journal contribution
posted on 2023-04-03, 15:07 authored by Li Peng, Wenting Shang, Pengyu Guo, Kunshan He, Hongzhi Wang, Ziyu Han, Hongmei Jiang, Jie Tian, Kun Wang, Wanhai Xu Table S1. Enrichment of phages for each round of selection from the phage display peptide library. Table S2. Patient characteristics and histopathological diagnosis. Table S3. Comparison of PLSWT7-DMI-based NIR-imaging analysis with histopathological diagnosis.
Funding
National Natural Science Foundation of China
National Key R&D Program of China
Chinese Academy of Sciences
Beijing Municipal Science & Technology Commission
Natural Science Foundation of Heilongjiang Province of China
History
ARTICLE ABSTRACT
Bladder cancer is a common human malignancy. Conventional ultrasound and white-light cystoscopy are often used for bladder cancer diagnosis and resection, but insufficient specificity results in a high bladder cancer recurrence rate. New strategies for the diagnosis and resection of bladder cancer are needed. In this study, we developed a highly specific peptide-based probe for bladder cancer photoacoustic imaging (PAI) diagnosis and near-infrared (NIR)-imaging-guided resection after instillation. A bladder cancer–specific peptide (PLSWT7) was selected by in vivo phage-display technology and labeled with IRDye800CW to synthesize a bladder cancer–specific dual-modality imaging (DMI) probe (PLSWT7-DMI). The feasibility of PLSWT7-DMI–based dual-modality PAI-NIR imaging was assessed in vitro, in mouse models, and ex vivo human bladders. An air-pouch bladder cancer (APBC) model suitable for probe instillation was established to evaluate the probe-based bladder cancer PAI diagnosis and NIR-imaging–guided resection. Human bladders were used to assess whether the PLSWT7-DMI–based DMI strategy is a translatable approach for bladder cancer detection and resection. The probe exhibited excellent selectivity and specificity both in vitro and in vivo. Postinstillation of the probe, tumors <3 mm were detectable by PAI, and NIR-imaging–guided tumor resection decreased the bladder cancer recurrence rate by 90% and increased the survival in the mouse model. Additionally, ex vivo NIR imaging of human bladders indicated that PLSWT7-DMI–based imaging would potentially allow precise resection of bladder cancer in clinical settings. This PLSWT7-DMI–based DMI strategy was a translatable approach for bladder cancer diagnosis and resection and could potentially lower the bladder cancer recurrence rate. Mol Cancer Ther; 17(10); 2100–11. ©2018 AACR.