RUTH LUQUEZE CAMILO
7 resultados
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Artigo IPEN-doc 10628 Sintese do nucleo magnetico de nanocompositos funcionalizados para uso no tratamento de rejeitos radioativos e toxicos2005 - CAMILO, R.L.; YAMAURA, M.; FELINTO, M.C.F.C.; RODRIGUES, L.S.; LIMA, L.C.S.Artigo IPEN-doc 10853 Magnetic polymeric microspheres for protein adsorption2004 - FELINTO, M.C.F.C.; PARRA, D.F.; LUGAO, A.B.; BATISTA, M.P.; HIGA, O.Z.; YAMAURA, M.; CAMILO, R.L.; RIBELA, M.T.C.P.; SAMPAIO, L.C.Artigo IPEN-doc 11955 Magnetic nanoparticles and their application in biomedicine2007 - FELINTO, MARIA C.F.C.; CAMILO, RUTH L.; DIEGUES, T.G.The magnetic nanoparticles offer some attractive possibilities in biomedicine for the following reasons: First, they have controllable sizes ranging from a few nanometers up to tens of nanometers, which places them at dimensions that are smaller than or comparable to those of a cell (10– –450 nm) or a protein (5–50 nm). Second, the nanoparticles are magnetic, which means that they obey Coulomb’s law, and can be manipulated by an external magnetic field gradient. This possibility, combined with the intrinsic penetrability of magnetic fields into human tissue, opens up many applications involving the transport and/or immobilization of magnetic nanoparticles, or of magnetically tagged biological entities. Third, the magnetic nanoparticles can be made to resonantly respond to a time-varying magnetic field, with advantageous results related to the transfer of energy from the exciting field to the nanoparticle. In this paper, we will address the underlying chemical and physics of the biomedical applications of magnetic nanoparticles including radioisotope delivery and a magnetic radiolabeled fluid. We will consider four particular applications: magnetic separation for radio labeled proteins, drug radiolabeled delivery, hyperthermia treatments, and magnetic resonance imaging (MRI) contrast enhancement. There will be included some results obtained in our laboratory in the obtention of these magnetic nanoparticles.Artigo IPEN-doc 08476 Synthesis of organic magnetic particles for the removal of heavy metals from aqueous waste2001 - YAMAURA, M.; CAMILO, R.L.; FELINTO, M.C.F.C.Artigo IPEN-doc 06247 Dissolution and ion exchange operations mathematical modeling in a sup(99)Mo production process for medical purposes1998 - GONCALVES, M.A.; NERY, A.R.L.; YAMAURA, M.; FELINTO, M.C.F.C.; CAMILO, R.L.; COHEN, V.H.Artigo IPEN-doc 08627 Synthesis and performance of organic-coated magnetite particles2002 - YAMAURA, M.; CAMILO, R.L.; FELINTO, M.C.F.C.Artigo IPEN-doc 10844 Magnetic polymeric microspheres for protein adsorption2005 - FELINTO, M.C.F.C.; PARRA, D.F.; LUGAO, A.B.; BATISTA, M.P.; HIGA, O.Z.; YAMAURA, M.; CAMILO, R.L.; RIBELA, M.T.C.P.; SAMPAIO, L.C.Magnetic beads consisting of polymer-coated manganese ferrite nanoparticles were prepared by the precipitation reaction of manganese ferrite into the channels of methyl methacrylate polymer beads by sodium hydroxide, resulting in MnMagBead. MnMagBead was characterized by infrared spectra (FTIR), thermogravimetric analysis of TGA/DTG and indicates the presence of –CO (carbonyl) groups and the MnFe2O4 on the beads. Magnetization measurements were obtained at room temperature in magnetic fields up to 10 KOe using a vibrating sample magnetometer. Introductory Protein adsorption biological tests were processed using labeled I-125 albumin (BSA), and the activity was measured in a gamma counting spectrometer. These superparamagnetic beads exhibit the capacity to bind biological molecules such as proteins like albumin, with a good capability (5 × 10−6) μg/100 mg of beads as compared with other magnetic resins studied in our group.