Transporte de água em células de melanona murino S91 submetidas a condições anisosmóticas / Water transport in murine melanoma S91 cells submitted to anisosmotic conditions

Silva, James Fernando Malta da

06 June 2007

Uma das principais necessidades da célula é a regulação do seu ambiente interno. Aparte da considerável importância teórica, o transporte de água é de importância prática numa ampla gama de processos, desde a proteção de células na preservação criogênica até os efeitos de certos hormônios em alguns tecidos. Virtualmente todas as células são submetidas a transições osmóticas durante o seu período de vida, uma vez que tanto o metabolismo intracelular quanto o transporte por membranas produzem flutuações nas concentrações dos solutos osmoticamente ativos. A regulação de volume celular é um fenômeno ubíquo e permite, às células, manter o seu volume normal. Células submetidas a choques anisosmóticos agudos sofrem rápidas alterações de volume (dependentes do gradiente osmótico e da permeabilidade da membrana à água e osmólitos) podendo ou não ser seguidas de lentas alterações regulatórias de volume. Assim, o objetivo do presente trabalho visou esclarecer alguns aspectos do transporte de água em células de melanoma murino S91 submetidas a condições anisosmóticas. Células de melanoma murino S91, foram mantidas em meio de cultura F12 HAM (290 mOsm.kgH2O-1). As medidas morfométricas das mudanças relativas de volume foram realizadas usando-se um sistema de aquisição e análise de imagens (Image Pro-Lite, Media Cybernetics). As células foram expostas tanto a choques hiposmóticos agudos (190 mOsm.kgH2O-1) como a choques hiperosmóticos agudos (350 mOsm.kgH2O-1) em diferentes temperaturas (de 17 a 37 oC) e em diferentes doses (de 0,001 a 1000 µM) de HgCl2, um bloqueador de aquaporinas (AQP). Os resultados sugerem que: (i) o tempo de regulação de volume em células de melanoma murino S91 é dependente da temperatura; (ii) o fluxo osmótico de água apresenta valores de Energia de Ativação compatíveis com aqueles propostos para o trânsito de água através de aquaporinas (Ea < 6 kcal.mol-1); (iii) o HgCl2 afeta de forma dose dependente as respostas osmóticas em células de melanoma murino S91 e sugerem a presença de mais de um tipo de AQP. Nestas condições as concentrações necessárias para reduzir ao máximo a permeabilidade osmótica à água estão localizadas na faixa de 0,1-1,0 µM HgCl2. / One of the major needs of living cells is the regulation of their internal environment. Apart from being of considerable theoretical importance, the transport of water is of practical importance in a broad range of process, from the protection of cells undergoing cryogenic preservation to the effects of certain hormones in some tissues. Virtually all the cells are submitted the osmotic transitions during their period of life, because both intracellular metabolism and transmembrane transport produce fluctuations in concentrations of osmolytes. The regulation of cellular volume is a phenomenon ubiquitous and allows, to the cells, to keep their normal volume. Cells subjected to acute anisosmotic shocks suffer from fast alterations in volume (depending on the osmotic gradient and on the permeability of the membrane to the water and osmotically active substances), and followed or not by a slow volume regulation response. Thus, the present work aims to clarify some aspects of the water transport in murine melanoma S91 cells subjected to anisosmotic conditions. S91 murine melanoma cells were grown in F12 HAM medium (290 mOsm.kgH2O-1). Morphometric measurements of relative changes in cell volume were performed using a video microscopy system and a PC software (Image Pro-Lite, Media Cybernetics). The experimental cells were exposed either to acute hyposmotic shocks (190 mOsm.kgH2O-1) or to acute hyperosmotic shocks (350 mOsm.kgH2O-1), in different temperatures (ranging from 17 to 37 oC) and in the presence of HgCl2 (from 0,001 to 1000 µM), an aquaporin blocker. The results of the present study indicate that: (i) the time of volume regulation in S91 murine melanoma cells is dependent on temperature; (ii) the values of osmotic water flow are compatible with activation energy through aquaporins (E < 6 kcal.mol-1) and (iii) HgCl2 treatments affect osmotic behavior of S91 murine melanoma cells in a dose-response manner and also suggest the presence of more than one type of aquaporin. Minimum osmotic water permeabilities were observed in a range of µM HgCl2 treatments.

HgCl2

HgCl2

Melanoma murino S91

Murine melanoma S91

Regulação de volume

Temperatura

Temperature

Volume regulation

Transporte de água em células de melanona murino S91 submetidas a condições anisosmóticas / Water transport in murine melanoma S91 cells submitted to anisosmotic conditions

James Fernando Malta da Silva

06 June 2007

Uma das principais necessidades da célula é a regulação do seu ambiente interno. Aparte da considerável importância teórica, o transporte de água é de importância prática numa ampla gama de processos, desde a proteção de células na preservação criogênica até os efeitos de certos hormônios em alguns tecidos. Virtualmente todas as células são submetidas a transições osmóticas durante o seu período de vida, uma vez que tanto o metabolismo intracelular quanto o transporte por membranas produzem flutuações nas concentrações dos solutos osmoticamente ativos. A regulação de volume celular é um fenômeno ubíquo e permite, às células, manter o seu volume normal. Células submetidas a choques anisosmóticos agudos sofrem rápidas alterações de volume (dependentes do gradiente osmótico e da permeabilidade da membrana à água e osmólitos) podendo ou não ser seguidas de lentas alterações regulatórias de volume. Assim, o objetivo do presente trabalho visou esclarecer alguns aspectos do transporte de água em células de melanoma murino S91 submetidas a condições anisosmóticas. Células de melanoma murino S91, foram mantidas em meio de cultura F12 HAM (290 mOsm.kgH2O-1). As medidas morfométricas das mudanças relativas de volume foram realizadas usando-se um sistema de aquisição e análise de imagens (Image Pro-Lite, Media Cybernetics). As células foram expostas tanto a choques hiposmóticos agudos (190 mOsm.kgH2O-1) como a choques hiperosmóticos agudos (350 mOsm.kgH2O-1) em diferentes temperaturas (de 17 a 37 oC) e em diferentes doses (de 0,001 a 1000 µM) de HgCl2, um bloqueador de aquaporinas (AQP). Os resultados sugerem que: (i) o tempo de regulação de volume em células de melanoma murino S91 é dependente da temperatura; (ii) o fluxo osmótico de água apresenta valores de Energia de Ativação compatíveis com aqueles propostos para o trânsito de água através de aquaporinas (Ea < 6 kcal.mol-1); (iii) o HgCl2 afeta de forma dose dependente as respostas osmóticas em células de melanoma murino S91 e sugerem a presença de mais de um tipo de AQP. Nestas condições as concentrações necessárias para reduzir ao máximo a permeabilidade osmótica à água estão localizadas na faixa de 0,1-1,0 µM HgCl2. / One of the major needs of living cells is the regulation of their internal environment. Apart from being of considerable theoretical importance, the transport of water is of practical importance in a broad range of process, from the protection of cells undergoing cryogenic preservation to the effects of certain hormones in some tissues. Virtually all the cells are submitted the osmotic transitions during their period of life, because both intracellular metabolism and transmembrane transport produce fluctuations in concentrations of osmolytes. The regulation of cellular volume is a phenomenon ubiquitous and allows, to the cells, to keep their normal volume. Cells subjected to acute anisosmotic shocks suffer from fast alterations in volume (depending on the osmotic gradient and on the permeability of the membrane to the water and osmotically active substances), and followed or not by a slow volume regulation response. Thus, the present work aims to clarify some aspects of the water transport in murine melanoma S91 cells subjected to anisosmotic conditions. S91 murine melanoma cells were grown in F12 HAM medium (290 mOsm.kgH2O-1). Morphometric measurements of relative changes in cell volume were performed using a video microscopy system and a PC software (Image Pro-Lite, Media Cybernetics). The experimental cells were exposed either to acute hyposmotic shocks (190 mOsm.kgH2O-1) or to acute hyperosmotic shocks (350 mOsm.kgH2O-1), in different temperatures (ranging from 17 to 37 oC) and in the presence of HgCl2 (from 0,001 to 1000 µM), an aquaporin blocker. The results of the present study indicate that: (i) the time of volume regulation in S91 murine melanoma cells is dependent on temperature; (ii) the values of osmotic water flow are compatible with activation energy through aquaporins (E < 6 kcal.mol-1) and (iii) HgCl2 treatments affect osmotic behavior of S91 murine melanoma cells in a dose-response manner and also suggest the presence of more than one type of aquaporin. Minimum osmotic water permeabilities were observed in a range of µM HgCl2 treatments.

HgCl2

Melanoma murino S91

Regulação de volume

Temperatura

HgCl2

Murine melanoma S91

Temperature

Volume regulation

Dentální materiály a imunitní reakce / Dental materials and imunne reaction

Chrástová, Iveta

January 2013

Adverse reactions to metals is relatively frequent in sensitive individuals, and may lead to the development of various diseases, such as lichen planus and lichenoid reaction and was also described effect of amalgam to the pathology of autoimmune diseases. In sensitive patients with known reactions to metals leads to atrophy of the oral mucosa and discomfort (burning, cutting, excessive salivation). Adverse effects of dental materials are described as an allergic reaction type IV delayed hypersensitivity. It disrupt the immune system, increased vascular permeability, tissue is often damaged by chronic inflammation and it is also activated antigen- nonspecific component of immunity. Monocytes are the key cells of the immune system, which act as antigen presenting cells, in particular after conversion in the tissues into macrophages are directly involved in the activation of immune responses and their stimulation is therefore crucial for the development of adverse reactions to dental materials. In the thesis was measured cytokine production by monocytes after stimulation with metal salts. To determine the extent of the patients' responses to the metals was used lymphocyte proliferation assay (MELISA® ), which was developed and patented in Sweden. We compared lymphocyte proliferation after stimulation...

A Study on the Measurement and Analysis of Mercury in Flue Gas Emitted from Municipal Waste Incinerator and the Adsorption of Gaseous Mercury Chloride by Powder Activated Carbon Derived from the Pyrolysis of Waste Tires

Wu, Chun-Hsin

01 August 2000

The objective of this study was to remove mercury vapor from municipal waste incinerator (MWI) by the adsorption of powder activated carbon (PAC) prepared from the pyrolysis of waste tire. The study focused on the measurement of mercury concentration in flue gas emitted from municipal waste incinerator, the preparation of PAC from the pyrolysis of the waste tire and impregnated with sulfur, and the adsorption capacity of mercury by the self-made PAC. The measurement of heavy metals in flue gas emitted from four typical MWIs was conducted in this study. Experimental results obtained from the measurement of mercury from flue gas indicated that the removal efficiency of mercury ranged from 83.71%~96.22%for the tested MWIs. This study revealed that the injection of PAC in flue gas would enhance the removal efficiency of mercury. Besides, oxided mercury (Hg2+) can be removed much more easily than elemental mercury (Hg0). Experimental results obtained from the pyrolysis of waste tires indicated that the pyrolysis temperature of waste tire was approximately 400~500¢J, and the percentage of carbon residue is 35~37%. With higher temperature and water feed rate and longer activation time, the specific surface area and total pore volume of PAC increased while the average pore radius decreased. The highest specific surface area of PAC obtained in this study was 996 m2/g. In addition, experimental results obtained from sulfur impregnation process indicated that the specific surface area of PAC decreased dramatically as sulfur was added to PAC. Experiment results obtained from the adsorption capacity of HgCl2 on PAC by column test indicated that PAC with higher specific surface area could adsorb more HgCl2 at room temperature (25¢J). The adsorption capacity of sulfur impregnated PAC decreased at 25¢J was due to the decrease of specific surface area of PAC. However, results from the comparison of two PAC with similar specific surface area indicated that the PAC with higher sulfur content had higher adsorption capacity. It suggested that the addition of sulfur to PAC could enhance the adsorption of HgCl2 at 25¢J. Experimental results obtained from column tests at 150¢J showed that the adsorption capacity of PAC increased as sulfur content of PAC increased. These results suggested that the adsorption mechanism of HgCl2 by PAC was mainly physical adsorption at lower temperature and it was chemisorption at higher temperature. Besides, the self-made PAC demonstrated the similar adsorption capacity of HgCl2 with commercial PAC used in MWIs.

waste tires

activated carbon

sulfur-impregnation

municipal waste incinerator

pyrolysis

flue gas

HgCl2

mercury

Application of Thermogravimetric Analysis (TGA) Technique on Adsorption Capacity and Adsorption and Desorption Kinetics of Sulfur-impregenated Activated Carbon Saturated with Gaseous Mercury Chloride

Chen, Wei-chin

09 July 2010

The objective of this study is to investigate the influence of sulfur compounds (S and Na2S) for powdered activated carbon derived from carbon black of pyrolyzed waste tires (CPBAC). Besides, this study investigated the distribution of impregnated sulfur in the inner pores of activated carbon and its effected on the specific surface area and pore size distribution. This study investigated the fundamental mechanisms by analysis of thermodynamic properties and to establish the kinetic models for the adsorption/desorption of HgCl2 by/from sulfur impregnated CBPAC. Furthermore, this study investigated the adsorptive and desorption capacity of HgCl2 onto CPBAC via thermogravimetric analysis (TGA). Experimental results indicated that the specific surface area of sulfur impregnated CBPAC with elemental S (S0) was larger than sulfur impregnated CBPAC with Na2S. Besides, the sulfur content of sulfur impregnated CBPAC increased with increasing the surface area of CBPAC under the same impregnated temperature. And, the adsorptive capacity of CBPAC increased with the increase of influent HgCl2 concentration and surface area of the activated carbon. According to the experimental results of the adsorption capacity under the differential sulfur content, its indicated that the affection of sulfur content for adsorption capacity of HgCl2 was much than HgCl2 concentration and surface area of the activated carbon. The desorption energys were 266 and 282 kJ/mole for HgCl2 desorption from saturated CBPAC-S0 and CBPAC-Na2S, respectively. The results showed the process of HgCl2 adsorption onto CBPAC was in favor of a physisorbed state of HgCl2 at the adsorption temperature of 150 oC but the process of HgCl2 adsorption onto CBPAC which impregated was in favor of a chemisorbed state of HgCl2 at the adsorption of 150 oC. The value of ∆G for CBPAC at the adsorption temperature of 30 ~150 oC were ranged from -15.28 kJ/mole to -26.63 kJ/mole. The value of ∆G for CBPAC-S0 at the adsorption temperature of 30~150 oC ranged from -23.45 kJ/mole to -32.09 kJ/mole. The value of ∆G for CBPAC-Na2S at the adsorption temperature of 30~150 oC ranged from -22.84 kJ/mole to -32.72 kJ/mole. The results showed negative values of ∆G confirmed the feasibility of adsorption process and the spontaneous nature for the adsorption of HgCl2. The value of ∆H for CBPAC at the adsorption temperature of 30 ~150 oC ranged from -35.58 kJ/mole to -35.82 kJ/mole. The value of ∆H for CBPAC-S0 at the adsorption temperature of 30 ~150 oC ranged from -38.07 kJ/mole to -52.49 kJ/mole. The value of ∆H for CBPAC-Na2S at the adsorption temperature of 30~150 oC was -37.45 kJ/mole to -53.12 kJ/mole. A negative ∆H suggested that the adsorption of HgCl2 is an exothermic process. Besides, the adsorptive behavior of HgCl2 for two activated carbons (CBPAC-Na2S and CBPAC-S0) at high temperature (110 ¢J and 150 ¢J ) was the same chemical reaction mechanism due to the same ∆H. Besides, the results of model simulation indicated that modified adsorption kinetic model based on pore diffusion scheme developed in this study could successfully simulate the transport and adsorption of HgCl2 by considering the chemical reaction within the inner pores of carbon grains at 150 oC.

thermogravimetric analysis (TGA)

powdered activated carbons

sulfur impregnation

adsorptive capacity of HgCl2

desoption energy

adsorption/desorption kinetic model