Surface degradation of composite resins by acidic medicines and ph-cycling

This study evaluated the effects of acidic medicines (Dimetapp® and Claritin®), under pH-cycling conditions, on the surface degradation of four composite resins (microhybrid: TPH, Concept, Opallis and Nanofilled: Supreme). Thirty disc-shaped specimens (Ø = 5.0 mm / thickness = 2.0 mm) of each composite were randomly assigned to 3 groups (n = 10): a control and two experimental groups, according to the acidic medicines evaluated. The specimens were finished and polished with aluminum oxide discs, and the surface roughness was measured by using a profilometer. After the specimens were submitted to a pH-cycling regimen and immersion in acidic medicines for 12 days, the surface roughness was measured again. Two specimens for each material and group were analyzed by scanning electron microscopy (SEM) before and after pH-cycling. Data were analyzed by the Student's-t test, ANOVA, Duncan's multiple range test and paired t-test (α=0.05). Significant increase in roughness was found only for TPH in the control group and TPH and Supreme immersed in Claritin® (p<0.05). SEM analyses showed that the 4 composite resins underwent erosion and surface degradation after being subjected to the experimental conditions. In conclusion, although the roughness was slightly affected, the pH-cycling and acidic medicines caused surface degradation of the composite resins evaluated. Titratable acidity seemed to play a more crucial role on surface degradation of composite resins than pH.

Conformational Analysis of 2- [4- [5-Bromo-3-Methyl Pyridyl] Butyamino] -4-Pyrimidone

Potential energy of 2-[4-[5-Bromo-3-Methyl pyridyl] butylamino]-4-pyrimidone was calculated. This calculation suggests that most stable conformation existed at W1=220°, W2=220° and the minimum potential energy was -0.00807 kcal/mole

Bioinorganic study on [Fe(promethazine)2H2O Cl]2+ complex.

The coordination chemistry of iron (III) is the environment of an antihistaminic drug, promethazine has been explained to include a low spin, six-coordinate complex [Fe(Prometha)2(H2O) Cl] Cl2. Metaldrug interaction in vitro in aqueous KCl phase was studied polarographically at physiological pH and temperature. On the basis of elemental, magnetic, conductometric, IR, UV-visible, NMR spectroscopic analysis it is concluded that in solid phase two promethazine molecules with their N,N donor sites encompass the metal. Mass spectral study on the complex confirms that one of the three chlorides is involved in the coordination. The respective changes in the antihistaminic activity of the drug as a result of complexation has been determined and a possible mechanism is suggested.

N-acetylaspartylglutamate acetoxymethyl triester (NAAG.AM) as a tool for loading the neuropeptides NAAG and succinimidyl-NAAG into intact cells: effect on [3H]-dopamine exocytosis

Although N-acetylaspartylglutamate (NAAG) is one of the neuropeptides found in highest concentrations in the mammalian central nervous system, its functional role in neuronal signaling has not been definitively established. In some neuronal populations, NAAG is concentrated in nerve terminals and thus, it may play a role in the cytoplasmic events underlying neurotransmitter exocytosis. In the present study we have validated the use of the synthetic derivative NAAG-acetoxymethyl triester (NAAG.AM) as a tool to increase the intracellular levels of the peptide and assessed the ability of NAAG to regulate [3H]-dopamine ([3H]-DA) secretion in PC12 cells. Enzymatic degradation of NAAG.AM by nonspecific brain esterases resulted in the progressive formation of NAAG and succinimidyl-NAAG (Asu-NAAG). However, only 8 percent of NAAG.AM was converted to NAAG. Significant amounts of NAAG (1 nmol/mg protein) were demonstrable in cultures of the neuroblastoma cell line N2A following incubation with NAAG.AM for 2 h, with the concentration of (Asu)-NAAG being at least 100-fold higher. The pheochromocytoma cell line PC12 was used to assess the influence of loaded NAAG derivatives on [3H]-DA exocytosis. Incubation with 0.1-1 mM NAAG.AM did not affect the basal efflux or total content of [3H]-DA. However, it induced a dose-dependent decrease of [3H]-DA secretion in response to 56 mM KCI depolarization reaching an inhibition of 49 percent with 1 mM NAAG.AM. In contrast, NAAG.AM did not affect secretion induced by the calcium ionophore A23187 (100 microM). The present study validates the use of NAAG.AM as a tool to load NAAG derivatives into intact cells and provides preliminary evidence for an intracellular role of the peptide.