Publications in collaboration with researchers from BCMaterials, Centro Vasco de Materiales, Aplicaciones y Nanoestructuras (42)

2024

  1. Magnetic imaging of individual magnetosome chains in magnetotactic bacteria

    Biomaterials Advances, Vol. 163

2023

  1. Incorporation of Tb and Gd improves the diagnostic functionality of magnetotactic bacteria

    Materials Today Bio, Vol. 20

  2. Magnetotactic Bacteria: Biorobots for Targeted Therapies and Model Nanomagnetic Systems

    2023 IEEE International Magnetic Conference - Short Papers, INTERMAG Short Papers 2023 - Proceedings

  3. Tuning the Magnetic Response of Magnetospirillum magneticum by Changing the Culture Medium: A Straightforward Approach to Improve Their Hyperthermia Efficiency

    ACS Applied Materials and Interfaces, Vol. 15, Núm. 1, pp. 566-577

2022

  1. Erratum: Modifying the magnetic response of magnetotactic bacteria: incorporation of Gd and Tb ions into the magnetosome structure (Nanoscale Adv. (2022) DOI: 10.1039/d2na00094f)

    Nanoscale Advances

  2. Modifying the magnetic response of magnetotactic bacteria: incorporation of Gd and Tb ions into the magnetosome structure

    Nanoscale Advances, Vol. 4, Núm. 12, pp. 2649-2659

  3. Towards the design of contrast-enhanced agents: Systematic Ga3+doping on magnetite nanoparticles

    Dalton Transactions, Vol. 51, Núm. 6, pp. 2517-2530

2021

  1. A Milestone in the Chemical Synthesis of Fe3O4Nanoparticles: Unreported Bulklike Properties Lead to a Remarkable Magnetic Hyperthermia

    Chemistry of Materials, Vol. 33, Núm. 22, pp. 8693-8704

  2. Improved photocatalytic and antibacterial performance of Cr doped TiO2 nanoparticles

    Surfaces and Interfaces, Vol. 22

  3. Nature Driven Magnetic Nanoarchitectures

    Springer Series in Materials Science (Springer Science and Business Media Deutschland GmbH), pp. 159-179

  4. Shaping up Zn-Doped Magnetite Nanoparticles from Mono- And Bimetallic Oleates- And Impact of Zn Content, Fe Vacancies, and Morphology on Magnetic Hyperthermia Performance

    Chemistry of Materials, Vol. 33, Núm. 9, pp. 3139-3154

2020

  1. Controlled Magnetic Anisotropy in Single Domain Mn-doped Biosynthesized Nanoparticles

    Journal of Physical Chemistry C, Vol. 124, Núm. 41, pp. 22827-22838

  2. Elucidating the role of shape anisotropy in faceted magnetic nanoparticles using biogenic magnetosomes as a model

    Nanoscale, Vol. 12, Núm. 30, pp. 16081-16090

  3. Highly Reproducible Hyperthermia Response in Water, Agar, and Cellular Environment by Discretely PEGylated Magnetite Nanoparticles

    ACS applied materials & interfaces, Vol. 12, Núm. 25, pp. 27917-27929

  4. Isolation of cancer-derived exosomes using a variety of magnetic nanostructures: From fe3 o4 nanoparticles to ni nanowires

    Nanomaterials, Vol. 10, Núm. 9, pp. 1-16

  5. Magnetosomes could be protective shields against metal stress in magnetotactic bacteria

    Scientific Reports, Vol. 10, Núm. 1

  6. Magnetotactic bacteria for cancer therapy

    Journal of Applied Physics, Vol. 128, Núm. 7

  7. Probing the stability and magnetic properties of magnetosome chains in freeze-dried magnetotactic bacteria

    Nanoscale Advances, Vol. 2, Núm. 3, pp. 1115-1121

2019

  1. Enhanced mass sensitivity in novel magnetoelastic resonators geometries for advanced detection systems

    Sensors and Actuators, B: Chemical, Vol. 296

  2. Mn-Doping level dependence on the magnetic response of MnxFe3- xO4 ferrite nanoparticles

    Dalton Transactions, Vol. 48, Núm. 30, pp. 11480-11491