Efeitos clínicos e microbiológicos do óleo de copaíba (copaifera officinalis) sobre bactérias formadoras de placa dental em cães / Clinical and microbiological effects of copaiba oil (copaifera officinalis) on dental plaque forming bacteria in dogs

O potencial de uso do óleo de copaíba (Copaifera officinalis) na prevenção da doença periodontal, eliminando seu agente etiológico, foi avaliado em 18 cães sem raça definida, distribuídos homogeneamente em três grupos: teste, (contendo óleo de copaíba) controle positivo e controle negativo. Os tratamentos ocorreram três vezes ao dia, durante oito dias. Ao nono dia, os animais receberam aplicação tópica de fucsina básica 0,5 por cento para evidenciação do biofilme. Mudanças na halitose e gengivite foram avaliadas diariamente por inspeção visual. Adicionalmente, foram realizados testes laboratoriais de inibição de aderência de Streptococcus mutans e ensaio antimicrobiano de difusão em ágar, sobre bactérias formadoras de placa dental. Os resultados da placa evidenciada apontaram áreas de cobertura microbiana nos dentes de 53,4±8,8 por cento, 28,5±5,4 por cento, e 22,3±5,3 por cento para os grupos negativo, positivo e teste, respectivamente, indicando diferença entre o controle negativo e os demais grupos (P<0,05). Quanto à melhora nos aspectos clínicos, halitose e gengivite, o grupo teste respondeu melhor quando comparado ao grupo controle negativo (P<0,05). A análise dos ensaios de difusão e inibição de aderência mostrou superioridade do grupo da copaíba (teste) em relação aos outros grupos (P<0,05). Os resultados sugerem o uso do óleo de copaíba na prevenção da doença periodontal e como um possível substituto da clorexidina na terapia antimicrobiana oral.

The copaiba oil (Copaifera officinalis) potential was evaluated in preventing periodontal disease and reducing its etiology. For that 18 mongrel dogs were homogeneously distributed in three groups: test (copaiba oil), positive control (chlorexidine) and negative control. The treatments were carried out three times a day, during eight days. On the 9th day, the animals were tested with a 0.5 percent basic solution of fuchsin for the detection of biofilm. Changes in halitosis and gingivitis were daily observed. In addition, the following laboratory tests were done: inhibition of the adherence of Streptococcus mutans, and plaque forming bacteria antimicrobial assays by the agar diffusion method. The results of the fuchsin test showed that dental plaque reached areas of 53.4±8.8 percent, 28.5±5.4 percent, and 22.3±5.3 percent in the negative control, positive control, and test groups, respectively, showing differences between dogs from the negative control group and dogs from the other two groups (P<0.05). Furthermore, halitosis and gingivitis decreased in the copaiba group animals when compared with the negative group (P<0.05). The results of the attachment inhibition and agar diffusion tests showed that copaiba induced better effects against the microorganisms as compared to the results of the other groups (P<0.05). These findings suggest that copaiba oil may effectively replace chlorexidine for oral antimicrobial therapy and prevention of periodontal disease.

A time-dependent, two-step binding mode of the nitro dye flavianic acid to trypsin in acid media

Synthetic dyes bind to proteins causing selective coprecipitation of the complexes in acid aqueous solution by a process of reversible denaturation that can be used as an alternative method for protein fractionation. The events that occur before precipitation were investigated by equilibrium dialysis using bovine trypsin and flavianic acid as a model able to cause coprecipitation. A two-step mode of interaction was found to be dependent on the incubation periods allowed for binding, with pronounced binding occurring after 42 h of incubation. The first step seems to involve hydration effects and conformational changes induced by binding of the first dye molecule, following rapid denaturation due to the binding of six additional flavianate anions to the macromolecule

Flavianate, an amino acid precipitant, is a competitive inhibitor of trypsin at pH 3.0

Textile dyes bind to proteins leading to selective co-precipitation of a complex involving one protein molecule and more than one dye molecule of opposite charge in acid solutions, in a process of reversible denaturation that can be utilized for protein fractionation. In order to understand what occurs before the co-precipitation, a kinetic study using bovine ß-trypsin and sodium flavianate was carried out based on reaction progress curve techniques. The experiments were carried out using a-CBZ-L-Lys-p-nitrophenyl ester as substrate which was added to 50 mM sodium citrate buffer, pH 3.0, containing varying concentrations of ß-trypsin and dye. The reaction was recorded spectrophotometrically at 340 nm for 30 min, and the families of curves obtained were analyzed simultaneously by fitting integrated Michaelis-Menten equations. The dye used behaved as a competitive inhibitor of trypsin at pH 3.0, with Ki = 99 µM; kinetic parameters for the substrate hydrolysis were: Km = 32 µM, and kcat = 0.38/min. The competitive character of the inhibition suggests a specific binding of the first dye molecule to His-57, the only positively charged residue at the active site of the enzyme