Artículos de revistas
Quasi-static Magnetic Measurements To Predict Specific Absorption Rates In Magnetic Fluid Hyperthermia Experiments
Registro en:
Journal Of Applied Physics. American Institute Of Physics Inc., v. 115, n. 4, p. - , 2014.
218979
10.1063/1.4862647
2-s2.0-84903159429
Autor
Coral D.F.
Mendoza Zelis P.
De Sousa M.E.
Muraca D.
Lassalle V.
Nicolas P.
Ferreira M.L.
Fernandez Van Raap M.B.
Institución
Resumen
In this work, the issue on whether dynamic magnetic properties of polydispersed magnetic colloids modeled using physical magnitudes derived from quasi-static magnetic measurement can be extrapolated to analyze specific absorption rate data acquired at high amplitudes and frequencies of excitation fields is addressed. To this end, we have analyzed two colloids of magnetite nanoparticles coated with oleic acid and chitosan in water displaying, under a radiofrequency field, high and low specific heat power release. Both colloids are alike in terms of liquid carrier, surfactant and magnetic phase composition but differ on the nanoparticle structuring. The colloid displaying low specific dissipation consists of spaced magnetic nanoparticles of mean size around 4.8 nm inside a large chitosan particle of 52.5 nm. The one displaying high specific dissipation consists of clusters of magnetic nanoparticles of mean size around 9.7 nm inside a chitosan particle of 48.6 nm. The experimental evaluation of Néel and Brown relaxation times (∼10-10s and 10-4s, respectively) indicate that the nanoparticles in both colloids magnetically relax by Néel mechanism. The isothermal magnetization curves analysis for this mechanism show that the magnetic nanoparticles behave in the interacting superparamagnetic regime. The specific absorption rates were determined calorimetrically at 260 kHz and up to 52 kA/m and were well modeled within linear response theory using the anisotropy density energy retrieved from quasi-static magnetic measurement, validating their use to predict heating ability of a given polydispersed particle suspension. Our findings provide new insight in the validity of quasi-static magnetic characterization to analyze the high frequency behavior of polydispersed colloids within the framework of the linear response and Wohlfarth theories and indicate that dipolar interactions play a key role being their strength larger for the colloid displaying higher dissipation, i.e., improving the heating efficiency of the nanoparticles for magnetic fluid hyperthermia. 115 4
Gilchrist, N.R.K., Medal, R., Shorey, W.D., Hanselman, R.C., Parrott, J.C., Taylor, C.B., Selective inductive heating of Limph (1957) Ann. Surg., 146, p. 596 Jordan, A., Wust, P., Scholz, R., Tesche, B., Fähling, H., Mitrovics, T., Vogl, T., Felix, R., Cellular uptake of magnetic fluid particles and their effects on human adenocarcinoma cells exposed to AC magnetic fields in vitro (1996) Int. J. Hyperthermia., 12 (6), pp. 705-722 Hergt, R., Hiergeist, R., Zeisberger, M., Schüler, D., Heyen, U., Hilger, I., Kaiser, W.A., Magnetic particle hyperthermia: Nanoparticle magnetism and materials development for cancer therapy (2005) J. Magn. Magn. Mater., 293, pp. 80-86 Avdeev, M.V., Mucha, B., Lamszus, K., Ladislau, V., Garamus, V.M., Feoktystov, A.V., Marinica, O., Willumeit, R., Structure and in vitro biological testing of water-based ferrofluids stabilized by monocarboxylic acids (2010) Langmuir, 26 (11), pp. 8503-8509 Rosensweig, R.E., (1985) Ferrohydrodynamics, , Cambridge University Press, Cambridge, England Brullot, W., Reddy, N.K., Wouters, J., Valev, V.K., Goderis, B., Vermant, J., Verbiest, T., Versatile ferrofluids based on polyethylene glycol coated iron oxide nanoparticles (2012) J. Magn. Magn. Mater., 324, pp. 1919-1925 Luong, T.T., Ha, T.P., Tran, L.D., Hung Do, M., Thu Mai, T., Hong Pham, N., Bich Thi Phan, H., Nguyen, P.X., Design of carboxylated Fe3O4/poly(styreneco-acrylic acid) ferrofluids with highly efficient magnetic heating effect (2011) Colloids Surf. A: Physicochem. Eng. Aspects, 384, pp. 23-30 Laurent, S., Dutz, S., Häfeli, U.O., Mahmoudi, M., Magnetic fluid hyperthermia: Focus on superparamagnetic iron oxide nanoparticles (2011) Adv. Colloid Interface Sci., 166, pp. 8-23 Jeun, M., Bae, S., Tomitaka, A., Takemura, Y., Ho Park, K., Ha Paek, S., Chung, K.W., Effects of particle dipole interaction on the ac magnetically induced heating characteristics of ferrite nanoparticles for hyperthermia (2009) Appl. Phys. Lett., 95, p. 082501 Urtizberea, A., Natividad, E., Arizaga, A., Castro, M., Mediano, A., Specific absorption rates and magnetic properties of ferrofluids with interaction effects at low concentrations (2010) J. Phys. Chem. C, 114 (11), pp. 4916-4922 Serantes, D., Baldomir, D., Martinez-Boubeta, C., Simeonidis, K., Angelakeris, M., Natividad, E., Castro, M., Martínez, B., Influence of dipolar interactions on hyperthermia properties of ferromagnetic particles (2010) J. Appl. Phys., 108, p. 073918 Mehdaoui, B., Tan, R.P., Meffre, A., Carrey, J., Lachaize, S., Chaudret, B., Respaud, M., Increase of magnetic hyperthermia efficiency due to dipolar interactions in low-anisotropy magnetic nanoparticles: Theoretical and experimental results (2013) Phys. Rev. B, 87, p. 174419 De Sousa María, M.E., Fernández Van Raap, M.B., Rivas, P.C., Mendoza Zélis, P., Girardin, P., Pasquevich, G., Alessandrini, J., Sánchez, F.H., Stability and relaxation mechanisms of citric acid coated magnetite nanoparticles for magnetic hyperthermia (2013) J. Phys. Chem. C, 117 (10), pp. 5436-5445 Rosensweig, R.E., Heating magnetic fluid with alternating magnetic field (2002) J. Magn. Magn. Mater., 252, pp. 370-374 Carrey, J., Mehdaoui, B., Respaud, M., Simple models for dynamic hysteresis loop calculations of magnetic single-domain nanoparticles: Application to magnetic hyperthermia optimization (2011) J. Appl. Phys., 109, p. 083921 (1991) Rare Earth Magnetism: Structures and Excitations, , edited by J. Jensen and A. R. Mackintosh Clarendon Press, Oxford, Chap. 3 Stoner, E.C., Wohlfarth, E.P., A Mechanism of magnetic hysteresis in heterogeneous alloys (1948) Philos. Trans. Roy. Soc. A, 240, pp. 599-642 Dormann, J.L., Bessais, L., Fiorani, D., A dynamic study of small interacting particles: Superparamagnetic model and spin-glass laws (1988) J. Phys. C: Solid State Phys., 21, p. 2015 Lima, E., Jr., Torres, T.E., Rossi, L.M., Rechenberg, H.R., Berquo, T.S., Ibarra, A., Marquina, C., Goya, G.F., Size dependence of the magnetic relaxation and specific power absorption in iron oxide nanoparticles (2013) J. Nanopart Res., 15, p. 1654 Mendoza Zélis, P., Pasquevich, G.A., Stewart, S.J., Fernández Van Raap, M.B., Aphesteguy, J., Bruvera, I.J., Laborde, C., Sánchez, F.H., Structural and magnetic study of zinc-doped magnetite nanoparticles and ferrofluids for hyperthermia applications (2013) J. Phys. D: Appl. Phys., 46, p. 125006 Fortin, J.P., Gazeau, F., Wilhelm, C., Intracellular heating of living cells through Neél relaxation of magnetic nanoparticles (2008) Eur. Biophys. J., 37, pp. 223-228 Hergt, R., Dutz, S., Roder, M., Effects of size distribution on hysteresis losses of magnetic nanoparticles for hyperthermia (2008) J. Phys.: Condens. Matter, 20, p. 385214 Salas, G., Casado, C., Teran, F.J., Miranda, R., Serna, C.J., Puerto Morales, M., Controlled synthesis of uniform magnetite nanocrystals with high-quality properties for biomedical applications (2012) J. Mater. Chem., 22, p. 21065 Qu, J., Liu, G., Wang, Y., Hong, R., Preparation of Fe3O4- chitosan nanoparticles used for hyperthermia (2010) Adv. Powder Technol., 21, pp. 461-467 Belessi, V., Zboril, R., Tucek, J., Mashlan, M., Tzitzios, V., Petridis, D., Ferrofluids from magnetic-Chitosan hybrids (2008) Chem. Mater., 20, pp. 3298-3305 Gaihre, B., Seob Khil, M., Rae Lee, D., Yong Kim, H., Gelatin-coated magnetic iron oxide nanoparticles as carrier system: Drug loading and in vitro drug release study (2009) Int. J. Pharam., 365, pp. 180-189 Lassalle, V., Ferreira, M., Nano and microspheres based on Polylactide (PLA) polymers and copolymers: An overview of their characteristics as a function of the obtention method (2007) Macromol. Biosci., 7, pp. 767-783 Nicolás, P., Saleta, M., Troiani, H., Zysler, R., Lassalle, V., Ferreira, M.L., Preparation of iron oxides nanoparticles stabilized with biomolecules: Experimental and mechanism issues (2013) Acta Biomater., 9 (1), pp. 4754-4762 Li, P., Zhu, A.M., Liu, Q.L., Zhang, Q.G., Fe3O4/poly(N-isopropylacrylamide)/ chitosan composite microspheres with multiresponsive properties (2008) Ind. Eng. Chem. Res., 47, pp. 7700-7706 Freltoft, T., Kjems, J.K., Sinha, S.K., Power-law correlations and finite-size effects in silica particle aggregates studied by small-angle neutron scattering (1986) Phys. Rev. B, 33, pp. 269-275 Chen, S., Texeira, J., Structure and fractal dimension of protein-detergent complexes (1986) Phys. Rev. Lett., 57, pp. 2583-2586 Fernández Van Raap, M.B., Mendoza Zélis, P., Coral, D.F., Torres, T.E., Marquina, C., Goya, G.F., Sánchez, F.H., Self organization in oleic acid coated CoFe2O4colloids: A SAXS study (2012) J. Nanoparticle Res., 14 (9), pp. 1072-1075 Beaucage, G., Approximations leading to a unified exponential/power-law approach to small-angle scattering (1995) J. Appl. Cryst., 28, pp. 717-728 Micha, J.S., Dieny, B., Régnard, J.R., Jacquot, J.F., Sort, J., Estimation of the Co nanoparticles size by magnetic measurements in Co/SiO2 discontinuous multilayers (2004) J. Magn. Magn. Mater., 272-276, pp. E967-E968 Allia, P., Coisson, M., Tiberto, P., Vinai, F., Knobel, M., Novak, M.A., Nunes, W.C., Granular Cu-Co alloys as interacting superparamagnets (2001) Phys. Rev. B, 64 (14), p. 144420 Nunes, W.C., Folly, W.S.D., Sinnecker, J.P., Novak, M.A., Temperature dependence of the coercive field in single-domain particle systems (2004) Phys. Rev. B, 70, p. 014419 Gilmore, K., Idzerda, Y.U., Klem, M.T., Allen, M., Douglas, T., Young, M., Surface contribution to the anisotropy energy of spherical magnetite particles (2005) J. Appl. Phys., 97, p. 10B301 Dormann, J.L., Fiorani, D., Tronc, E., On the models for interparticle interactions in nanoparticle assemblies: Comparison with experimental results (1999) J. Magn. Magn. Mater., 202, pp. 251-267 Hugounenq, P., Levy, M., Alloyeau, D., Lartigue, L., Dubois, E., Cabuil, V., Ricolleau, C., Bazzi, R., Iron oxide monocrystalline nanoflowers for highly efficient magnetic hyperthermia (2012) J. Phys. Chem. C, 116 (29), pp. 15702-15712 Dormann, J.L., Fiorani, D., Tronc, E., Magnetic relaxation in fine-particle systems (2007) Advances in Chemical Physics, 98, p. 339. , edited by I. Prigogine and S. A. Rice John Wiley & Sons, Inc., Hoboken, NJ, USA, Chap. 4 Vallejo-Fernandez, G., Whear, O., Roca, A.G., Hussain, S., Timmis, J., Patel, V., O'Grady, K., Mechanisms of hyperthermia in magnetic nanoparticles (2013) J. Phys. D: Appl. Phys., 46, p. 312001