Role of the Fraction of Blocked Nanoparticles on the Hyperthermia Efficiency of Mn-Based Ferrites at Clinically Relevant Conditions

Aquino, V. R. R.; Vinícius‐Araújo, Marcus; Shrivastava, Navadeep; Coaquira, J. A. H.; Bakuzis, Andris F.

doi:10.1021/acs.jpcc.9b06599

Cited by 27 publications

(63 citation statements)

References 48 publications

(109 reference statements)

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“…Immobilizing the nanoparticles strongly affects the harmonic signals, indicating the importance of Brownian relaxation at this frequency range. This is consistent with the analysis of the hydrodynamic radii of multicore nanostructures that, in the range of 50-100 nm, predicts Brownian relaxation in the frequency range lower than 20 kHz, as experimentally found by AC susceptibility measurements [192] or estimated theoretically using linear response theory [148]. On the other hand, Bender et al clearly demonstrated that at typical magnetic hyperthermia frequencies (100-500 kHz) the magnetic response of multicore nanoparticles is governed by intrinsic magnetic relaxation, i.e., by N eel-like relaxation [163,192].…”

Section: Final Considerations and Future Directionssupporting

confidence: 91%

“…According to this criteria it is clear from Figure 1 that no preclinical study from the literature is satisfactory (as far as we know) which means, in principle, that the experimental conditions that have been studied would not be applicable for human use, since they are predicted to generate a lot of non-localized heat by eddy currents. This is very disappointing, and suggests that several studies had not focused enough on the priority for clinical translation, which is related to improving the heating efficiency of magnetic nanoparticles at low-field condition [147,148]. On the other hand, Dutz and Hergt suggest that this limit can increase by a factor of 10 [25,26]; even so, note that only a few investigations are within the expected safety range of the second clinical limit.…”

Section: In Vivo Mnh: Clinical Safety Criteria and Preclinical Resultmentioning

confidence: 99%

“…To address some of the current limitations of this thermal therapy modality, not only for GBM treatment but mainly for its widespread application as an elective treatment modality for cancer, the development of better nano-heaters with low toxicity formulations and high specific loss power (SLP) in low-field conditions (i.e., feasible combinations of AMF amplitude and frequency) [148], are eagerly needed in order to explore the real potential of the technique, which in principle might not need to be combined with ionizing radiation.…”

Section: In Vivo Mnh: Clinical Safety Criteria and Preclinical Resultmentioning

confidence: 99%

See 2 more Smart Citations

In vivo magnetic nanoparticle hyperthermia: a review on preclinical studies, low-field nano-heaters, noninvasive thermometry and computer simulations for treatment planning

Rodrigues

Capistrano

Bakuzis

2020

International Journal of Hyperthermia

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Section: Final Considerations and Future Directionssupporting

confidence: 91%

Section: In Vivo Mnh: Clinical Safety Criteria and Preclinical Resultmentioning

confidence: 99%

Section: In Vivo Mnh: Clinical Safety Criteria and Preclinical Resultmentioning

confidence: 99%

See 1 more Smart Citation

In vivo magnetic nanoparticle hyperthermia: a review on preclinical studies, low-field nano-heaters, noninvasive thermometry and computer simulations for treatment planning

Rodrigues

Capistrano

Bakuzis

2020

International Journal of Hyperthermia

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“…Indeed, the dynamic hysteresis is strongly influenced by this term and shows optimum anisotropy values for hyperthermia. 11,49 The τ N of the ferrites varies in accordance with K eff , and the volume of the ferrite particles (V), as given in; 21 where τ 0 is the characteristic relaxation time approximately equal to 10 −9 s, k B and T are the Boltzmann constant and temperature, respectively (see Table 2). From the graphs (Figures 5 and 6), it is very clear that the heating rates of CFO_UR and CuF_20 show better efficiency compared to other ferrite samples.…”

Section: Magnetic Hyperthermia Of Ferritesmentioning

confidence: 99%

Single‐phase and binary phase nanogranular ferrites for magnetic hyperthermia application

et al. 2020

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The study demonstrates the performance of heating efficiency in single-phase and binary phase spinel ferrite nanosystems. Ferrimagnetic cobalt ferrite (CoFe 2 O 4) (CFO) and superparamagnetic copper ferrite/copper oxide (CuFe 2 O 4 /CuO) (CuF) nanosystems of different particle sizes were synthesized through a microwave-assisted coprecipitation method. The heating behavior was observed in range of both field amplitudes (8-24 kA/m at 516 kHz) and frequencies (325-973 kHz at 12 kA/m). The heating efficiency was analyzed and compared by means of particle size, magnetization, effective anisotropy constant, and Néel relaxation mechanism. Indeed, the heating rate was maximized in larger ferrite particles with low effective anisotropy constant. Moreover, though the magnetization and effective anisotropy constant of single-phase CoFe 2 O 4 nanoparticles were higher, the binary phase CuFe 2 O 4 /CuO nanosystems of similar crystallite size (28 nm) exhibited superior heating efficiency (4.21°C/s). For a field amplitude and frequency of 24 kA/m and 516 kHz, the heating rate of CuF and CFO ferrites with different crystallite sizes decreased in the order of 4.21 > 2.14 > 0.58 > 0.52°C/s for 29 nm > 25 nm > 12 nm > 15 nm, respectively. The results emphasize that binary phase ferrite nanoparticles are better thermoseeds than the single-phase ferrites for the magnetic hyperthermia application.

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“…When exposed to an alternating magnetic field, magnetic particles, considered in a broad sense as passive sensors, are able to detect and transduce it in a controlled and localized release of heat; this ability has promoted the use of these materials for advanced therapeutic applications such as magnetic hyperthermia and heat-assisted drug release [13,[21][22][23]. The physical mechanism at the base of heat generation has been recently identified to be mainly the magnetic hysteresis losses [24].…”

Section: Introductionmentioning

confidence: 99%

Specific Loss Power of Co/Li/Zn-Mixed Ferrite Powders for Magnetic Hyperthermia

Barrera

Celegato

Martino

et al. 2020

Sensors

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An important research effort on the design of the magnetic particles is increasingly required to optimize the heat generation in biomedical applications, such as magnetic hyperthermia and heat-assisted drug release, considering the severe restrictions for the human body’s exposure to an alternating magnetic field. Magnetic nanoparticles, considered in a broad sense as passive sensors, show the ability to detect an alternating magnetic field and to transduce it into a localized increase of temperature. In this context, the high biocompatibility, easy synthesis procedure and easily tunable magnetic properties of ferrite powders make them ideal candidates. In particular, the tailoring of their chemical composition and cation distribution allows the control of their magnetic properties, tuning them towards the strict demands of these heat-assisted biomedical applications. In this work, Co0.76Zn0.24Fe2O4, Li0.375Zn0.25Fe2.375O4 and ZnFe2O4 mixed-structure ferrite powders were synthesized in a ‘dry gel’ form by a sol-gel auto-combustion method. Their microstructural properties and cation distribution were obtained by X-ray diffraction characterization. Static and dynamic magnetic measurements were performed revealing the connection between the cation distribution and magnetic behavior. Particular attention was focused on the effect of Co2+ and Li+ ions on the magnetic properties at a magnetic field amplitude and the frequency values according to the practical demands of heat-assisted biomedical applications. In this context, the specific loss power (SLP) values were evaluated by ac-hysteresis losses and thermometric measurements at selected values of the dynamic magnetic fields.

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Role of the Fraction of Blocked Nanoparticles on the Hyperthermia Efficiency of Mn-Based Ferrites at Clinically Relevant Conditions

Cited by 27 publications

References 48 publications

In vivo magnetic nanoparticle hyperthermia: a review on preclinical studies, low-field nano-heaters, noninvasive thermometry and computer simulations for treatment planning

In vivo magnetic nanoparticle hyperthermia: a review on preclinical studies, low-field nano-heaters, noninvasive thermometry and computer simulations for treatment planning

Single‐phase and binary phase nanogranular ferrites for magnetic hyperthermia application

Specific Loss Power of Co/Li/Zn-Mixed Ferrite Powders for Magnetic Hyperthermia

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