Abstract
Studies with tracking of single nanoparticles are providing new insights into the interactions and processes involved in the transport of drug carriers in living mice. Here, we report the tracking of a single particle quantum dot (Qdot) conjugated with tumor-targeting antibody in tumors of living mice using a dorsal skinfold chamber and a high-speed confocal microscope with a high-sensitivity camera. Qdot labeled with the monoclonal anti-HER2 antibody was injected into mice with HER2-overexpressing breast cancer to analyze the molecular processes of its mechanistic delivery to the tumor. Movement of single complexes of the Qdot-antibody could be clearly observed at 30 frames/s inside the tumor through a dorsal skinfold chamber. We successfully identified six processes of delivery: initially in the circulation within a blood vessel, during extravasation, in the extracelullar region, binding to HER2 on the cell membrane, moving from the cell membrane to the perinuclear region, and in the perinuclear region. The six processes were quantitatively analyzed to understand the rate-limiting constraints on Qdot-antibody delivery. The movement of the complexes at each stage was "stop-and-go." The image analysis of the delivery processes of single particles in vivo provides valuable information on antibody-conjugated therapeutic nanoparticles, which will be useful in increasing therapeutic efficacy.
Highlights
Recent anticancer therapeutics based on active tumor targeting by conjugating tumor-specific antibodies has become of great interest in oncology, pharmacology, and nanomedicine
quantum dot (Qdot) was conjugated to trastuzumab (Herceptin, Chugai Pharmaceuticals Co., Ltd., Tokyo, Japan) with a Qdot 800 Antibody Conjugation Kit (Quantum Dot Corp., Hayward, CA) coated with polyethylene glycol (PEG) amine (MW 2,000) according to the manufacturer’s instruction
Qdots were conjugated to trastuzumab using the Qdot-antibody conjugation kit (QT complex)
Summary
Recent anticancer therapeutics based on active tumor targeting by conjugating tumor-specific antibodies has become of great interest in oncology, pharmacology, and nanomedicine. This approach will allow to increase therapeutic efficacy and to decrease systemic toxicity [1,2,3]. One of the best ways to do this is to apply a new technology in biophysics wherein the positions of proteins are detected quantitatively at the single molecule or particle level with nanometer precision [4]. The specific processes of its delivery in vivo postinjection are not known at the single particle level. Conventional modalities of in vivo imaging such as computed tomography, magnetic
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