ABSTRACT
A través del método de equilibrio batch se comparó la adsorción de las catecolaminas Dopamina (DA), Noradrenalina (NA) y Adrenalina (A), y de los metabolitos ácido dihidroxifenilacético (Dopac) y ácido indolacético (5- HIAA) en las fases sólidas octadecil (C18) hidrofóbica, diol (C Diol) hidrofílica y de intercambio catiónico débil (WCX). En la fase sólida WCX a pH 4,0 se observó un 78% de adsorción de catecolaminas y 68% de adsorción de Dopac. Las isotermas de adsorción de las catecolaminas en la fase WCX son de tipo Langmuir. La adrenalina tiene mayor afinidad que la dopamina por la fase WCX a pH 4,0 y la dopamina mayor afinidad que el Dopac y éste es coadsorbido sobre las catecolaminas adsorbidas en la fase WCX. Un ensayo con solventes orgánicos demostró que el tolueno extrajo selectivamente de una mezcla sintética el Dopac y el 5-HIAA coadsorbido, mientras que en una muestra de tejido cerebral de ratas experimentales fueron extraídos el Dopac y el ácido homovanílico (HVA). Estos resultados sirvieron para proponer un paso adicional de extracción con solventes orgánicos para la separación de metabolitos ácidos durante la extracción en fase sólida (EFS) en el análisis de catecolaminas.
The adsorptions of Dopamine (DA), Noradrenaline (NA), and Adrenaline (A) catecholamines were compared by using the batch equilibrium method, as well as those of the dihydroxyphenylacetic acid (Dopac) and indolacetic acid (5-HIAA) metabolites on the hydrophobic octadecyl (C18), hydrophilic diol (C Diol) and weak cation exchange (WCX) solid phases. On the WCX solid phase at pH 4.0, catecholamines adsorption of 78% and Dopac adsorption of 68% were observed. The adsorption isotherms of catecholamines on the for the WCX phase at pH 4.0 than dopamine, dopamine has greater affinity than Dopac, and this latter is coadsorbed over the adsorbed catecholamines on the WCX phase. A trial with organic solvents demonstrated that toluene selectively extracted Dopac and the coadsorbed 5-HIAA from a synthetic mix, while in a brain tissue specimen from experimental rats, Dopac and homovanilic acid (HVA) were extracted. These results served to propose an additional extraction step with organic solvents throughout the separation of acid metabolites during solid phase extraction (EFS) for the analysis of catecholamines.
Subject(s)
Animals , Rats , 3,4-Dihydroxyphenylacetic Acid/cerebrospinal fluid , Catecholamines/chemistry , Hydroxyindoleacetic Acid/cerebrospinal fluid , Dopamine , Epinephrine/chemistry , Norepinephrine , Solid Phase ExtractionABSTRACT
Iron was found to form coloured stable complexes with both adrenaline hydrogen tartrate and catechol as inhibitors for iron corrosion in aqueous solutions of different pH values [2.0-11.5]. The electrochemically formed complexes on the surface of the iron electrode in different media were separated and studied in comparison with the same complexes prepared by chemical method in the same media. The prepared complexes were studied using micro-, electro-and thermal analyses together with electron ionization mass [EI-MS] and IR spectral methods. Both chemically and electrochemically prepared complexes were found to be of the same structures. The electrochemically formed complex in different media was found to be as a chemisorbed layer on the surface of iron electrode. The aim of the present work is to compare the results of chemical and electrochemical techniques in preparation of stable iron chelates of both adrenaline hydrogen tatrate [AHT] and Catechol [Cat.] as inhibitors for iron corrosion. The morphology of the chemisorbed complex layers on the electrode surface was also tested by electron microscope [EMS] and characterized as an amorphous or crystalline adsorbents
Subject(s)
Catecholamines/chemistry , Mass Spectrometry/methods , Microscopy, Electron/methods , Differential Thermal Analysis/methodsABSTRACT
Embora o hormônio do crescimento (GH) seja um dos hormônios mais estudados, vários de seus aspectos fisiológicos ainda não estão integralmente esclarecidos, incluindo sua relação com o exercício físico. Estudos mais recentes têm aumentado o conhecimento a respeito dos mecanismos de ação do GH, podendo ser divididos em: 1) ações diretas, mediadas pela rede de sinalizações intracelulares, desencadeadas pela ligação do GH ao seu receptor na membrana plasmática; e 2) ações indiretas, mediadas principalmente pela regulação da síntese dos fatores de crescimento semelhantes à insulina (IGF). Tem sido demonstrado que o exercício físico é um potente estimulador da liberação do GH. A magnitude deste aumento sofre influência de diversos fatores, em especial, da intensidade e do volume do exercício, além do estado de treinamento. Atletas, normalmente, apresentam menor liberação de GH induzida pelo exercício que indivíduos sedentários ou pouco treinados. Evidências experimentais demonstram que o GH: 1) favorece a mobilização de ácidos graxos livres do tecido adiposo para geração de energia; 2) aumenta a capacidade de oxidação de gordura e 3) aumenta o gasto energético.
Although growth hormone (GH) is one of the most extensively studied hormones, various aspects related to this hormone have not been completely established, including its relationship with physical exercise. Recent studies have contributed to the understanding of the mechanisms of action of GH, which can be divided into 1) direct actions mediated by intracellular signals that are triggered by the binding of GH to its receptor on the plasma membrane, and 2) indirect actions mediated mainly by the regulation of the synthesis of insulin-like growth factors (IGF). Physical exercise has been shown to be a potent stimulator of GH release, especially in young men and women. The magnitude of this increase is influenced by several factors, especially the intensity and volume of exercise, in addition to training status. In this respect, athletes normally present a lower exercise-induced GH release than sedentary or poorly trained individuals. Experimental evidence indicates that GH may 1) favor the mobilization of free fatty acids from adipose tissue for energy generation, 2) increase the capacity of fat oxidation, and 3) increase energy expenditure.
Subject(s)
Humans , Male , Female , Exercise , Human Growth Hormone/metabolism , Lipolysis , Protein Biosynthesis , Biologic Oxidation , Catecholamines/chemistryABSTRACT
Inactivation of lipoamide dehydrogenase (LipDH) by the Cu(II)/H2O2 Fenton system (SF-Cu(II): (5.0 microM Cu(II), 3.0 mM H2O2) was enhanced by catecholamines (CAs), namely, epinephrine, levoDOPA (DOPA), DOPAMINE, 6-hydroxyDOPAMINE (OH-DOPAMINE) and related compounds (DOPAC, CATECHOL, etc.). After 5 min incubation with the Cu(II)/H2O2/CA system (0,4 mM CA), the enzyme activity decayed as indicated by the following percentage values (mean +/- S.D.; in parenthesis, number of determinations): SF-Cu(II) alone, 43 +/- 10 (18); SF-Cu(II) + epinephrine, 80 +/- 9 (5); SF-Cu(II)'+ DOPA, 78 +/- 2 (4); SF + Cu(II) + DOPAMINE, 88 +/- 7 (5); SF-Cu(II) + OH-DOPAMINE 87 +/- 6 (7); SF-Cu(II) + DOPAC, 88 +/- 3 (6); SF-Cu(II) + catechol, 85 +/- 6 (5). In all cases P < 0,05, with respect to the SF-Cu(II) control sample. CAs effect was concentration-dependent and at the 0-100 microM concentration range, it varied with the CA structure. Above the 100 MicroM concentration, CAs were equally effective and produced 90-100 percent enzyme, inactivation (Figure 2). In the absence of oxy-radical generation, the enzyme specific activity (mean + S.D.) was 149 +/- 10 (24) micromol NADH/min/mg protein. Assay of HO. production by the Cu(II)/H2O2/CA system in the presence of deoxyribose (TBA assay) yielded values much greater than those obtained omitting CA. Hydroxyl radical production depended on the presence of Cu(II) and H2O2, and significant HO. values were obtained with OH-DOPAMINE, DOPAC, epinephrine, DOPAMINE, DOPA and catecol supplemented systems (Table 2). LipDH (1.0 microM) inhibited 50-80 percent deoxyribose oxidation, the inhibition depending on the CA structure (Table 2). Native catalase (20 microg/ml) and bovine serum albumin (40 microg/ml) effectively prevented LipDH inactivation by the Cu(II)/H2O2/CA system, denaturated catalase, SOD, 0,3 M mannitol, 6,0 mM ethanol and 0,2 M benzoate were less effective or did not protect LipDH (Table 3). Incubation of CAs with the Cu(II)H2O2 system produced a time and Cu(II)-dependent destruction of CAs, the corresponding o-quinone, production as illustrated with epinephrine (figures 6 and 7), as illustrated with epinephrine and DOPAMINE (Table 4). These results support LipDH inactivation by (a) reduction of Cu(II) to Cu(I) by CAs followed by Cu-catalyzed production of HO. from H2O2; (b) CA oxidation followed by the corresponding o-quinone interaction with LipDH. CAPTOPRIL, N-acetylcysteine, mercaptopropionylglycine and penicillamine prevented to various degree LipDH inactivation by the Cu(II)/H2O2/CA systems (Table 1). The former was the most effective and 0,4 mM CAPTOPRIL prevented about 95-100 percent the effect of Cu(II)/H2O2/CA systems supplemented with epinephrine, DOPAMINE and OH-DOPAMINE (Figures 3 and Table 1). LipDH increased and CAPTOPRIL inhibited epinephrine oxidation by Cu(II)/H2O2 (Figures 4 and 5). Since un-physiological concentrations of CAs and Cu(II) may be released in the myocardium after ischemia-reperfusion, the summarized observations may contribute to explain myocardial damage in that condition.