Abstract
Developed and tested for many years, a variety of tumor hypoxia detection methods have been inconsistent in their ability to predict treatment outcomes or monitor treatment efficacy, limiting their present prognostic capability. These variable results might stem from the fact that these approaches are based on inherently wide-ranging global tumor oxygenation levels based on uncertain influences of necrotic regions present in most solid tumors. Here, we have developed a novel non-invasive and specific method for tumor vessel hypoxia detection, as hypoxemia (vascular hypoxia) has been implicated as a key driver of malignant progression, therapy resistance and metastasis. This method is based on high-frequency ultrasound imaging of α-pimonidazole targeted-microbubbles to the exogenously administered hypoxia marker pimonidazole. The degree of tumor vessel hypoxia was assessed in three mouse models of mammary gland carcinoma (4T1, SCK and MMTV-Wnt-1) and amassed up to 20% of the tumor vasculature. In the 4T1 mammary gland carcinoma model, the signal strength of α-pimonidazole targeted-microbubbles was on average 8-fold fold higher in tumors of pimonidazole-injected mice than in non-pimonidazole injected tumor bearing mice or non-targeted microbubbles in pimonidazole-injected tumor bearing mice. Overall, this provides proof of principle for generating and targeting artificial antigens able to be ‘created’ on-demand under tumor specific microenvironmental conditions, providing translational diagnostic, therapeutic and treatment planning potential in cancer and other hypoxia-associated diseases or conditions.
Highlights
Initially thought to be homogeneous, early proof of heterogeneous physiology in tumor vessels were described with low oxygen tensions (
We describe a novel hypoxemia detection method based on high-frequency ultrasound imaging of vascular restricted α-pimonidazole targeted-microbubbles, targeting the hypoxia marker pimonidazole in mouse mammary gland carcinoma models
After demonstrating in vitro that MBα-pimo was specific to hypoxic endothelial cells incubated with pimonidazole, quantification of the amount of vascular hypoxia in three different murine mammary gland carcinoma models using immunohistochemical staining was performed, i.e. 4T1, SCK and MMTV-Wnt-1 (2)
Summary
Initially thought to be homogeneous, early proof of heterogeneous physiology in tumor vessels were described with low oxygen tensions (
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