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Magneticky modifikované aktivní uhlí a biouhel a jejich využití. Ivo Šafařík, Kate řina Horská, Kristýna Pospíšková, Zdenka Maděrová, Mirka Šafaříková Oddělení n anobiotechnolog ie Ústav nanobiologie a strukturní biologie CVGZ AVČR Č esk é Bud ě jovice ivosaf@yahoo.com
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Magneticky modifikované aktivní uhlí a biouhel a jejich využití Ivo Šafařík, Kateřina Horská, Kristýna Pospíšková, Zdenka Maděrová, Mirka Šafaříková Oddělení nanobiotechnologie Ústav nanobiologie a strukturní biologie CVGZ AVČR České Budějovice ivosaf@yahoo.com www.nh.cas.cz/people/safarik
Types of magnetic nano- and microparticles Multi domain, single domain or superparamagnetic • Magnetite (Fe3O4) • Ferrites (MeO . Fe2O3; Me = Ni, Co, Mg, Zn, Mn ...) • Maghemite (-Fe2O3) • Greigite (Fe3S4) • Iron, nickel
Why magnetic materials are so important in bioapplications? They are smart materials!!!! The following typical properties of magnetic materials form the basis of their applications in biosciences and biotechnology
Important properties • Selective separation (removal) of magnetic particles from the system • Targeting (navigation) of magnetic particles to desired area using magnetic field
Important properties • “keeping” magnetic particles in appropriate area using magnetic field • Heat formation in alternated magnetic field
Important properties • Increasing of contrast during MRI • Peroxidase-like activity
Important properties • Hardening of biological structures (chiton teeth) • Navigation in magnetic field
Important properties • Magnetic labeling of biologically active compounds • Magnetization of biological diamagnetic materials
Examples of of magnetic nano- and microparticlesapplications • From molecular biology to environmental technologies • Manipulation of microliters as well as million of liters • Manipulation in suspension systems • Both separation and non-separation techniques are important
Preparation of magnetic particles for bioapplications • Precipitation • High-temperature reactions • Reactionsin steric environments • Sol-gel reactions • Decompositionof organometallic precursors • Polyol methods • Biosynthesis Laurent S, Forge D, Port M, Roch A, Robic C, Elst LV, Muller RN: Magnetic iron oxide nanoparticles: Synthesis, stabilization, vectorization, physicochemical characterizations, and biological applications. Chem Rev 2008, 108(6):2064-2110.
Postmagnetization • Chemical precipitation procedures • High temperature treatment • Ferrofluid treatment • Microwave assisted procedures • Mechanochemistry • Encapsulation
Conversion Of Activated Carbons (Charcoal) Into Their Magnetic Derivatives Using Chemical Precipitation Procedures
Conversion Of Activated Carbons (Charcoal) Into Their Magnetic Derivatives By High Temperature Treatment
Conversion Of Activated Carbons (Charcoal) Into Their Magnetic Derivatives By Encapsulation
Application Of Magnetic Activated Carbons (Charcoal) For The Separation Of Organic Compounds
Application Of Magnetic Activated Carbons (Charcoal) For The Separation Of Inorganic Compounds
Microwave assisted synthesis of magnetically responsive biochar high pH Biochar Microwave oven Magnetic biochar Ferrous sulfate Fe2+ + H2O → Fe(OH)2 3Fe(OH)2 + ½O2Fe3O4 + 3H2O microwave Magnetic properties are caused by the deposition of magnetic iron oxides nano- and microparticles on the biochar surface using the developed procedure
Safarik,I., Horska,K., Pospiskova,K., Maderova,Z., Safarikova,M.: Microwave Assisted Synthesis of Magnetically Responsive Composite Materials. IEEE Trans. Magn. 49 (1) (2013) 213-218
ありがとうございます!!!!! ivosaf@yahoo.com www.nh.cas.cz/people/safarik