{"id":56,"date":"2011-12-13T16:17:23","date_gmt":"2011-12-13T15:17:23","guid":{"rendered":"http:\/\/www.icmm.csic.es\/csc\/?page_id=56"},"modified":"2025-09-24T15:07:03","modified_gmt":"2025-09-24T15:07:03","slug":"publications","status":"publish","type":"page","link":"https:\/\/wp.icmm.csic.es\/csc\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

2025<\/strong><\/h2>\n

Iron oxide nanospheres: dual functionality as MRI contrast agents and magnetic fluid hyperthermia therapeutics<\/a>. <\/em>Porru, M., Brero, F., D\u00ecaz-Ufano, C., … Morales, M.D.P., Lascialfari, A. Dalton Transactions, 2025<\/strong>, 54(22), pp. 9057\u20139068<\/p>\n

The Second Life of Cobalt MOF: Alternating Magnetic Field- Assisted Electrocatalytic Oxygen Evolution Reaction in MOF-derived Nanoparticles.<\/a> <\/em>del Rio-Rodr\u00edguez, J.L., Guti\u00e9rrez-Tarri\u00f1o, S., M\u00e1rquez, I., … Olloqui-Sariego, J.L., O\u00f1a-Burgos,P. Small , 2025, <\/strong>21, 2503871.<\/p>\n

Multiscale Thermal Analysis of Gold Nanostars in 3D Tumor Spheroids: Integrating Cellular-Level Photothermal Effects and Nanothermometry via X-Ray Spectroscopy.<\/em> <\/a> L\u00f3pez-M\u00e9ndez, R., Dubrova, A., Reguera, J., … Mu\u00f1oz-Noval, \u00c1., Espinosa, A. Advanced Healthcare Materials, 2025<\/strong>, 14(11), 2403799<\/p>\n

Luminescence Fingerprint of Intracellular NIR-II Gold Nanocluster Transformation: Implications for Sensing and Imaging<\/a><\/em>. Par\u00eds Og\u00e1yar, M., Ayed, Z., Josserand, V., … Le Gu\u00e9vel, X., Jaque, D. ACS Nano, 2025<\/strong>, 19(8), pp. 7821\u20137834<\/p>\n

Hyperthermic Core-Shell Silver-Gold Nanoparticles: Green Synthesis and Adsorption-Uptake by Macrophages, Fibroblasts and Cancer Cells<\/em>. <\/a>Valdivieso, E., Zabala, M., Mu\u00f1oz Noval, A., … Azcondo, M.T., Hurtado-Marcos, C. Chemistryopen, 2025<\/strong>, 14(3), e202400459.<\/p>\n

Impact of gold nanoparticle size and coating on radiosensitization and generation of reactive oxygen species in cancer therapy<\/em><\/a>.<\/em> Loscertales, E., L\u00f3pez-M\u00e9ndez, R., Mateo, J., … Espinosa, A., Espa\u00f1a, S. Nanoscale Advances 2025<\/strong>, 7(4), pp. 1204\u20131214<\/p>\n

Tailorable Piezoelectric Chain Morphology in Biocompatible Poly-l-lactide Induced by Melt-Based 3D Printing.<\/em> <\/a>Pascual-Gonz\u00e1lez, C., Pacheco-Carpio, G., Fern\u00e1ndez-Bl\u00e1zquez, J.P., … Alguer\u00f3, M., Amor\u00edn, H. ACS Applied Polymer Materials, 2025<\/strong>, 7(10), pp. 6067\u20136081<\/p>\n

3D nanofibrous frameworks with on-demand engineered gray and white matters for reconstructing the injured spinal cord<\/em>. <\/a>Gir\u00e3o, A.F., Barroca, N., Hern\u00e1ndez-Mart\u00edn, Y., … Marques, P.A.A.P., Serrano, M.C. Biomaterials Advances, 2025<\/strong>, 170, 214200<\/p>\n

Graphene oxide scaffolds promote functional improvements mediated by scaffold-invading axons in thoracic transected rats<\/em><\/a>. Zaforas, M., Benayas, E., Madro\u00f1ero-Mariscal, R., ….Aguilar, J., Serrano, M.C. Bioactive Materials 2025<\/strong>, 47, pp. 32\u201350<\/p>\n

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2024<\/strong><\/h2>\n

Toward More Sustainable Magnetic Nanoparticle Synthesis Based on Microwave-Assisted Continuous-Flow Processes<\/a>. <\/em>Simeonidis, K., Morales, M.D.P., Damartzis, T., Maniotis, N., Veintemillas-Verdaguer, S. Industrial and Engineering Chemistry Research, 2024<\/strong>, 63(47), pp. 20651\u201320660<\/p>\n

Key factors influencing magnetic nanoparticle-based photothermal therapy: physicochemical properties, irradiation power, and particle concentration in vitro<\/a>. <\/em>Fern\u00e1ndez-Afonso, Y., As\u00edn, L., Pardo, J., … Morales, M.P., Guti\u00e9rrez, L. Nanoscale Advances 2024<\/strong>, 7(1), pp. 336\u2013345<\/p>\n

Finite element modeling of plasmonic resonances in photothermal gold <\/em>nanoparticles embedded  in  cells. <\/em><\/a>Par\u00eds Og\u00e1yar, R.et al. Nanoscale Adv 2024<\/strong>. 6,<\/strong> 4635-4646.<\/p>\n

Modulating the Magnetic Properties of Fe3C\/Few-layered Graphene Core\/Shell Nanoparticles for Potential Prospects in Biomedicine<\/em>.<\/a> Castellano-Soria, R. et al. Materials Today Chemistry 2024<\/strong>. 39, 102143 (2024). <\/p>\n

Elucidating the dynamics of biodegradation and biosynthesis of magnetic nanoparticles in human stem cells. <\/em><\/a>Curcio, G.  et al. Small 2024,<\/strong> 102143.<\/strong>  <\/p>\n

Cost-effective synthesis of stable CoxC@few-layered graphene nanostructures embedded in a carbon matrix<\/em>.<\/a> C. del Pino-Batlles et al.  J. Alloys and Comp 2024<\/strong>. 995, 174799.<\/p>\n

The role of temperature in the photoluminescence quantum yield (PLQY) of Ag2S-based nanocrystals.<\/a> <\/em>Wang, R. et al.<\/em> Mater. Horizons 2024<\/strong>.  <\/p>\n

Unveiling the crystal and magnetic texture of iron oxide nanoflowers<\/a>. Moya, C. et al. <\/em>Nanoscale 2024<\/strong>,16, 1942-1951.<\/p>\n

Effect of temperature and copper doping on the heterogeneous Fenton-like activity of CuxFe3-xO4 nanoparticles<\/a>. Nu\u00f1ez, N. et al. <\/em>Applied Surface Science 2024<\/strong>, 656, 159655.<\/p>\n

Incidence of the Brownian relaxation process on the magnetic properties of ferrofluids.<\/a> Vajtai, L. et al. <\/em>Nanomaterials 2024<\/strong>, 14, 634.<\/p>\n

Magnetic Induction Heating-assisted synthesis of biodiesel using an alumina\/iron oxide nanocatalyst<\/a>. Corrales-P\u00e9rez, B. et al.<\/em> Fuel 2024<\/strong>, 368, 131659.<\/p>\n

Magnetic harvesting and degradation of microplastics using iron oxide nanoflowers prepared by a scaled-up procedure<\/a>. Gallo-Cordova, A. et al. <\/em>Chemical Engineering Journal 2024<\/strong>, 490, 151725.<\/p>\n

Alternative Metallic Fillers for the Preparation of Conductive Nanoinks for Sustainable Electronics<\/a>. Corrales-P\u00e9rez, B. et al. <\/em>Advanced Functional Materials 2024<\/strong>, 2405326 (1-12).<\/p>\n

Periodic table screening for enhanced positive contrast in MRI and in vivo uptake in glioblastoma<\/a>, Herraiz, A. et al. <\/em>Chemical Science 2024<\/strong>, 15, 8578-859.<\/p>\n

Reversible Alignment of Nanoparticles and Intracellular Vesicles During Magnetic Hyperthermia Experiments<\/a>, Fern\u00e1ndez-Afonso, Y. et al. <\/em>Advanced Functional Materials 2024<\/strong>, 2405334 (1-15).<\/p>\n

Beyond Newton\u2019s Law of Cooling in evaluating magnetic hyperthermia performance: a device-independent procedure<\/a>. Ruta, S. et al. <\/em>Nanoscale Advances 2024<\/strong>, advanced article.<\/p>\n

Mn-ferrite nanoparticles as promising magnetic tags for radiofrequency inductive detection and quantification in lateralflow assays<\/a>. Vanessa Pilati, V. et al. <\/em>Nanoscale Advances 2024<\/strong>,advanced article.<\/p>\n

Effect of precursor concentration, surfactant and temperature on the size, morphology and nanostructure of zero-valent iron nanocrystals synthesised by a polyol route<\/a>. D\u00edaz-Ufano, C. et al.<\/em> Colloids and Surfaces A: Physicochemical and Engineering Aspects 2024<\/strong>, 698, 134604.<\/p>\n

Flexible metallic core\u2013shell nanostructured electrodes for neural interfacing<\/a>. Rodilla, B. L. et al. <\/em>Scientific Reports 2024, 14, 3729.<\/p>\n

Nanorheology and nanoindentation revealed a softening and an increased viscous fluidity of adherent mammalian cells upon increasing the frequency<\/a>. Gisbert, V. et al.<\/em> Small 2024<\/strong>, 20, 2304884.<\/p>\n

Hybrid hydrogels support neural cell culture development under magnetic actuation at high frequency<\/a>. Mart\u00ednez-Ram\u00edrez, J. et al. <\/em>Acta Biomaterialia 2024<\/strong>, 176, 156-172.
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Graphene oxide films as a novel tool for the modulation of myeloid-derived suppressor cell activity in the context of multiple sclerosis<\/a>. Camacho-Toledano, C. et al. <\/em>Nanoscale 2024<\/strong>, 16, 7515-7531.<\/p>\n

2023<\/strong><\/h2>\n

Ion-induced bias in Ag2S luminescent nanothermometers. <\/em><\/a>Par\u00eds Og\u00e1yar M. et .al. <\/em>Nanoscale 2023. <\/strong>15, 17956-17962 .<\/p>\n

From Multi- to Single-Hollow Trimetallic Nanocrystals by Ultrafast Heating. <\/i><\/a>Manzaneda-Gonz\u00e1lez V. et al.<\/i><\/span>  Chem. Mater <\/span>2023<\/strong>.<\/span> 35<\/span>,<\/span> 9603\u20139612<\/span> .<\/span><\/p>\n

Emergence of magnetic nanoparticles in photothermal and ferroptotic therapies. <\/i><\/a>Van de Walle, A. et al.<\/span>  Mater Horiz 2023<\/strong>. 10, 4757-775.<\/p>\n

Design and evaluation of multi-core raspberry-like platinum nanoparticles for enhanced photothermal treatment<\/a>. Gu\u00e9nin, E. et al. Communications Materials 2023<\/strong>, 4, 84.<\/p>\n

Cubic mesocrystal magnetic iron oxide nanoparticle formation by oriented aggregation of cubes in organic media: A rational design to enhance the magnetic hyperthermia efficiency<\/a>. Egea-Benavente, D. et al.<\/em> ACS Applied Materials and Interfaces 2023<\/strong>, 15, 32162-32176. <\/p>\n

Insights into the magnetic properties of single-core and multicore magnetite and manganese-doped magnetite nanoparticles<\/a>. Delgado, A. et al.<\/em> Journal of Physical Chemistry C 2023<\/strong>, 127, 4714\u20134723.<\/p>\n

Biomineralization of magnetic nanoparticles in stem cells<\/a>. Fromain, A. et al.<\/em> Nanoscale 2023<\/strong>, 15, 10097-10109.<\/p>\n

Ag2S biocompatible ensembles as dual OCT contrast agents and NIR imaging probes<\/a>.<\/em> Coro, A. et al. <\/em>Small 2023<\/strong>, 2305026.<\/p>\n

Nanomedical research and development in Spain: improving the treatment of diseases from the nanoscale<\/a>.<\/em> Fern\u00e1ndez, P. et al. <\/em>Frontiers in Bioengineering and Biotechnology 2023<\/strong>, 11, 1191327.<\/p>\n

X-ray nanothermometry of nanoparticles in tumour-mimicking tissues under photothermia<\/a>. L\u00f3pez-M\u00e9ndez, R. et al.<\/em> Advanced Healthcare Materials 2023<\/strong>, 2301863.<\/p>\n

Cellular and molecular processes are differently influenced in primary neural cells by slight changes in the physicochemical properties of multicore magnetic nanoparticles<\/a>. Benayas, E. et al. <\/em>ACS Applied Materials and Interfaces 2023<\/strong>, 15, 17726 – 17741.<\/p>\n

Maximizing the adsorption capacity of iron oxide nanocatalysts for the degradation of organic dyes<\/a>. D\u00edaz-Ufano, C. et al. <\/em>Colloids and Surfaces A: Physicochemical and Engineering Aspects 2023<\/strong>, 658, 130695.
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Inductive heating enhances ripening in the aqueous synthesis of magnetic nanoparticles<\/a>. Ovejero, J.G. et al. <\/em>Crystal Growth and Design 2023<\/span><\/strong>, 23<\/span>, <\/span>59 – 67.<\/span><\/p>\n

High-performance implantable sensors based on anisotropic magnetoresistive La0.67<\/sub>Sr0.33<\/sub>MnO3<\/sub> for biomedical applications<\/a>. Vera, A. et al. <\/em>ACS Biomaterials Science Enigneering 2023<\/strong>, <\/em>9, 1020\u20131029<\/span>.<\/em>
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2022<\/strong><\/h2>\n

Tailoring the magnetic and structural properties of manganese\/zinc doped iron oxide nanoparticles through microwaves-assisted polyol synthesis<\/span><\/a>. Porru, M. et al. <\/em>Nanomaterials 2022, 12, 3304.
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Different coatings on magnetic nanoparticles dictate their degradation kinetics in vivo <\/em>for 15 months after intravenous administration in mice<\/a>. Portilla, Y. et al.<\/em> Journal of Nanobiotechnology 2022<\/strong>, 20, 543.<\/p>\n

Is graphene shortening the path toward spinal cord regeneration? <\/a>Gir\u00e3o, A. et al. <\/em>ACS Nano 2022, 16, 13430 – 13467<\/span>.<\/em><\/p>\n

Iron oxide and iron oxyhydroxide nanoparticles impair SARS-CoV-2 infection of cultured cells<\/a>. DeDiego, M. L. et al.<\/em> Journal of Nanotechnology 2022, 20, 352.
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Tunable control of the structural features and related physical properties of Mnx<\/sub>Fe3- x<\/sub>O4n<\/sub>anoparticles: Implication on their heating performance by magnetic hyperthermia<\/a><\/span>. <\/span><\/strong>Del Sol Fern\u00e1ndez, S. et al. <\/em>Journal of Physical Chemistry C 2022, 126, 10110-10128.
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Superparamagnetic-blocked state transition under alternating magnetic fields: towards determining the magnetic anisotropy in magnetic suspensions<\/a>. Cabrera, D. et al.<\/em> Nanoscale 2022, 24.<\/p>\n

Superparamagnetic iron oxide nanoparticles decorated mesoporous silica nanosystem for combined antibiofilm therapy<\/a>. \u00c1lvarez, E. et al.<\/em> Pharmaceutics 2022, 14, 162.<\/p>\n

Microwave-assisted Nix<\/sub>Fe1\u2212x<\/sub> nanoclusters ultra-stable to oxidation in aqueous media<\/a>. Santana-Otero, A. et al. <\/em>Nanoscale 2022, 14, 16639-16646.
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Engineering biomaterials for neural applications: Targetting traumatic brain and spinal cord injuries<\/a>. Springer-Nature (2022). ISBN: 978-3-030-81399-4. Editors: Elisa L\u00f3pez-Dolado and M. Concepci\u00f3n Serrano. Co-authors: Chapters 1 and 3 (M. Concepci\u00f3n Serrano) and Chapter 7 (M. Puerto Morales, Sabino Veintemillas and Jes\u00fas G. Ovejero).<\/p>\n

The surface coating of iron oxide nanoparticles drives their intracellular trafficking and degradation in endolysosomes differently depending on the cell type<\/a>. Portilla, Y. et al. Biomaterials 2022, 281, 121365.<\/span><\/p>\n

Unravelling an amine-regulated crystallization crossover to prove single\/multicore effects on the biomedical and environmental catalytic activity of magnetic iron oxide colloids<\/a>. Gallo-C\u00f3rdova, A. et al. <\/em>Journal of Colloid and Interface Science 2022, 608, Part B, 1585-1597.<\/p>\n

2021<\/strong><\/h2>\n

Understanding mnps behaviour in response to amf in biological milieus and the effects at the cellular level: Implications for a rational design that drives magnetic hyperthermia therapy toward clinical implementation<\/a><\/strong>. Egea-Benavente, D. et al.<\/em> Cancers 2021, 13, 4583.<\/p>\n

Nanoparticles for magnetic heating: When two (or more) is better than one<\/a>. Ovejero, J. G. et al.<\/em> Materials 2021, 14, 6416.<\/p>\n

Nanostructured gold electrodes promote neural maturation and network connectivity<\/span><\/a>. Dom\u00ednguez-Bajo, A. et al. <\/em>Biomaterials 2021, 279, 121186.<\/span><\/p>\n

How size, shape and assembly of magnetic nanoparticles give rise to different hyperthermia scenarios<\/a><\/strong>. Gavil\u00e1n, H. et al. <\/em>Nanoscale 2021, 13, 15631-15646.<\/p>\n

Selective magnetic nanoheating: Combining iron oxide nanoparticles for multi-hot-spot induction and sequential regulation<\/a>. Ovejero, J.G. et al. <\/em>Nano Letters 2021, 21, 7213-7220.<\/span><\/p>\n

Reproducibility and scalability of magnetic nanoheater synthesis<\/a><\/strong>. Ovejero, J.G. et al.<\/em> Nanomaterials 2021, 11, 2059.<\/p>\n

Mixing iron oxide nanoparticles with different shape and size for tunable magneto-heating performance<\/a><\/strong>. Ovejero, J.G. et al.<\/em> Nanoscale 2021, 13, 5714-5729.<\/p>\n

Improving degradation of real wastewaters with self-heating magnetic nanocatalysts<\/a><\/strong>. Gallo-Cordova, A. et al.<\/em> Journal Cleaner Production 2021, 308, 127385.<\/p>\n

Engineering iron oxide nanocatalysts by a microwave-assisted polyol method for the magnetically induced degradation of organic pollutants<\/a><\/strong>. Gallo-Cordova, A. et al.<\/em> Nanomaterials, 2021, 11, 1052.<\/p>\n

Iron oxide nanoparticle coatings dictate cell outcomes despite the influence of protein coronas<\/a><\/strong>. Portilla, Y. et al.<\/em> ACS Applied Materials Interfaces 2021, 13, 7924\u20137944.<\/p>\n

Whither magnetic hyperthermia? A tentative roadmap<\/a><\/strong>. Rubia-Rodr\u00edguez, I. et al.<\/em> Materials, 2021, 14, 1\u201337.<\/p>\n

Effective actions of ion release from mesoporous bioactive glass and macrophage mediators on the differentiation of osteoprogenitor and endothelial progenitor cells<\/a><\/strong>. Polo-Montalvo, A. et al.<\/em> Pharmaceutics, 2021, 13, 1152.<\/p>\n

Effects of ipriflavone-loaded mesoporous nanospheres on the differentiation of endothelial progenitor cells and their modulation by macrophages<\/a><\/strong>. Casarrubios, L. et al.<\/em> Nanomaterials, 2021, 11, 1102.<\/p>\n

Temperature dependence of the magnetic interactions taking place in monodisperse magnetite nanoparticles having different morphologies<\/a><\/strong>. Navarro, E. et al.<\/em> AIP Advances 2021, 11, 15025.<\/p>\n

2020<\/strong><\/h2>\n

Tailor-made PEG coated iron oxide nanoparticles as contrast agents for long lasting magnetic resonance molecular imaging of solid cancers<\/a><\/strong>. Lazaro-Carrillo, A. et al.<\/em> Materials Science and Engineering C 2020, 107, 110262.<\/p>\n

Combined magnetoliposome formation and drug loading in one step for efficient AC-magnetic field remote controlled drug release<\/a><\/strong>. Fortes Brollo, M.E. et al.<\/em> ACS Applied Materials Interfaces 2020, 12, 4295-4307.<\/p>\n

Continuous production of magnetic iron oxide nanocrystals by oxidative precipitation<\/a><\/strong>. Asimakidou, T. et al.<\/em> Chemical Engineering Journal 2020, 124593.<\/p>\n

Superparamagnetic nanosorbent for water purification: Assessment of the adsorptive removal of lead and methyl orange from aqueous solutions<\/a><\/strong>. Gallo-Cordova, A. et al.<\/em> Science Total Environment 2020, 711, 134644.<\/p>\n

3D Reduced graphene oxide scaffolds with a combinatorial fibrous-porous architecture for neural tissue engineering<\/a><\/strong>. Gir\u00e3o A. et al.<\/em> ACS Applied Materials Interfaces 2020, 12, 38962-38975.<\/p>\n

Graphene Oxide microfibers promote regenerative responses after chronic implantation in the cervical injured spinal cord<\/a><\/strong>. Dom\u00ednguez-Bajo, A. et al.<\/em> ACS Biomaterials Science and Engineering 2020, 6, 2401-2414.<\/p>\n

Interfacing neurons with nanostructured electrodes modulates synaptic circuit features<\/a><\/strong>. Dom\u00ednguez-Bajo, A. et al.<\/em> Advanced Biosystems 2020, 4, 200017.<\/p>\n

Silicon substituted hydroxyapatite\/VEGF scaffolds stimulate bone regeneration in osteoporotic sheep<\/a><\/strong> Casarrubios, L. et al.<\/em> Acta Biomaterialia 2020, 101, 544-553.<\/p>\n

Smartphone-based colorimetric method to quantify iron concentration and to determine the nanoparticle size from magnetic nanoparticles suspensions<\/a><\/strong>. Fernadez-Afonso, Y. et al.<\/em> Particle and Particle Systems Characterization 2020, 37, 2000032.<\/p>\n

Enzyme-induced formation of Iron hybrid nanostructures with different morphologies<\/a><\/strong>. Benavente, R. et al.<\/em> Nanoscale 2020, 12, 12917.<\/p>\n

New insights in the structural analysis of maghemite and (MFe2O4, M= Co, Zn) ferrite nanoparticles synthetized by Microwave assisted – Polyol process<\/a><\/strong>. Gallo-Cordova, A. et al.<\/em> Materials Chemistry Frontiers 2020, 4, 3063-3073.<\/p>\n

2019<\/strong><\/h2>\n

Slow magnetic relaxation in well crystallized, monodispersed, octahedral and spherical magnetite nanoparticles<\/a><\/strong>. Navarro, E. et al.<\/em> AIP Advances 2019, 9.<\/p>\n

Effect of the surface charge on the adsorption capacity of chromium (VI) of iron oxide magnetic nanoparticles prepared by microwave-assisted synthesis<\/a><\/strong>. Gallo-Cordova, A. et al.<\/em> Water 2019, 11, 2372.<\/p>\n

Rheological behavior of magnetic colloids in the borderline between ferrofluids and magnetorheological fluids<\/a><\/strong>, Shahrivar, K. et al.<\/em> Journal Rheology 2019, 63, 547-558.<\/p>\n

Flower-like Mn-doped magnetic nanoparticles functionalized with AV-B3-integrin-ligand to efficiently induce intracellular heat after AMF-exposition triggering glioma cell death<\/a><\/strong>. Del Sol-Fern\u00e1ndez, S. et al.<\/em> ACS Applied Materials and Interfaces 2019, 11, 26648-26663.<\/p>\n

Design strategies for shape-controlled magnetic iron oxide nanoparticles<\/a><\/strong>, Roca, A.G. et al.<\/em> Advanced Drug Delivery Reviews 2019, 138, 68.<\/p>\n

Understanding the influence of a bifunctional polyethylene glycol derivative in the protein corona formation around iron oxide nanoparticles<\/a><\/strong>, Ruiz, A. et al.<\/em> Materials 2019, 12, 2218.<\/p>\n

99mTc-, 90Y-, and 177Lu-labeled iron oxide nanoflowers designed for potential use in dual magnetic hyperthermia\/radionuclide cancer therapy and diagnosis<\/a><\/strong>. Ognjanovi\u0107, M. et al.<\/em> ACS Applied Materials Interfaces 2019 11, 41109-41117.<\/p>\n

Elongated magnetic nanoparticles with high-aspect ratio: a nuclear relaxation and specific absorption rate investigation<\/a><\/strong>, Avolio, M. et al.<\/em> Phys Chem Chem Phys 2019, 21, 18741-18752.<\/p>\n

Cell-promoted nanoparticle aggregation decreases nanoparticle-induced hyperthermia under an alternating magnetic field independently of nanoparticle coating, core size, and subcellular localization<\/a><\/strong>, Mej\u00edas, R. et al.<\/em> ACS Applied Materials and Interfaces 2019, 11, 340-355.<\/p>\n

Doped-iron oxide nanocrystals synthesized by one-step aqueous route for multi-imaging purposes<\/a><\/strong>, Luengo, Y. et al.<\/em> J Phys Chem C 2019, 123, 7356-7365.<\/p>\n

Versatile graphene-based platform for robust nanobiohybrid interfaces<\/a><\/strong>. Bueno, R. et al.<\/em> ACS Omega 2019, 4, 3287-3297.<\/p>\n

Cu-Doped extremely small iron oxide nanoparticles with large longitudinal relaxivity: One-pot synthesis and in vivo targeted molecular imaging<\/a><\/strong>, Fern\u00e1ndez-Barahona, I. et al.<\/em> ACS Omega 2019, 4, 2719-2727.<\/p>\n

Do biomedical engineers dream of graphene sheets?<\/a><\/strong>, Gir\u00e3o, A.F. et al.<\/em> Biomaterials Science 2019, 7, 1228-1239.<\/p>\n

Myelinated axons and functional blood vessels populate mechanically compliant rGO foams in chronic cervical hemisected rats<\/a><\/strong>, Dom\u00ednguez-Bajo, A. et al.<\/em> Biomaterials 2019, 192, 461-474.<\/p>\n

Synergistic effect of Si-hydroxyapatite coating and VEGF adsorption on Ti6Al4V-ELI scaffolds for bone regeneration in an osteoporotic bone environment<\/a><\/strong>, Izquierdo-Barba, I. et al.<\/em> Acta Biomaterialia 2019, 83, 456-466.<\/p>\n

Aggregation effects on the magnetic properties of iron oxide colloids<\/a><\/strong>, Guti\u00e9rrez, L. et al.<\/em> Nanotechnology 2019, 30, 112001.<\/p>\n

Improving the reliability of the iron concentration quantification for iron oxide nanoparticle suspensions: A two-institutions study<\/a><\/strong>. Costo, R. et al.<\/em> Analytical Bioanalytical Chemistry 2018, 411, 1895\u20131903.<\/p>\n

2018<\/b><\/h2>\n

Development and application of nanoparticles in biomedical imaging<\/a><\/strong>, Rosado-De-Castro, P.H. et al.<\/em> Contrast Media and Molecular Imaging 2018, 1403826.<\/p>\n

Response of macrophages and neural cells in contact with reduced graphene oxide microfibers<\/a><\/strong>, Serrano, M.C. et al.<\/em> Biomaterials Science 2018, 6, 2987-2997.<\/p>\n

Reductive nanometric patterning of graphene oxide paper using electron beam lithography<\/a><\/strong>, Gon\u00e7alves, G. et al.<\/em> Carbon 2018, 129, 63-75.<\/p>\n

Magnetic properties of nanoparticles as a function of the spatial distribution on liposomes and cells<\/a><\/strong>. Fortes Brollo, M.E. et al.<\/em> Phys. Chem. Chem. Phys. 2018, 20, 17829-17838.<\/p>\n

Effect of the sodium polyacrylate on the magnetite nanoparticles produced by green chemistry routes: Applicability in forward osmosis<\/a><\/strong>. Zufia-Rivas, J. et al.<\/em> Nanomaterials 2018, 8, E470-413.<\/p>\n

RGD-Functionalized Fe3O4 nanoparticles for magnetic hyperthermia<\/a><\/strong>. Arriortua O.K. et al.<\/em> Colloids and Surfaces B: Biointerfaces 2018, 165, 315-324.<\/p>\n

Unravelling the mechanisms that determine the uptake and metabolism of magnetic single and multicore nanoparticles in a Xenopus laevis model<\/a><\/strong>. Marin-Barba, M. et al.<\/em> Nanoscale 2018, 10, 690-704.<\/p>\n

2017<\/strong><\/h2>\n

Favorable biological responses of neural cells and tissue interacting with graphene oxide microfibers<\/a><\/strong>. Gonza\u0301lez-Mayorga, A. et al.<\/em> ACS Omega 2017, 2, 8253-8263.<\/p>\n

Graphene-derived materials interfacing the spinal cord: Outstanding in vitro and in vivo findings<\/a><\/strong>. Dom\u00ednguez-Bajo, A. et al.<\/em> Front. Syst. Neurosci. 2017, 11, 71.<\/p>\n

Ice as a green-structure-directing agent in the synthesis of macroporous MWCNTs and chondroitin sulphate composites<\/a><\/strong>. Nardecchia, S. et al.<\/em> Materials 2017, 10, 355.<\/p>\n

Key parameters on the microwave assisted synthesis of magnetic nanoparticles for MRI contrast agents<\/a><\/strong>. Fortes Brollo, M.E. et al.<\/em> Contrast Media and Molecular Imaging 2017, 8902424.<\/p>\n

Formation mechanism of maghemite nanoflowers synthesized by polyol mediated process<\/a><\/strong>. Gavil\u00e1n, H. et al.<\/em> ACS Omega 2017, 2, 7172\u20137184.<\/p>\n

Time-course assessment of the aggregation and metabolization of magnetic nanoparticles<\/a><\/strong>. Rojas, J. et al.<\/em> Acta Biomaterialia 2017, 58, 181-195.<\/p>\n

Colloidal flower-shaped iron oxide nanoparticles: Synthesis strategies and coatings<\/a><\/strong>. Gavil\u00e1n, H. et al.<\/em> Part. Part. Syst. Charact. 2017, 34, 1700094.<\/p>\n

One-step fast synthesis of nanoparticles for MRI: coating chemistry as the key variable determining positive or negative contrast<\/a><\/strong>, Pellico, J. et al.<\/em> Langmuir 2017, 33, 10239-10247.<\/p>\n

The internal structure of magnetic nanoparticles determines the magnetic response<\/a><\/b>. Pacakova, B. et al.<\/em> Nanoscale 2017, 9, 5129-5140.<\/p>\n

How shape and internal structure affect the magnetic properties of anisometric magnetite nanoparticles<\/a><\/b>. Gavilan, H. et al.<\/em> Acta Materialia 2017, 125, 416-424.<\/p>\n

Freeze-dried cylinders carrying chitosan nanoparticles for vaginal peptide delivery<\/a><\/b>. Marciello, M. et al.<\/em> Carbohyd. Polym. 2017, 170, 43-51.<\/p>\n

Conversion of biogenic aragonite into hydroxyapatite scaffolds in boiling solutions<\/a><\/b>. Reinares-Fisac, D. et al.<\/em> Crystengcomm 2017, 19, 110-116.<\/p>\n

Size analysis of single-core magnetic nanoparticles<\/a><\/b>. Ludwig, F. et al.<\/em> J. Magn. Magn. Mater. 2017, 427, 19-24.<\/p>\n

SAXS analysis of single- and multi-core iron oxide magnetic nanoparticles<\/a><\/b>. Szczerba, W. et al.<\/em> J. Appl. Crystallogr. 2017, 50, 481-488.<\/p>\n

Studies of the colloidal properties of superparamagnetic iron oxide nanoparticles functionalized with platinum complexes in aqueous and PBS buffer media<\/a><\/b>. da Silva, G.B. et al.<\/em> J Brazil Chem Soc 2017, 28, 731-739.<\/p>\n

2016<\/strong><\/h2>\n

Superparamagnetic iron oxide nanoparticle uptake alters M2 macrophage phenotype, iron metabolism, migration and invasion<\/b>. Rojas, J.M. et al.<\/em> Nanomed Nanotechnol Biol Med 2016, 12, 1127-1138.<\/p>\n

I<\/strong>n-situ particles reorientation during magnetic hyperthermia application: Shape matters twice<\/b>. Simeonidis, K. et al.<\/em> Sci. Rep. 2016, 6, 38382.<\/p>\n

Counterion and solvent effects on the size of magnetite nanocrystals obtained by oxidative precipitation<\/b>. Luengo, Y. et al.<\/em> J. Mater. Chem. C 2016, 4, 9482-9488.<\/p>\n

Profilin-2, a new player in iron metabolism<\/b>. Luscieti, S. et al.<\/em> Am. J. Hematol. 2016, 91, E42-E42.<\/p>\n

Oriented attachment of recombinant proteins to agarose-coated magnetic nanoparticles by means of a beta-trefoil lectin domain<\/b>. Acebron, I. et al.<\/em> Bioconjugate. Chem. 2016, 27, 2734-2743.<\/p>\n

Effect of nanoclustering and dipolar interactions in heat generation for magnetic hyperthermia<\/b>. Coral, D.F.et al.<\/em> Langmuir 2016, 32, 1201-1213.<\/p>\n

Tuning morphology and magnetism of magnetite nanoparticles by calix[8]arene-induced oriented aggregation<\/b>. Vita, F. et al.<\/em> Crystengcomm 2016, 18, 8591-8598.<\/p>\n

Subsurface imaging of silicon nanowire circuits and iron oxide nanoparticles with sub-10nm spatial resolution<\/b>. Perrino, A.P. et al.<\/em> Nanotechnology 2016, 27, 700-710.<\/p>\n

Versatile theranostics agents designed by coating ferrite nanoparticles with biocompatible polymers<\/b>. Zahraei, M. et al.<\/em> Nanotechnology 2016, 27, 0]00-12.<\/p>\n

Detailed magnetic monitoring of the enhanced magnetism of ferrihydrite along its progressive transformation into hematite<\/b>. Gutierrez, L. et al.<\/em> J Geophys Res 2016, 121, 4118-4129.<\/p>\n

Fast synthesis and bioconjugation of Ga-68 core-doped extremely small iron oxide nanoparticles for PET\/MR imaging<\/b>. Pellico, J. et al.<\/em> Contrast Media Mol I 2016, 11, 203-210.<\/p>\n

Metal homeostasis regulators suppress FRDA phenotypes in a Drosophila model of the disease<\/b>. Soriano, S. et al.<\/em> PLoS One 2016, 11.<\/p>\n

Improving the magnetic heating by disaggregating nanoparticles<\/b>. Arteaga-Cardona, F. et al.<\/em> J. Alloy. Compd. 2016, 663, 636-644.<\/p>\n

Recent advances in the preparation and application of multifunctional iron oxide and liposome-based nanosystems for multimodal diagnosis and therapy<\/b>. Marciello, M. et al.<\/em> Interface Focus 2016, 6.<\/p>\n

Dose-response bioconversion and toxicity analysis of magnetite nanoparticles<\/b>. Ruiz, A. et al.<\/em> IEEE Magn. Lett. 2016, 7.<\/p>\n

Protein-modified magnetic nanoparticles for biomedical applications<\/b>. Talelli, M. et al.<\/em> Curr. Org. Chem. 2016, 20, 1252-1261.<\/p>\n

Thermodynamic charge-to-mass sensor for colloids, proteins, and polyelectrolytes<\/b>. van Rijssel, J. et al.<\/em> ACS Sensors 2016, 1, 1344-1350.<\/p>\n

Fast synthesis and bioconjugation of 68Ga core-doped extremely small iron oxide nanoparticles for PET\/MR imaging<\/a><\/strong>. Contrast Media and Molecular Imaging 2016, 11, 203-210.<\/p>\n

Superparamagnetic iron oxide nanoparticle uptake alters M2 macrophage phenotype, iron metabolism, migration and invasion<\/a><\/strong>. Rojas, J.M. et al.<\/em> Nanomedicine 2016, 12, 1127-1138.<\/p>\n

2015<\/strong><\/h2>\n

Dimercaptosuccinic acid-coated magnetic nanoparticles as a localized delivery system in cancer immunotherapy: tumor targeting, in vivo detection and quantification, long-term biodistribution, biotransformation and toxicity<\/strong>. Mejias, R. et al.<\/em> Book Chapter in \u00abAdvanced Materials: Health Care\u00bb, WILEY-Scrivener Publishing LLC, USA (2015)<\/strong><\/p>\n

SOL-GEL magnetic materials<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Book Chapter in \u00abHbk Sol-Gel Vol. 2\u00bb, Wiley-VCH Books (2015)<\/strong><\/p>\n

Challenges for diagnosis of malaria and neglected tropical diseases in elimination settings<\/strong>. Karl, S. et al.<\/em> Biomed Research International 2015, 270756.<\/p>\n

Tissue iron distribution assessed by MRI in patients with iron loading anemias<\/strong>. Guti\u00e9rrez, L. et al.<\/em> PLOS One 2015, 10, e0139220.<\/p>\n

Improving magnetic properties of ultrasmall magnetic nanoparticles by biocompatible coatings<\/strong>. Costo, R. et al.<\/em> J. Appl. Phys. 2015, 117, 14, 064311.<\/p>\n

Bismuth labeling for the CT assessment of local administration of magnetic nanoparticles<\/strong>. Veintemillas-Verdaguer, S. et al.<\/em> Nanotechnology 2015, 26, 135101.<\/p>\n

A single picture explains the diversity of hyperthermia response of magnetic nanoparticles<\/strong>. Conde-Leboran, I. et al.<\/em> J Phys Chem C 2015, 119, 15698\u201315706.<\/p>\n

Tuning the magnetic properties of Co-ferrite nanoparticles through the 1,2-hexadecanediol concentration in the reaction mixture<\/strong>. Moya, C. et al.<\/em> Phys Chem Chem Phys 2015, 17, 13143-13149.<\/p>\n

Inducing glassy magnetism in Co-ferrite nanoparticles through crystalline nanostructure<\/strong>. Moya, C. et al.<\/em> J Mater Chem C 2015, 3, 4522-4529.<\/p>\n

Polyethylenimine-coated SPIONs trigger macrophage activation through TLR-4 signaling and ROS production and modulate podosome dynamics<\/strong>. Mulens-Arias, V. et al.<\/em> Biomaterials 2015, 52, 494-506.<\/p>\n

Electrochemical synthesis of core-shell magnetic nanowires<\/strong>. Ovejero, J.G. et al.<\/em> J Magnetism Magnetic Mater 2015, 144-147.<\/p>\n

A value-added exopolysaccharide as a coating agent for MRI nanoprobes<\/a><\/strong>. Palma, S.I. et al.<\/em> Nanoscale 2015, 7, 14272-14283.<\/p>\n

Polyethylenimine-coated SPION exhibits potential intrinsic anti-metastatic properties inhibiting migration and invasion of pancreatic tumor cells<\/a><\/strong>. Mulens-Arias, V. et al.<\/em> J Controlled Release 2015, 216, 78-92.<\/p>\n

Hematotoxicity of magnetite nanoparticles coated with polyethylene glycol: In vitro and in vivo study<\/a><\/strong>. Ruiz, A. et al.<\/em> Toxicology Report 2015, 4, 1555-1564.<\/p>\n

Biotransformation of magnetic nanoparticles as a function of the coating in a rat model<\/strong>. Ruiz, A. et al.<\/em> Nanoscale 2015, 7, 16321-16329.<\/p>\n

Classification of magnetic nanoparticle systems \u2013 Synthesis, standardization and analysis methods in the NanoMag projec<\/strong>. Bogren, S. et al.<\/em> Int J Mol Sci 2015, 16, 20308-20325.<\/p>\n

Degradation of magnetic nanoparticles mimicking lysosomal conditions followed by ac susceptibility<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Biomed Eng Biomed Tech 2015, 60, 417-425.<\/p>\n

Safety assessment of chronic oral exposure to iron oxide nanoparticles<\/strong>. Chamorro, S. et al.<\/em> Nanotechnology 2015, 26, 205101.<\/p>\n

The affinity of magnetic microspheres for Schistosoma eggs<\/strong>. Renata RF Candido R. et al.<\/em> International journal for parasitology 2015, 45, 43-50.<\/p>\n

Manipulating directional cell motility using intracellular superparamagnetic nanoparticles<\/strong>. Bradshaw, M. et al.<\/em> Nanoscale 2015, 7, 4884-4889.<\/p>\n

Effects of phase transfer ligands on monodisperse iron oxide magnetic nanoparticles<\/strong>. Palma, S. et al.<\/em> Journal of Colloid and Interface Science 2015, 437, 147\u2013155.<\/p>\n

Towards MRI T2 contrast agents of increased efficiency<\/strong>. Branca, M. et al.<\/em> Journal of Magnetism and Magnetic Materials 2015, 377, 348-353.<\/p>\n

Improving magnetic properties of ultrasmall magnetic nanoparticles by biocompatible coatings<\/strong>. Costo, R. et al.<\/em> J. Appl. Phys. 2015, 117, 064311.<\/p>\n

Synthesis methods to prepare single- and multi-core magnetic nanoparticles for biomedical applications<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Dalton Transactions 2015, 44, 2943-2952.<\/p>\n

Covalent coupling of gum arabic onto superparamagnetic iron oxide nanoparticles for MRI cell labeling: physiochemical and in vitro characterization<\/strong>. Palma, S. et al.<\/em> Contrast Media and Molecular Imaging 2015, 10, 320-328.<\/p>\n

Particle interactions in liquid magnetic colloids by zero field cooled measurements and heating efficiency effects<\/strong>. de la Presa, P. et al.<\/em> J Phys Chem C 2015, 119, 11022\u201311030.<\/p>\n

2014<\/strong><\/h2>\n

Modulation of Magnetic Heating via Dipolar Magnetic Interactions in Monodisperse and Crystalline Iron Oxide Nanoparticles<\/strong>. Salas, G. et al.<\/em> J Phys Chem C 2014, 118, 19985\u221219994.<\/p>\n

Structural disorder versus spin canting in monodisperse maghemite nanocrystals<\/strong>. Kubickova, S. et al.<\/em> Applied Physics Letters 2014, 104, 223105.<\/p>\n

Magnetic nanoparticles coated with dimercaptosuccinic acid: development, characterization and application in biomedicine<\/strong>. Ruiz, A. et al.<\/em> J Nanopart Res 2014, 16, 2589.<\/p>\n

Magnetic, structural and particle size analysis of single- and multi-core magnetic nanoparticles<\/strong>. Ludwig, F. et al.<\/em> IEEE Transactions on Magnetism 2014, 50, 5300204.<\/p>\n

Structural determination of Bi-doped magnetite multifunctional nanoparticles for contrast imaging<\/strong>.
\nLaguna-Marco, M.A. et al.<\/em> Phys Chem Chem Phys 2014, 16, 18301-18310.<\/p>\n

Magnetic nanocrystals for biomedical applications<\/strong>. Veintemillas-Verdaguer, S. et al.<\/em> Progress in Crystal Growth and Characterization of Materials 2014, 60, 80-86.<\/p>\n

Multiplying magnetic hyperthermia response by nanoparticle assembling<\/strong>. Serantes, D. et al.<\/em> J Phys Chem C 2014, 118, 5927-5934.<\/p>\n

Efficient and safe internalization of magnetic iron oxide nanoparticles designed for biomedical applications<\/strong>. Calero, M. et al.<\/em> Nanomedicine: Nanotechnology, Biology and Medicine 2014, 10, 733-743.<\/p>\n

Prospects for magnetic nanoparticles in systemic administration: synthesis and quantitative detection<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Phys Chem Chem Phys 2014, 16, 4456.<\/p>\n

Variability and consistency in respiratory responses to particles with a geogenic origin<\/strong>. Zosky, G.R. et al.<\/em> Respirology 2014, 19, 58-66.<\/p>\n

2013<\/strong><\/h2>\n

Development of mgnetic nanoparticles for cancer gene therapy: A comprehensive review<\/strong>. Mulens, V. et al.<\/em> ISRN Nanomaterials 2013, 646284.<\/p>\n

Biophysical and genetic analysis of iron partitioning and ferritin function in Drosophila Melanogaster<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Metallomics 2013, 5, 997-1005.<\/p>\n

Multiparametric toxicity evaluation of SPIONs by high content screening technique: Identification of biocompatible multifunctional nanoparticles for nanomedicine<\/strong>. Prina-Mello, A. et al.<\/em> IEEE T Magn 2013, 49, 377-382.<\/p>\n

Size sorting of ultrasmall magnetic nanoparticles and their aggregates behaviour<\/strong>. Costo, R. et al.<\/em> Mater Res Bull 2013, 48, 4294-4300.<\/p>\n

Deferiprone and idebenone rescue frataxin depletion phenotypes in a Drosophila model of Friedreich’s ataxia<\/strong>. Soriano, S. et al.<\/em> Gene 2013, 521, 274-281.<\/p>\n

Key parameters for scaling up the synthesis of magnetite nanoparticles in organic media: Stirring rate and growth kinetic<\/strong>. Ibarra-Sanchez, J.J. et al.<\/em> Ind Eng Chem Res 2013, 52, 17841-17847.<\/p>\n

Bulk metastable cobalt in fcc crystal structure<\/strong>. Meng, Q.K. et al.<\/em> J Alloy Compd 2013, 580, 187-190.<\/p>\n

Relationship between physico-chemical properties of magnetic fluids and their heating capacity<\/strong>. Salas, G. et al.<\/em> Int J Hyperthermia 2013, 29, 768-776.<\/p>\n

Iron bioavailability from ingested iron oxide nanoparticles<\/strong>. Chamorro, S. et al.<\/em> Am J Hematol 2013, 88, E112-E113.<\/p>\n

Analysis of iron distribution and magnetic characterization of Schistosoma mansoni and Schistosoma japonicum eggs<\/strong>. Karl, S. et al.<\/em> Am J Hematol 2013, 88, E117-E118.<\/p>\n

Large scale production of biocompatible magnetite nanocrystals with high saturation magnetization values through green aqueous synthesis<\/strong>. Marciello, M. et al.<\/em> J Mater Chem B 2013, 1, 5995-6004.<\/p>\n

Synthesis of heterogeneous enzyme-metal nanoparticle biohybrids in aqueous media and their applications in C-C bond formation and tandem catalysis<\/strong>. Filice, M. et al.<\/em> Chem Commun 2013, 6876-6878.<\/p>\n

Long term biotransformation and toxicity of dimercaptosuccinic acid-coated magnetic nanoparticles support their use in biomedical applications<\/strong>. Mejias, R. et al.<\/em> J Control Release 2013, 171, 225-233.<\/p>\n

Short-chain PEG molecules strongly bound to magnetic nanoparticle for MRI long circulating agents<\/a><\/strong>. Ruiz, A. et al.<\/em> Acta Biomaterialia 2013, 9, 6421-6430.<\/p>\n

Effect of anesthesia on magnetic nanoparticle biodistribution after intravenous injection<\/strong>. Gutierrez, L. et al.<\/em> IEEE Transactions on Magnetics 2013, 49, 398-401.<\/p>\n

2012<\/strong><\/h2>\n

Fighting cancer with magnetic nanoparticles and immunotherapy<\/strong>. Guti\u00e9rrez, L. et al.<\/em> Progress in Biomedical Optics and Imaging – Proceedings of SPIE 2012, 8232. Colloidal Nanocrystals for Biomedical Applications 2012, VII, 82320X.<\/p>\n

Study of heating efficiency as a function of concentration, size, and applied field in \u03b3-Fe2O3 nanoparticles<\/strong>. de la Presa, P. et al.<\/em> J Physical Chemistry C 2012, 116, 25602-25610.<\/p>\n

Controlled synthesis of uniform magnetite nanocrystals with high-quality properties for biomedical applications<\/strong>. Salas, G. et al.<\/em> J Mater Chem 2012, 22, 21065-21075.<\/p>\n

Synthesis of aqueous ferrofluids of ZnxFe3-xO4 nanoparticles by citric acid assisted hydrothermal-reduction route for magnetic hyperthermia applications<\/strong>. Behdadfar, B. et al.<\/em> J Magnetism Magnetic Materials 2012, 324, 2211-2217.<\/p>\n

Core\/shell magnetite\/Bismuth oxide nanocrystals with tunable size, colloidal, and magnetic propertie<\/strong>. Andre\u0301s-Verge\u0301s, M. et al.<\/em> Chemistry of Materials 2012, 24, 319-324.<\/p>\n

Synthesis and surface modification of uniform MFe2O4 (M = Fe, Mn, and Co) nanoparticles with tunable sizes and functionalities<\/strong>. Cabrera, L.I. et al.<\/em> Journal of Nanoparticle Research 2012, 14, 873.<\/p>\n

Biological applications of magnetic nanoparticles<\/strong>. Colombo, M. et al.<\/em> Chemical Society Reviews 2012, 41, 4306-4334.<\/p>\n

Ultrasmall iron oxide nanoparticles for biomedical applications: Improving the colloidal and magnetic properties<\/b>. Costo, C. et al.<\/em> Langmuir 2012, 28, 178-185.<\/p>\n

Uniform magnetite nanoparticles larger than 20 nm synthesized by an aqueous route<\/strong>. Veintemillas-Verdaguer, S. et al.<\/em> Magnetic Particle Imaging: A Novel Spio Nanoparticle Imaging Technique 2012, 140, 380.<\/p>\n

Control of cristallite orientation and size in Fe and FeCo nanoneedles<\/strong>. Mendoza-Res\u00e9ndez, R. et al.<\/em> Nanotechnology 2012, 23, 225601.<\/p>\n

2011<\/strong><\/h2>\n

The iron oxides strike back: From biomedical applications to energy storage devices and photoelectrochemical water splitting<\/strong>. Tartaj, P. et al.<\/em> Advanced Materials 2011, 23, 5243-5249.<\/p>\n

Dimercaptosuccinic acid-coated magnetite nanoparticles for magnetically guided in vivo delivery of interferon gamma for cancer immunotherapy<\/strong>. Mej\u00edas, R. et al.<\/em> Biomaterials 2011, 32, 2938-2952.<\/p>\n

Magnetic Capsules for NMR Imaging: Effect of Magnetic Nanoparticles Spatial Distribution and aggregation<\/strong>. Abbasi, A.Z. et al.<\/em> J Phys Chem C 2011, 115, 6257-6264.<\/p>\n

Magnetic nanoparticles with bulk-like properties<\/strong>. Batlle, X. et al.<\/em> J Appl Phys 2011, 109, 07B524-1-6.<\/p>\n

AC magnetic susceptibility study of in vivo nanoparticle biodistribution<\/strong>. Gutierrez, L. et al.<\/em> J. Phys. D: Appl. Phys 2011, 44, 255002-255011.<\/p>\n

Nanopart\u00edculas magn\u00e9ticas para biomedicina<\/b>. Roca, G. et al.<\/em> Acta Cient\u00edfica y Tecnol\u00f3gica 2011, 18, 32-38.<\/p>\n

One step production of magnetic nanoparticle films by laser pyrolysis inside a chemical vapour deposition reactor<\/strong>. de Castro V. et al.<\/em> Thin Solid Films 2011, 519, 7677\u20137682.<\/p>\n","protected":false},"excerpt":{"rendered":"

2025 Iron oxide nanospheres: dual functionality as MRI contrast agents and magnetic fluid hyperthermia therapeutics. Porru, M., Brero, F., D\u00ecaz-Ufano, C., … Morales, M.D.P., Lascialfari, A. Dalton Transactions, 2025, 54(22), pp. 9057\u20139068 The Second Life of Cobalt MOF: Alternating Magnetic Field- Assisted Electrocatalytic Oxygen Evolution Reaction in MOF-derived Nanoparticles. del Rio-Rodr\u00edguez, J.L., Guti\u00e9rrez-Tarri\u00f1o, S., M\u00e1rquez, I., … Olloqui-Sariego,…
Leer m\u00e1s<\/a><\/p>\n","protected":false},"author":46,"featured_media":0,"parent":0,"menu_order":2,"comment_status":"closed","ping_status":"open","template":"","meta":{"ngg_post_thumbnail":0,"footnotes":""},"class_list":["post-56","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/pages\/56","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/users\/46"}],"replies":[{"embeddable":true,"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/comments?post=56"}],"version-history":[{"count":161,"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/pages\/56\/revisions"}],"predecessor-version":[{"id":1882,"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/pages\/56\/revisions\/1882"}],"wp:attachment":[{"href":"https:\/\/wp.icmm.csic.es\/csc\/wp-json\/wp\/v2\/media?parent=56"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}