Ni-Cu Nanoparticles and Their Feasibility for Magnetic Hyperthermia

Meneses-Brassea, Bianca P.; Borrego, Edgar A; Blazer, Dawn S.; Sanad, Mohamed Fathi; Pourmiri, Shirin; Gutierrez, Denisse A.; Varela-Ramı́rez, Armando; Hadjipanayis, G. C.; El-Gendy, Ahmed A.

doi:10.3390/nano10101988

Cited by 18 publications

(8 citation statements)

References 24 publications

(58 reference statements)

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“…However, the effectiveness and efficiency of superparamagnetic hyperthermia in destroying tumor cells depends very much on the magnetic nanoparticles used for it. Most viable results have been obtained so far by using Fe 3 O 4 nanoparticles (magnetite) [13][14][15][16][17][18][19][29][30][31][32][33][34][35][36][37][38][39], but also other magnetically soft ferromagnetic nanoparticles (which have low magnetic anisotropy) [40][41][42][43][44][45][46][47][48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Theoretical Study on Specific Loss Power and Heating Temperature in CoFe2O4 Nanoparticles as Possible Candidate for Alternative Cancer Therapy by Superparamagnetic Hyperthemia

Caizer

2021

Applied Sciences

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In this paper, we present a theoretical study on the maximum specific loss power in the admissible biological limit (PsM)l for CoFe2O4 ferrimagnetic nanoparticles, as a possible candidate in alternative and non-invasive cancer therapy by superparamagnetic hyperthermia. The heating time of the nanoparticles (Δto) at the optimum temperature of approx. 43 °C for the efficient destruction of tumor cells in a short period of time, was also studied. We found the maximum specific loss power PsM (as a result of superparamegnetic relaxation in CoFe2O4 nanoparticles) for very small diameters of the nanoparticles (Do), situated in the range of 5.88–6.67 nm, and with the limit frequencies (fl) in the very wide range of values of 83–1000 kHz, respectively. Additionally, the optimal heating temperature (To) of 43 °C was obtained for a very wide range of values of the magnetic field H, of 5–60 kA/m, and the corresponding optimal heating times (Δto) were found in very short time intervals in the range of ~0.3–44 s, depending on the volume packing fraction (ε) of the nanoparticles. The obtained results, as well as the very wide range of values for the amplitude H and the frequency f of the external alternating magnetic field for which superparamagnetic hyperthermia can be obtained, which are great practical benefits in the case of hyperthermia, demonstrate that CoFe2O4 nanoparticles can be successfully used in the therapy of cancer by superaparamagnetic hyperthermia. In addition, the very small size of magnetic nanoparticles (only a few nm) will lead to two major benefits in cancer therapy via superparamagnetic hyperthermia, namely: (i) the possibility of intracellular therapy which is much more effective due to the ability to destroy tumor cells from within and (ii) the reduced cell toxicity.

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Section: Introductionmentioning

confidence: 99%

Theoretical Study on Specific Loss Power and Heating Temperature in CoFe2O4 Nanoparticles as Possible Candidate for Alternative Cancer Therapy by Superparamagnetic Hyperthemia

Caizer

2021

Applied Sciences

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“…In addition, Ni−Cu nanoparticle swarms were developed for MH of cancer. 100 As shown in Figure 4b2, the death rate of breast cancer cells increased with the concentration of nanoparticles and incubation time.…”

Section: Design Of Micronanoswarmsmentioning

confidence: 82%

“…The left image shows Ni–Cu nanoparticle swarms, and the bar chart indicates the death rate of cancer cells using the swarm. Adapted with permission under a Creative Commons CC-BY license from ref . Copyright 2020 MDPI.…”

Section: Biomedical Applications Of Micronanoswarmsmentioning

confidence: 85%

An Overview of Micronanoswarms for Biomedical Applications

Chen

Zhang

et al. 2021

ACS Nano

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Micronanoswarms have attracted extensive attention worldwide due to their great promise in biomedical applications. The collective behaviors among thousands, or even millions, of tiny active agents indicate immense potential for benefiting the progress of clinical therapeutic and diagnostic methods. In recent years, with the development of smart materials, remote actuation modalities, and automatic control strategies, the motion dexterity, environmental adaptability, and functionality versatility of micronanoswarms are improved. Swarms can thus be designed as dexterous platforms inside living bodies to perform a multitude of tasks related to healthcare. Existing surveys summarize the design, functionalization, and biomedical applications of micronanorobots and the actuation and motion control strategies of micronanoswarms. This review presents the recent progress of micronanoswarms, aiming for biomedical applications. The recent advances on structural design of artificial, living, and hybrid micronanoswarms are summarized, and the biomedical applications that could be tackled using micronanoswarms are introduced, such as targeted drug delivery, hyperthermia, imaging and sensing, and thrombolysis. Moreover, potential challenges and promising trends of future developments are discussed. It is envisioned that the future success of these promising tools will have a significant impact on clinical treatment.

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“…Ni-Cu is an example of a molecule that can be used for this purpose. Low concentrations are not toxic, in high concentrations, a toxic effect on neoplastic cells is observed [ 252 ]. Another interesting aspect of nanomedicine and nanotechnology is the use of nano thermometers that can determine the temperatures of solutions and biological systems, even at the cellular level [ 253 ].…”

Section: Why Are Hyperthermia and Pdt Used In Treatment? Why Are They A Good Option For Combination Treatment?mentioning

confidence: 99%

Photodynamic Therapy and Hyperthermia in Combination Treatment—Neglected Forces in the Fight against Cancer

et al. 2021

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Cancer is one of the leading causes of death in humans. Despite the progress in cancer treatment, and an increase in the effectiveness of diagnostic methods, cancer is still highly lethal and very difficult to treat in many cases. Combination therapy, in the context of cancer treatment, seems to be a promising option that may allow minimizing treatment side effects and may have a significant impact on the cure. It may also increase the effectiveness of anti-cancer therapies. Moreover, combination treatment can significantly increase delivery of drugs to cancerous tissues. Photodynamic therapy and hyperthermia seem to be ideal examples that prove the effectiveness of combination therapy. These two kinds of therapy can kill cancer cells through different mechanisms and activate various signaling pathways. Both PDT and hyperthermia play significant roles in the perfusion of a tumor and the network of blood vessels wrapped around it. The main goal of combination therapy is to combine separate mechanisms of action that will make cancer cells more sensitive to a given therapeutic agent. Such an approach in treatment may contribute toward increasing its effectiveness, optimizing the cancer treatment process in the future.

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Ni-Cu Nanoparticles and Their Feasibility for Magnetic Hyperthermia

Cited by 18 publications

References 24 publications

Theoretical Study on Specific Loss Power and Heating Temperature in CoFe2O4 Nanoparticles as Possible Candidate for Alternative Cancer Therapy by Superparamagnetic Hyperthemia

Theoretical Study on Specific Loss Power and Heating Temperature in CoFe2O4 Nanoparticles as Possible Candidate for Alternative Cancer Therapy by Superparamagnetic Hyperthemia

An Overview of Micronanoswarms for Biomedical Applications

Photodynamic Therapy and Hyperthermia in Combination Treatment—Neglected Forces in the Fight against Cancer

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