Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia

Laura Martinez Maestro; Patricia Haro-Gonzalez; M. Carmen Iglesias-de la Cruz; Francisco Sanz-Rodriguez; Angeles Juarranz; Jose Garcia Sole; Daniel Jaque

doi:10.2217/NNM.12.122

Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia

Laura Martinez Maestro, Patricia Haro-Gonzalez, M. Carmen Iglesias-de la Cruz, Francisco Sanz-Rodriguez, Angeles Juarranz, Jose Garcia Sole, Daniel Jaque

Research output: Contribution to journal › Article › peer-review

Abstract

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.

Original language	English
Pages (from-to)	379-388
Number of pages	10
Journal	Nanomedicine (London, England)
Volume	8
Issue number	3
DOIs	https://doi.org/10.2217/NNM.12.122
Publication status	Published - Mar 2013

Keywords

cancer therapy
hyperthermia
laser thermal effect
metallic nanoheaters
nanothermometers

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.2217/NNM.12.122

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title = "Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia",

abstract = "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.",

keywords = "cancer therapy, hyperthermia, laser thermal effect, metallic nanoheaters, nanothermometers",

author = "{Martinez Maestro}, Laura and Patricia Haro-Gonzalez and {Carmen Iglesias-de la Cruz}, M. and Francisco Sanz-Rodriguez and Angeles Juarranz and {Garcia Sole}, Jose and Daniel Jaque",

year = "2013",

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doi = "10.2217/NNM.12.122",

language = "English",

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T1 - Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia

AU - Martinez Maestro, Laura

AU - Haro-Gonzalez, Patricia

AU - Carmen Iglesias-de la Cruz, M.

AU - Sanz-Rodriguez, Francisco

AU - Juarranz, Angeles

AU - Garcia Sole, Jose

AU - Jaque, Daniel

PY - 2013/3

Y1 - 2013/3

N2 - 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.

AB - 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.

KW - cancer therapy

KW - hyperthermia

KW - laser thermal effect

KW - metallic nanoheaters

KW - nanothermometers

U2 - 10.2217/NNM.12.122

DO - 10.2217/NNM.12.122

M3 - Article

SN - 1743-5889

VL - 8

SP - 379

EP - 388

JO - Nanomedicine (London, England)

JF - Nanomedicine (London, England)

IS - 3

ER -

Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia

Abstract

Keywords

UN SDGs

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