BONFIM, LETICIAGONÇALVES, KARINA O.VIEIRA, DANIEL P.2018-02-012018-02-01BONFIM, LETICIA; GONÇALVES, KARINA O.; VIEIRA, DANIEL P. Development of three-dimensional cellular culture system for testing of biological effects of radiations in tumoral and non-tumoral models. In: CONGRESSO DA SOCIEDADE BRASILEIRA DE BIOCIENCIAS NUCLEARES, 12., 09-11 de outubro, 2017, São Paulo, SP. <b>Anais...</b> Disponível em: http://repositorio.ipen.br/handle/123456789/28433.http://repositorio.ipen.br/handle/123456789/28433Pre-clinical drug testing is currently based on based on monolayer or 2D (2D) cell cultures and, despite the large-scale use of this form of culture, there is already scientific evidence that the cellular disposition in monolayers does not adequately simulate tissue physiology, as it prevents cells from expressing their characteristics in a manner analogous to that found in the organism. For this purpose, the work aimed to produce three dimensional structures, referred as spheroids, using magnetic levitation by adding iron nanoparticles to the cultures and with the aid of magnets. Electron microscopy showed particles with about 20nm in diameter. FTIR (Fourier-transform infrared spectroscopy) analysis showed stretches compatible with iron and amino acid (Lysine) binding. The images showed the formation of spherical bodies until the ninth day. LnCap spheroid diameter varied from (mean ± error) 434.407 ± 50.018 m (5th day) to 264.574 ± 13.184 μm (9th day). Cultures of CHO ranged from 229.237 ± 5.278 to 236.719 ± 12.910 μm in the same period. Spheres generated by magnetic levitation could be measured by digital means and compared throughout the experiment. The tool can be used to test the biological effects of radiation and / or radiopharmaceuticals in culture.openAccessbiological radiation effectscell culturesfourier transformationinfrared spectrairon oxideslevitationnanoparticlesneoplasmsspheroidsthree-dimensional calculationsTexto completo de eventohttps://orcid.org/0000-0002-0007-534X