Fluorescent Nanorods and Nanospheres for Real-Time In Vivo Probing of Nanoparticle Shape-Dependent Tumor Penetration
Authors: Vikash P. Chauhan, Zoran Popovic, Ou Chen, Jian Cui, Dai Fukumura, Moungi G. Bawendi, and Rakesh K. Jain Entry by: Pichet Adstamongkonkul
Summary
Motivation and Hypothesis
Nanomedicine has been shown advantageous over conventional chemotherapy, in that it can greatly reduce systemic toxicity and lengthen circulation time. The major problem hindering the effectiveness of the treatment of cancer is the nonuniformly leaky vasculature and dense interstitial environment. These factors cause heterogeneous transvascular transport and limit penetration.
Many studies have reported that decreasing the size of nanoparticles partially improve delivery, lengthen the circulation time, and transport more rapidly within tumor mass. However, some shortcomings include lower drug payloads and loading efficiencies. The surface charges also affect the mode of delivery, as the cationic particles optimize the transvascular transport, while the neutral ones have long circulation time and interstitial transport in tumors. Modulating the charges are thus not attractive. Particle aspect ratio can affect diffusion rates through pores and porous media, but the effects on tumor penetration is unknown.
The main hypothesis of this study is that the nanorods will penetrate tumors more efficiently than nanospheres of the same hydrodynamic size.
Results and Discussion
Quantum dots were used as core in order to track the nanoparticles in vivo and at real time, with the use of multiphoton microscopy. Nanospheres and nanorods were designed with tunable size but identical surface charge and chemistry.