AIM: This article demonstrates how controlled hyperthermia at the cellular level can be achieved. MATERIALS & METHODS: The method is based on the simultaneous intracellular incorporation of fluorescence nanothermometers (CdSe quantum dots) and metallic nanoheaters (gold nanorods). RESULTS: Real-time spectral analysis of the quantum dot emission provides a detailed feedback about the intracellular thermal loading caused by gold nanorods excited at the plasmon frequency. Based on this approach, thermal dosimetry is assessed in such a way that the infrared laser (heating) power required to achieve catastrophic intracellular temperature increments in cancer cells is identified. CONCLUSIONS: This pure optical method emerges as a new and promising guide for the development of infrared hyperthermia therapies with minimal invasiveness.
AIM: This article demonstrates how controlled hyperthermia at the cellular level can be achieved. MATERIALS & METHODS: The method is based on the simultaneous intracellular incorporation of fluorescence nanothermometers (CdSe quantum dots) and metallic nanoheaters (gold nanorods). RESULTS: Real-time spectral analysis of the quantum dot emission provides a detailed feedback about the intracellular thermal loading caused by gold nanorods excited at the plasmon frequency. Based on this approach, thermal dosimetry is assessed in such a way that the infrared laser (heating) power required to achieve catastrophic intracellular temperature increments in cancer cells is identified. CONCLUSIONS: This pure optical method emerges as a new and promising guide for the development of infrared hyperthermia therapies with minimal invasiveness.
Authors: Alessandro Alabastri; Salvatore Tuccio; Andrea Giugni; Andrea Toma; Carlo Liberale; Gobind Das; Francesco De Angelis; Enzo Di Fabrizio; Remo Proietti Zaccaria Journal: Materials (Basel) Date: 2013-10-25 Impact factor: 3.623