Highly stable intrinsically radiolabeled indium-111 quantum dots with multidentate zwitterionic surface coating: dual modality tool for biological imaging

Abstract

Here we describe a novel strategy to incorporate indium-111 into near infrared (NIR) emitting Cu–In–Se quantum dots (CIS-QDs) to synthesize intrinsically radiolabeled QDs (rQDs), as a quantitative tool for in vivo SPECT/fluorescence imaging. Multidentate zwitterionic polymer ligands were used to functionalize and improve the stability of CIS-rQDs and reduce nonspecific binding with plasma proteins/cell membrane. CIS-rQDs were taken up by colorectal adenocarcinoma (COLO-205) and human epidermoid carcinoma (KB-3-1) cells at low uptake rate (∼0.4%, 2 × 10⁵ QDs per cell at 24 h) and reduced nonspecific interaction of zwitterionic CIS-rQDs with cells was observed by fluorescence microscopy. The cytotoxicity of CIS-rQDs was reduced due to the low toxic inorganic composition of QDs and multidentate zwitterionic surface coating. In 5 out of 6 nude mice bearing either COLO-205 or KB-3-1 tumor, both SPECT and fluorescence imaging demonstrated passive localization of CIS-rQDs in the tumor as early as 6 h post-injection. In these mice the passive accumulation of CIS-rQDs in the tumor, due to leaky vasculature, ranged from ∼0.3% ID per g to ∼4.6% ID per g at 48 h post-injection (from region of interest analysis of SPECT imaging). This intrinsic radio-labeling strategy provides a nanoparticle platform which incorporates imaging and potentially therapeutic radionuclides with retention of fluorescence intensity. It also provides complimentary quantitative data capabilities for both in vivo SPECT imaging and radiotracer ex vivo analysis.