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WE-FG-BRA-11: Theranostic Platinum Nanoparticle for Radiation Sensitization in Breast Cancer Radiotherapy.
Medical Physics 2016 June
PURPOSE: We have developed a novel receptor-targeted theranostic platinum nanoparticle (HER-PtNP) for enhanced radiation sensitization in HER2-positive breast cancer radiation treatment. This study aims to evaluate receptor-targeting specificity, and radiation sensitization of the nanoparticle.
METHODS: The platinum nanoparticle (PtNP) was synthesized with the diameter of 2nm, and capped with cysteine. The nanoparticle was tagged with a fluorescent dye (cy5) for the fluoresence detection, and conjuated with HER2/3 targeted protein (HerPBK10) for HER2-targeting specificity. We evaluated the theranostic features using in vitro breast cancer cell models: HER2-positive BT-474, and HER2-negative MDA-MB-231. The HER2-targeting specificity was evaluated using immunofluorescence and confocal microscopy. For each cell line, three sets of samples, including non-stained control, fluorescence stained PtNP-cy5 treated, and HER-PtNP treated, were imaged by confocal microscopy. Two breast cancer cell lineages were incubated with PtNP and HER-PtNP at 10 µg/mL, and then irradiated with X-rays for 2 Gy dose at 50 kVp. A colonogenic assay was used to determine cellular survival fractions by immediately reseeding 300 cells after irradiation in growth media and allowing colonies to grow for 2 weeks.
RESULTS: The results of confocal images show that no apparent nanoparticle cellular uptake was observed in the HER2-(MDA-MB-231) cells with 1% for PtNP-cy5 and 0.5% for HER-PtNP. Similarly no apparent PtNP-cy5 uptake (<1%) for BT474 cells was observed. However, there was significant HER-PtNP uptake (73%) for the HER2+(BT474) cells. The clonogenic assay showed that BT474 cells treated with HER-PtNP had significantly lower survival compared to those treated with PtNP (32% vs 81%, p=0.01). However, no significant radiosensitivity enhancement was observed for MDA-MB-231 cell treated with PtNP and HER-PtNP (89% vs 92%, p=0.78).
CONCLUSION: Our studies suggest that the HER2-targeted platinum nanoparticle has excellent receptor targeting specificity and enhanced radiation sensitization compared to nanoparticle alone, suggesting potential for clinical applications in breast cancer radiotherapy.
METHODS: The platinum nanoparticle (PtNP) was synthesized with the diameter of 2nm, and capped with cysteine. The nanoparticle was tagged with a fluorescent dye (cy5) for the fluoresence detection, and conjuated with HER2/3 targeted protein (HerPBK10) for HER2-targeting specificity. We evaluated the theranostic features using in vitro breast cancer cell models: HER2-positive BT-474, and HER2-negative MDA-MB-231. The HER2-targeting specificity was evaluated using immunofluorescence and confocal microscopy. For each cell line, three sets of samples, including non-stained control, fluorescence stained PtNP-cy5 treated, and HER-PtNP treated, were imaged by confocal microscopy. Two breast cancer cell lineages were incubated with PtNP and HER-PtNP at 10 µg/mL, and then irradiated with X-rays for 2 Gy dose at 50 kVp. A colonogenic assay was used to determine cellular survival fractions by immediately reseeding 300 cells after irradiation in growth media and allowing colonies to grow for 2 weeks.
RESULTS: The results of confocal images show that no apparent nanoparticle cellular uptake was observed in the HER2-(MDA-MB-231) cells with 1% for PtNP-cy5 and 0.5% for HER-PtNP. Similarly no apparent PtNP-cy5 uptake (<1%) for BT474 cells was observed. However, there was significant HER-PtNP uptake (73%) for the HER2+(BT474) cells. The clonogenic assay showed that BT474 cells treated with HER-PtNP had significantly lower survival compared to those treated with PtNP (32% vs 81%, p=0.01). However, no significant radiosensitivity enhancement was observed for MDA-MB-231 cell treated with PtNP and HER-PtNP (89% vs 92%, p=0.78).
CONCLUSION: Our studies suggest that the HER2-targeted platinum nanoparticle has excellent receptor targeting specificity and enhanced radiation sensitization compared to nanoparticle alone, suggesting potential for clinical applications in breast cancer radiotherapy.
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