Abstract
ObjectivesTo utilize phosphorescence to monitor hypoxic microenvironment in solid-tumors and investigate cancer chemotherapeutic effects in vivo.MethodsA hypoxia-sensitive probe named BTP was used to monitor hypoxic microenvironment in solid-tumors. The low-dose metronomic treatment with cisplatin was used in anti-angiogenetic chemotherapeutic programs. The phosphorescence properties of BTP were detected by a spectrofluorometer. BTP cytotoxicity utilized cell necrosis and apoptosis, which were evaluated by trypan blue dye exclusion and Hoechst33342 plus propidium iodide assays. Tumor-bearing mouse models of colon adenocarcinoma were used for tumor imaging in vivo. Monitoring of the hypoxic microenvironment in tumors was performed with a Maestro 2 fluorescence imaging system. Tumor tissues in each group were harvested regularly and treated with pathological hematoxylin and eosin and immunohistochemical staining to confirm imaging results.ResultsBTP did not feature obvious cytotoxicity for cells, and tumor growth in low-dose metronomic cisplatin treated mice was significantly inhibited by chemotherapy. Hypoxic levels significantly increased due to cisplatin, as proven by the expression level of related proteins. Phosphorescence intensity in the tumors of mice in the cisplatin group was stronger and showed higher contrast than that in tumors of saline treated mice.ConclusionsWe develop a useful phosphorescence method to evaluate the chemotherapeutic effects of cisplatin. The proposed method shows potential as a phosphorescence imaging approach for evaluating chemotherapeutic effects in vivo, especially anti-angiogenesis.
Highlights
Tumor is an extremely common problem for human beings, and chemotherapy is still the main treatment measure for tumor therapy
BTP did not feature obvious cytotoxicity for cells, and tumor growth in low-dose metronomic cisplatin treated mice was significantly inhibited by chemotherapy
We develop a useful phosphorescence method to evaluate the chemotherapeutic effects of cisplatin
Summary
Tumor is an extremely common problem for human beings, and chemotherapy is still the main treatment measure for tumor therapy. The tumor size is a main and superficial characteristic without monitoring of microenvironment. A reasonable method is urgently needed for evaluating chemotherapeutic effects. To develop such a method, a specific landmark of tumor which is significantly different with normal tissues should be indicated. Recent studies found hypoxia is a key feature in the solid-tumor microenvironment [1], facilitates tumor progression, metastatic spread, and resistance to radiation and chemotherapy. Hypoxia-inducible factor 1 (HIF-1) is the most significant hypoxia-related protein, and its cellular signal pathway has been studied for many years [2]. Angiogenesis-related protein vascular endothelial growth factor (VEGF) and multidrug resistance 1 (MDR1) are up-regulated by hypoxic conditions in tumor cells. Hypoxia and angiogenesis are hallmarks of cancer and major targets in cancer therapy, and several target-hypoxia/angiogenesis agents are being actively studied for their antitumor activity in preclinical models and/or in clinical trials [5]
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