This study evaluated the feasibility of site-specific gene delivery mediated by diagnostic ultrasound using genes encapsulated in commercially available ultrasound contrast agents in vitro and in vivo. Five different commercially available contrast agents were tested in vitro for their ability to enclose an adenoviral vector carrying GFP. Prostate cancer cells (DU 145) or non small cell lung cancer cells (H23) were plated in 80 culture wells and insonified at 207 or 535 kPa peak negative pressure for 1 min after administration of 0.1 ml of bubbles reconstituted with the viral vector. Experiments were repeated with the delivery vehicle incubated with complement to inactivate unenclosed Adeno-GFP and with controls. After 24 hours transduction efficiency was demonstrated by fluorescent microscopy. In vivo 15 nude mice with 21 melanoma tumors (DB-1) implanted received 0.1 ml injections of contrast. Mice were split into 3 control and 4 active groups and ultrasound was performed for 4 min at 4 MHz using an Aplio scanner (Toshiba America Medical Systems, Tustin, CA). Tumors, heart, lungs and liver were harvested 48 hours later. Specimens underwent regular and fluorescent microscopy and were stained using an antibody against GFP. In vitro all contrast agents produced more fluorescence at 207 kPa than at 535 kPa. However, only Imagent (IMCOR Pharmaceuticals, San Diego, CA) was able to induce marked gene transduction with the inactivating agent. In vivo systemic delivery of Adeno-GFP carrying microbubbles following pre-treatment with the inactivating agent resulted in specific transduction of the tumor cells only with no uptake in heart, lungs or liver (unlike the controls). In conclusion, specific viral gene transduction has been obtained in vitro and in vivo through the use of ultrasound and Imagent microbubbles as delivery vehicles.