MAGNO

MAGNO is the first commercially available magnetic colloid specially designed for Magnetic nanoHeating applications.

MAGNO is the first commercially available magnetic colloid specially designed for Magnetic nanoHeating applications.

Optimizing the heating properties of MNPs is cumbersome and takes long time and dedicated manpower. Magno offers the solution for those researchers that need accurate data, repetibility and reliability to test new ideas such as physical models, or any heating applications.

MAGNO is the ideal row material for a first approximation to Magnetic nanoHeating research as well as for a great variety of advanced applications, only limited by your imagination. Covered by Polyethylenimine (PEI), MAGNO nanoparticles constitutes a powerful tool not only for basic research on power absorption but also for different applications in most fields of biomedicine.

MAGNO is a water-based magnetic colloid consisting of magnetite (Fe3O4) nanoparticles with average sizes of 25nm functionalized with a biocompatible polymer. The magnetic nanoparticles display an impressive SPA value (typically >210W/g, for f = 580KHz, H0 =300G eq to 23.877 KA/m).

MAGNO has been manufactured and synthesized under controlled conditions using the DM100 technology. The precise control of the manufacturing conditions gives MAGNO a highly reproducible heating behavior and SPA values under different conditions, and an outstanding stability over the time.

MAGNO has been developed by nB nanoScale Biomagnetics under three basic principles for inductive heating research: repetibility, traceability and reliability.

MAGNO is the best and more specific magnetic colloid for your research on inductive heating of nanoestructured materials. Do not spend your time trying to synthesize your own MNPs,

Just test the application you have in mind using Magno and DM100 Series!!

Some literature about MAGNO
  • Long term stability and reproducibility of magnetic colloids are key issues for steady values of Specific Power Absorption through time. Beatriz Sanz; M. Pilar Calatayud; Nicolás Casinelli; Manuel Ricardo Ibarra; Gerardo F. Goya. European Journal of Inorganic Chemistry, 2015, p. n/a-n/a.
  • The effect of surface charge of functionalized Fe3O4 nanoparticles on protein adsorption and cell uptake. M. Pilar Calatayud; Beatriz Sanz; Vittoria Raffa; Cristina Riggio; Manuel Ricardo Ibarra; Gerardo F. Goya. Biomaterials 35(24):6389-99, 2014
  • The orientation of the neuronal growth process can be directed via magnetic nanoparticles under an applied magnetic field. Cristina Riggio; M. Pilar Calatayud; Martina Giannaccini; Beatriz Sanz; Teobaldo E. Torres; Rodrigo Fernández-Pacheco; Andrea Ripoli; Manuel Ricardo Ibarra; Luciana Dente; Alfred Cuschieri; Gerardo F. Goya; Vittoria Raffa. NANOMEDICINE. pp. 0 – [10 pp]. 2014. ISSN 1743-588.
  • Neuronal cells loaded with PEI-coated Fe3O4 nanoparticles for magnetically guided nerve regeneration. M. Pilar Calatayud; Cristina Riggio; Vittoria Raffa; Beatriz Sanz; Teobaldo E. Torres; M. Ricardo Ibarra; Clare Hoskins; Alfred Cuschieri; Lijun Wang; Josephine Pinkernelle; Gerburg Keilhoff; Gerardo F. Goya. JOURNAL OF MATERIALS CHEMISTRY B. 1 – 29, pp. 3607 – 3616. 2013. ISSN 2050-750X

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