Abstract
Nanoparticles (NPs) that combine biocompatibility and enhanced physical characteristics for biomedical applications are currently an area of intense scientific research. Hafnium oxide NPs are an innovative approach in the anticancer treatment by radiotherapy due to their low toxicity and enhancement of local dose in the tumor reducing the total radiation dose for the patient. The combination of this property with the excellent magnetic hyperthermia performance of Fe3O4 NPs can produce a promising nanomaterial for cancer therapy. In this work, we attempted to synthesize nanoscale samples of HfO2 doped with nominal 10 at.% Fe, and Fe3O4 doped with Hf at 10 at.% level using simple chemical routes. The crystal structure of the samples was characterized by X-ray diffraction. The material was irradiated with neutrons in a research reactor, the nuclear reaction 180Hf(n, γ)181Hf yielding the probe nucleus 181Hf(181Ta) used in the perturbed angular correlations experiments to measure hyperfine interactions. Despite their immediate response to the external magnetic field, at local level both samples showed only electric quadrupole interaction typical of the monoclinic hafnia indicating that Fe replaces Hf in HfO2 NPs, but, rather than substituting Fe, Hf enters magnetite in the form of HfO2 clusters. Transmission Electron Microscopy was exploited to study the morphology of these complex systems, as well as to localize hafnia clusters and understand the nature of their coupling to Fe3O4 specks.
Highlights
Magnetite nanoparticles (NPs) are known for their extended applications, among which is their employment in biomedicine.1 In this connection they are mostly known as imaging, delivery and hyperthermia agents.2,3 The latter two are, obviously, complementary.In turn, nanoscale hafnia was recently recognized as an excellent candidate for radiotherapy4 With its high atomic number Z = 72, Hf delivers an enhanced radiation dose to target cells, whereas the nontoxicity of HfO2 minimizes the damage to healthy tissue
Hafnium oxide NPs are an innovative approach in the anticancer treatment by radiotherapy due to their low toxicity and enhancement of local dose in the tumor reducing the total radiation dose for the patient
According to X-ray diffraction (XRD), the substitution of Hf ions by Fe has occurred in the sample causing a subtle positive chemical pressure
Summary
Magnetite nanoparticles (NPs) are known for their extended applications, among which is their employment in biomedicine.. Magnetite nanoparticles (NPs) are known for their extended applications, among which is their employment in biomedicine.1 In this connection they are mostly known as imaging, delivery and hyperthermia agents.. In this connection they are mostly known as imaging, delivery and hyperthermia agents.2,3 Nanoscale hafnia was recently recognized as an excellent candidate for radiotherapy With its high atomic number Z = 72, Hf delivers an enhanced radiation dose to target cells, whereas the nontoxicity of HfO2 minimizes the damage to healthy tissue. Composite HfxFeyO (HFO) NPs, with radioenhancers and preserved magnetic properties of Fe3O4, are expected to suit for a simultaneous hyperthermia and radiotherapy treatment, as well as to allow an easy magnetically controlled delivery
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