Characterization of Fe_3 O_4/Au-Ag@MoS_2 nanoparticles for brain cancer treatment using magneto plasmonic approach

TL;DR

This paper explores the design and optical properties of Fe_3O_4/Au-Ag@MoS_2 nanoparticles for brain cancer treatment via magnetic hyperthermia, demonstrating optimized compositions that achieve effective tumor heating within the biological window.

Contribution

It introduces a novel nanoparticle design combining Fe_3O_4, gold-silver alloy, and MoS_2, optimized for magnetic hyperthermia in brain cancer therapy, with detailed optical and thermal analysis.

Findings

Nanoparticles with Fe_3O_4 - Au_0.25 Ag_0.75@MoS_2 show optimal extinction and SPR.

Gold-silver alloy enhances extinction coefficient and prevents nanoparticle accumulation.

Tumor temperature reaches 45°C rapidly under magnetic hyperthermia, enabling effective treatment.

Abstract

This study investigates the treatment of brain cancer by the magnetic hyperthermia approach and nanoparticles including Fe_3 O_4 core with gold, silver alloy shell, and MoS_2 coating. Optical properties of these nanoparticles within the tumor, including the extinction coefficient and surface plasmon peak (SPR) as a function of size, structure, different compositions, and thickness are also investigated using the effective medium theory. Moreover, the impact of temperature distribution was assessed through the analytical modeling of alternating current (AC) magnetic field. The results of this study indicated that nanoparticles with a compound of Fe_3 O_4 - Au_0.25 Ag_0.75@MoS_2 and a thickness of 3 nm of gold-silver alloy and 3 layers of MoS_2 have the best coefficient of extinction and SPR in the biological window. The gold-silver alloy improved the extinction coefficient and, at the same time, prevented the accumulation of magnetic nanoparticles. Since the gold-silver alloy alone cannot function within the range of biological windows, MoS_2 was used, which increased the extinction efficiency at higher wavelengths. Examination of the temperature distribution in the tumor for the proposed alloy compound indicated that after a short time from the start of irradiation, the tumor temperature reaches 45 C degree. Also, the temperature distribution within the tumor tissue reached its maximum value at the center of the tumor and decreased dramatically as getting away from the center. The use of magnetic hyperthermia enabled localized delivery of therapeutic dose to malignant brain tumors; hence, exhibiting superior performance/efficiency over the photothermal method.