The objective of this study was to evaluate microwave heating enhancements offered by
iron/iron oxide nanoparticles dispersed within tissue-mimicking media for improving efficacy …

The use of nanoparticles, as enhancing agents to transform ultrasound energy into heat for
tumor destruction, is a promising approach to improve the efficacy of thermal-based cancer …

Abstract Effects of injection rate and tumor physiology on the diffusion of magnetic nano-
particles (MNPs) and temperature profile during magnetic hyperthermia are investigated in …

For in vivo magnetic hyperthermia tests, which are typically conducted on small animal
models, one of the objectives is the design of alternating current (AC) magnetic field …

Objective: Non-ablative or mild hyperthermia (HT) has been shown in preclinical (and
clinical) studies as a localized radiosensitizer that enhances the tumoricidal effects of …

In this work, effects of tumor shape on magnetic nanoparticle hyperthermia (MNPH) are
investigated and evaluated using four categories (spherical, oblate, prolate, and egg-shape) …

Magnetic particle hyperthermia (MPH) enables the direct heating of solid tumors with
alternating magnetic fields (AMFs). One challenge with MPH is the unknown particle …

Technologically relevant magnetic nanoparticles for biomedicine are rarely noninteracting
single-domain nanoparticles; instead, they are often interacting, with complex physical and …

Pharmaceuticals, and more recently biopharmaceuticals, have become the mainstay for
antineoplastic treatments in combination with surgical interventions and radiation therapy. In …

Magnetic particle imaging (MPI) technology can generate a real-time magnetic nanoparticle
(MNP) distribution image for biological tissues, and its use can overcome the limitations …