Fluorescent Image-guided Surgery in Breast Cancer by Intravenous Application of a Quenched Fluorescence Activity-based Probe for Cysteine Cathepsins in a Syngeneic Mouse Model

Overview

Journal EJNMMI Res

Date 2020 Sep 29

PMID 32990883

Citations 19

Authors

Frans V Suurs

Si-Qi Qiu

Joshua J Yim

Carolien P Schroder

Hetty Timmer-Bosscha

Eric S Bensen

John T Santini Jr

Elisabeth G E de Vries

Matthew Bogyo

Gooitzen M van Dam

Affiliations

Soon will be listed here.

Abstract

Purpose: The reoperation rate for breast-conserving surgery is as high as 15-30% due to residual tumor in the surgical cavity after surgery. In vivo tumor-targeted optical molecular imaging may serve as a red-flag technique to improve intraoperative surgical margin assessment and to reduce reoperation rates. Cysteine cathepsins are overexpressed in most solid tumor types, including breast cancer. We developed a cathepsin-targeted, quenched fluorescent activity-based probe, VGT-309, and evaluated whether it could be used for tumor detection and image-guided surgery in syngeneic tumor-bearing mice.

Methods: Binding specificity of the developed probe was evaluated in vitro. Next, fluorescent imaging in BALB/c mice bearing a murine breast tumor was performed at different time points after VGT-309 administration. Biodistribution of VGT-309 after 24 h in tumor-bearing mice was compared to control mice. Image-guided surgery was performed at multiple time points tumors with different clinical fluorescent camera systems and followed by ex vivo analysis.

Results: The probe was specifically activated by cathepsins X, B/L, and S. Fluorescent imaging revealed an increased tumor-to-background contrast over time up to 15.1 24 h post probe injection. In addition, VGT-309 delineated tumor tissue during image-guided surgery with different optical fluorescent imaging camera systems.

Conclusion: These results indicate that optical fluorescent molecular imaging using the cathepsin-targeted probe, VGT-309, may improve intraoperative tumor detection, which could translate to more complete tumor resection when coupled with commercially available surgical tools and techniques.

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