Estudo da forma??o dos complexos coacervados obtidos a partir de prote?nas globulares / Study of formation of complex coacervates obtained from globular proteins.

Santos, Monique Barreto

29 February 2016

Submitted by Sandra Pereira (srpereira@ufrrj.br) on 2016-10-17T10:53:24Z No. of bitstreams: 1 2016 - Monique Barreto Santos.pdf: 2356049 bytes, checksum: 8a379b47682a5e067746503ee59b6d27 (MD5) / Made available in DSpace on 2016-10-17T10:53:24Z (GMT). No. of bitstreams: 1 2016 - Monique Barreto Santos.pdf: 2356049 bytes, checksum: 8a379b47682a5e067746503ee59b6d27 (MD5) Previous issue date: 2016-02-29 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico - CNPq / Proteins are biopolymers of high nutritional and functional significance has been widely used as food ingredients. The interaction between two different proteins oppositely charged, and can give rise to complex coacervate currently used as an ingredient in food technology or as a microencapsulating agent. The formation of complex coacervates between Lysozyme and Ovalbumin and between Bovine serum albumin (BSA) and Lysozyme has been investigated as a function of pH, mass ratio of total and concentration of NaCl. For both interactions studied, complexing latched in a wide pH range which corresponds to the interval between the pI of proteins. Among Ovalbumin and Lysozyme interaction was more intense in the ratio r = 1 at pH 7.5 and BSA and Lysozyme most complex formation has occurred on the ratio r = 0.5 and pH 9.0. Changes in the ionic strength by adding NaCl negatively affected the interaction between Lysozyme and BSA already at a concentration of 0.01 mol / L and 0.03 mol / L abolished the interaction between Lysozyme and Ovalbumin. Through Potential - zeta can be seen that the formation of insoluble complexes was highest near the pI for all studied reasons, indicating that the interaction is given by neutralization of opposite charges. The Infrared spectra suggested that electrostatic interactions led interactions however, hydrogen bonds also had a hand in the coacervation process for the proteins under study. The micrographs showed that the insoluble complexes showed spherical structure and particle size showed the formation of structures with an average size around 2 ?m, much larger than the observable size for the isolated proteins. The isothermal titration calorimetry showed that the interaction between Lysozyme and Ovalbumin was exothermic and was performed in two steps, the first and second entropy directed enthalpy driven. The differential scanning calorimetry suggested the presence of a single point of denaturation, that the interaction between Lysozyme and BSA led to a new biopolymer with denaturation temperature 67 ? C differs from isolated proteins. These studies suggested that complex coacervates formed between Ovalbumin / Lysozyme and BSA / Lysozyme could be used as the encapsulating bioactive agent or as food ingredients in order to add nutritional value. / Prote?nas s?o biopol?meros de grande import?ncia nutricional e funcional tendo sido amplamente utilizadas como ingredientes alimentares. A intera??o entre duas prote?nas diferentes e opostamente carregadas pode dar origem aos complexo coacervado, atualmente utilizados como ingrediente na tecnologia de alimentos ou como agente de microencapsula??o. A forma??o de complexos coacervados entre Ovalbumina e Lisozima e entre Albumina s?rica bovina (BSA) e Lisozima foi investigada em fun??o do pH, raz?o de massa total e concentra??o de NaCl. Para as duas intera??es estudadas, a complexa??o acorreu em uma ampla faixa de pH, que corresponde ao intervalo entre os pI das prote?nas. Entre Ovalbumina e Lisozima a intera??o foi mais intensa na raz?o r=1 em pH 7,5 e para BSA e Lisozima a maior forma??o de complexos ocorreu na raz?o r=0,5 e pH 9,0. Altera??es na for?a i?nica por adi??o de NaCl influenciaram negativamente a intera??o entre Albumina BSA e Lisozima j? na concentra??o de 0,01 mol/L e a 0,03 mol/L suprimiu a intera??o entre Ovalbumina e Lisozima. Por meio do Potencial - zeta pode-se verificar que a forma??o de complexos insol?veis foi m?xima pr?ximo ao pI para todas as raz?es estudadas, indicando que a intera??o se deu por neutraliza??o de cargas opostas. Os espectros no infravermelho sugeriram que intera??es eletrost?ticas conduziram as intera??es no entanto, liga??es de hidrog?nio tamb?m tiveram participa??o no processo de coacerva??o para as prote?nas em estudo. As micrografias revelaram que os complexos insol?veis apresentavam estrutura esf?rica e o tamanho de part?cula demonstrou a forma??o de estruturas com tamanho m?dio em torno de 2 ?m, as quais s?o bem maiores do que o tamanho obervado para as prote?nas isoladas. A calorimetria de titula??o isot?rmica demonstrou que a intera??o entre Ovalbumina e Lisozima foi exot?rmica, a qual ocorreu em duas etapas, a primeira entropicamente dirigida e a segunda entalpicamente dirigida. A calorimetria diferencial de varredura sugeriu, pela presen?a de um ?nico ponto de desnatura??o, que a intera??o entre BSA e Lisozima deu origem a um novo biopol?mero com temperatura de desnatura??o a 67?C, diferente das prote?nas isoladas. Estes estudos sugeriram que complexos coacervados formados entre Ovalbumina / Lisozima e BSA / Lisozima poderiam ser utilizados como agente encapsulante de bioativos ou como ingredientes alimentares com o objetivo de agregar valor nutricional.

Microencapsulation

Differential scanning calorimetry

Microencapsulante, , .

Calorimetria diferencial de varredura

Calorimetria de titula??o isot?rmica

Isothermal titration calorimetry

Ci?ncias Exatas e da Terra