Nanotechnology in Hyperthermia Cancer Therapy: From Fundamental Principles to Advanced Applications

Overview

Journal J Control Release

Specialty Pharmacology

Date 2016 Jun 7

PMID 27264551

Citations 124

Authors

Jaber Beik

Ziaeddin Abed

Fatemeh S Ghoreishi

Samira Hosseini-Nami

Saeed Mehrzadi

Ali Shakeri-Zadeh

S Kamran Kamrava

Affiliations

Soon will be listed here.

Abstract

In this work, we present an in-depth review of recent breakthroughs in nanotechnology for hyperthermia cancer therapy. Conventional hyperthermia methods do not thermally discriminate between the target and the surrounding normal tissues, and this non-selective tissue heating can lead to serious side effects. Nanotechnology is expected to have great potential to revolutionize current hyperthermia methods. To find an appropriate place in cancer treatment, all nanotechnology-based hyperthermia methods and their risks/benefits must be thoroughly understood. In this review paper, we extensively examine and compare four modern nanotechnology-based hyperthermia methods. For each method, the possible physical mechanisms of heat generation and enhancement due to the presence of nanoparticles are explained, and recent in vitro and in vivo studies are reviewed and discussed. Nano-Photo-Thermal Therapy (NPTT) and Nano-Magnetic Hyperthermia (NMH) are reviewed as the two first exciting approaches for targeted hyperthermia. The third novel hyperthermia method, Nano-Radio-Frequency Ablation (NaRFA) is discussed together with the thermal effects of novel nanoparticles in the presence of radiofrequency waves. Finally, Nano-Ultrasound Hyperthermia (NUH) is described as the fourth modern method for cancer hyperthermia.

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