Pruebas bioquímicas para la detección de metabolitos producidos en los errores innatos del metabolismo / Biochemical tests for the detection of metabolites produced in inborn errors of metabolism / Provas bioquímicas para a detecção de metabólitos produzidos nos erros inatos do metabolismo

Los errores innatos del metabolismo (EIM) son más de 550 enfermedades en las que se presenta una deficiencia o ausencia de proteínas con actividad enzimática, transportadora, receptora o estructural. Cada una de estas enfermedades es rara, pero su gran variedad hace que, consideradas en conjunto, sean la principal patología neonatal. Para la detección de los metabolitos producidos en los EIM se pueden utilizar pruebas cualitativas. Su utilidad radica en que son muy rápidas y de fácil acceso, y en que sirven como pruebas presuntivas para proceder a hacer exámenes más especializados o para enfocar el diagnóstico. Teniendo en cuenta su importancia para un diagnóstico temprano de los EIM, el objetivo del presente artículo es describir el funcionamiento de las pruebas bioquímicas de resorcinol, dinitrofenilhidrazina, nitrosonaftol, nitroprusiato y Hoesch, haciendo énfasis en los metabolitos que detectan.

Inborn errors of metabolism (IEM) are more than 550 diseases in which there is a deficiency or absence of proteins with enzymatic, transporter, receptor or structural activity. Individually these diseases are rare, but because of their wide variety they are, considered together, the largest neonatal disease. To detect metabolites produced in IEM qualitative tests can be used. They are easily accessible and fast to carry out, and serve as presumptive elements before proceeding to more specialized tests or to focus diagnosis. Given their importance for the early diagnosis of IEM, this article aims to describe the functioning of the following biochemical tests: dinitrophenylhydrazine, resorcinol, nitrosonaphtol, nitroprusside and Hoesch, emphasizing in the metabolites that they detect.

Os erros inatos do metabolismo (EIM) são mais de 550 doenças nas que se apresenta uma deficiência ou ausência de proteínas com atividade enzimática, transportadora, receptora ou estrutural. Cada uma destas doenças é rara, mas sua grande variedade faz que, consideradas em conjunto, sejam a principal patologia neonatal. Para a detecção dos metabólitos produzidos nos EIM se podem utilizar provas qualitativas. Sua utilidade radica em que são muito rápidas e de fácil acesso, e em que servem como provas presuntivas para proceder a fazer exames mais especializados ou para enfocar o diagnóstico. Tendo em conta sua importância para um diagnóstico precoce dos EIM, o objetivo do presente artigo é descrever o funcionamento das provas bioquímicas de resorcinol, dinitrofenilhidrazina, nitrosonaftol, nitroprusiato e Hoesch, fazendo ênfases nos metabólitos que detectam.

Identification of mechanisms involved in the relaxation of rabbit cavernous smooth muscle by a new nitric oxide donor ruthenium compound

PURPOSE: The aim of this study was to evaluate the relaxation in vitro of cavernous smooth muscle induced by a new NO donor of the complex nitrosil-ruthenium, named trans-[Ru(NH3)4(caffeine)(NO)]C13 (Rut-Caf) and sodium nitroprusside (SNP). MATERIALS AND METHODS: The tissues, immersed in isolated bath systems, were pre-contracted with phenilephrine (PE) (1 µM) and then concentration-response curves (10-12 - 10-4 M) were obtained. To clarify the mechanism of action involved, it was added to the baths ODQ (10 µM, 30 µM), oxyhemoglobin (10 µM), L-cysteine (100 µM), hydroxicobalamine (100 µM), glibenclamide, iberotoxin and apamine. Tissue samples were frozen in liquid nitrogen to measure the amount of cGMP and cAMP produced. RESULTS: The substances provoked significant relaxation of the cavernous smooth muscle. Both Rut-Caf and SNP determined dose-dependent relaxation with similar potency (pEC50) and maximum effect (Emax). The substances showed activity through activation of the soluble guanylyl cyclase (sGC), because the relaxations were inhibited by ODQ. Oxyhemoglobin significantly diminished the relaxation effect of the substances. L-cysteine failed to modify the relaxations caused by the agents. Hydroxicobalamine significantly diminished the relaxation effect of Rut-Caf. Glibenclamide significantly increased the efficacy of Rut-Caf (pEC50 4.09 x 7.09). There were no alterations of potency or maximum effect of the substances with the addition of the other ion channel blockers. Rut-Caf induced production of significant amounts of cGMP and cAMP during the relaxation process. CONCLUSIONS: In conclusion, Rut-Caf causes relaxation of smooth muscle of corpus cavernosum by means of activation of sGC with intracellular production of cGMP and cAMP; and also by release of NO in the intracellular environment. Rut-Caf releases the NO free radical and it does not act directly on the potassium ion channels.