Cells # : CAPMs # = 2:1, 1:1, 1:2) with and/or without USWF treatment were examined. In this study, both number and fluorescence intensity of cells with and without USWF treatment were quantitatively analyzed by using flow cytometry. Our results showed that the optimal ratio of cell to CAPM was 2:1 in which the drug delivery efficiency of USWF-treated groupsignificantly enhanced about 2- (P< 0.05) and 8-fold (P< 0.05) in terms of fluorescence-expressed cell number and fluorescence intensity emitted, respectively as compared to the setting without USWF treatment. Overall the synthetic system of USWF in association with PLGA drug microcarriers developed in this study provided a feasible means for enhancement of molecular transfer efficiency of macrophages in vitro.