In vivo target-specific activatable near-infrared optical labeling of humanized monoclonal antibodies

Abstract

Imaging with labeled monoclonal antibodies may be useful in detecting, staging, and monitoring tumors. Despite their high affinity and specificity, a critical limitation of antibody imaging is the high background signal due to prolonged clearance from the blood, which reduces the tumor-to-background ratio. To address this problem, we developed a molecular imaging probe consisting of multiple self-quenching fluorophores [Cy5.5 or Alexa Fluor 680 (Alexa680)] conjugated to a monoclonal antibody (trastuzumab) to synthesize Tra-Cy5.5(SQ) or Tra-Alexa680(SQ), respectively. This agent only becomes fluorescently “active” after cellular internalization but is quenched in the unbound state leading to high tumor-to-background ratios. The in vitro quenching capacity for both conjugates was ∼9-fold. In vivo imaging experiments were done in mice bearing both 3T3/HER-2⁺ and BALB/3T3/ZsGreen/HER-2⁻ xenografts. Tra-Alexa680(SQ) produced specific enhancement in the 3T3/HER-2⁺ tumors but not in the HER-2⁻ control tumors. However, Tra-Cy5.5(SQ) produced nonspecific enhancement in both 3T3/HER-2⁺ and control tumors. In conclusion, whereas Cy5.5-conjugates produced nonspecific results as well as rapid liver accumulation, conjugating multiple Alexa680 molecules to a single monoclonal antibody resulted in a near-infrared optical agent that activated within specific target tumors with high tumor-to-background ratio with considerable potential for clinical translation. [Mol Cancer Ther 2009;8(1):232–9]