AVALIAÇÃO DA ATIVIDADE GENOTOXICA E ANTIGENOTOXICA de Euphorbia tirucalli (Aveloz).

Oliveira, Rodrigo Ansaloni de

08 March 2017

Submitted by admin tede (tede@pucgoias.edu.br) on 2018-04-18T19:00:37Z No. of bitstreams: 1 RODRIGO ANSALONI DE OLIVEIRA.pdf: 564136 bytes, checksum: 846f6a16985a9180c2d4d7056354c90d (MD5) / Made available in DSpace on 2018-04-18T19:00:37Z (GMT). No. of bitstreams: 1 RODRIGO ANSALONI DE OLIVEIRA.pdf: 564136 bytes, checksum: 846f6a16985a9180c2d4d7056354c90d (MD5) Previous issue date: 2017-03-08 / The use of medicinal plants, including extracts, of popular use as a therapeutic resource is a widespread trend in the Brazilian population. Euphorbia tirucalli is widely used by Brazilian popular medicine in the treatment of lesions, infectious diseases, tumors and inflammatory diseases. Through this work. Objective: To evaluate the genotoxic and antigenotoxic activity of Euphorbia tirucalli (aveloz). Methodology: Latex was obtained from a plant specimen, in the city of Goiânia, and diluted to the concentration of 1mg / ml. To evaluate the genotoxic and antigenotoxic activity of the aqueous solution of Euphorbia tirucalli latex were performed by the micronucleus test in the hematopoietic bone marrow of mice. The cytogenetic analysis of the slides was performed in order to detect possible chromosomal changes and / or losses (micronuclei) in the polychromatic erythrocytes of the bone marrow of the animals submitted to the different treatments. Results: In the treatments concomitant with the aqueous solutions of latex of Euphorbia tirucalli and Mitomycin C, there was a decrease in micronuclei numbers in 2000 EPC. The results allowed to conclude that the aqueous solutions of Euphorbia Tirucalli latex presented genotoxic, antigenotoxic, cytotoxic and anticitotoxic activity and the concomitant use of the aqueous solutions of the latex of Euphorbia tirucalli and Mitomycin C was not indicated, as the genotoxic and cytotoxic effects of MMC were decreased And thus not achieving the expected effect of this highly genotoxic agent. / A utilização de plantas medicinais, incluindo os extratos, de uso popular como recurso terapêutico é uma tendência generalizada na população brasileira. A Euphorbia tirucalli é amplamente utilizada pela medicina popular brasileira no tratamento de lesões, doenças infecciosas, tumores e doenças inflamatórias. Por meio deste trabalho. Objetivo: Avaliar a atividade genotóxica e antigenotóxica de Euphorbia tirucalli (aveloz). Metodologia: O látex foi obtido de um exemplar da planta, na cidade de Goiânia, e diluído para a concentração de 1mg/ml. Para a avaliação da atividade genotóxica e antigenotóxica da solução aquosa do látex da Euphorbia tirucalli foram realizadas pelo teste de micronúcleo na medula óssea hematopoiética de camundongos. A análise citogenética das lâminas foi realizada com a finalidade de se detectar possíveis alterações e/ou perdas cromossômicas (micronúcleos) nos eritrócitos policromáticos (EPC) da medula óssea dos animais submetidos aos diferentes tratamentos. Resultados: Nos tratamentos concomitantes com as soluções aquosas do látex da Euphorbia tirucalli e Mitomicina C, houve diminuição dos números de micronúcleos em 2.000 EPC. Os resultados permitiram concluir que as soluções aquosas do látex da Euphorbia Tirucalli apresentaram atividade genotóxica, antigenotóxica, citotóxica e anticitotóxica e não indicado o uso concomitante das soluções aquosas do látex da Euphorbia tirucalli e Mitomicina C, pois os efeitos genotóxicos e citotóxicos da MMC foram diminuídos e assim não obtendo o efeito esperado deste agente altamente genotóxico.

CIENCIAS DA SAUDE

Latex of <em>Sciadopitys verticillata</em> (Thunb.) Siebold and Zuccarini: Antibiotic Properties, Phytochemistry, and Inhibition of Adventitious Rooting of Stem Cuttings.

Yates, David Ira

15 August 2006

Sciadopitys verticillata was subjected to three propagation treatments designed to inhibit coagulation of its latex-like sap at the cut ends of the stem cuttings. Twenty-four hour soaking in water prior to rooting hormone application significantly enhanced production of adventitious roots. Old wood stem cuttings from shade-grown trees rooted at higher proportions than stem cuttings collected from sun-grown trees. Height, age, and place of origin of the source trees were not important factors in successful rooting. Antibacterial activity against some human pathogens and soil bacterial species was detected in latex application trials but the antibiotic activity was not related to the bacterial Gram reaction. The latex-like sap inhibited none of four plant pathogens tested. A suspension of the water insoluble latex-like sap of S. verticillata had a pH of 5.8. Antibacterial activity of S. verticillata sap was heat stable, which indicates the activity was not protein-based.

latex

vegetative propagation

stem cuttings

antibiotic

Sciadopitys verticillata

Life Sciences

Plant Biology

Plant Sciences

Design, Construction, and Characterization of the University of South Florida Wind Tunnel

Garcia, Jason S.

04 June 2018

Much of the aerosol research completed at the University of South Florida has revolved around evaluating industrial hygiene equipment and instrumentation in environmental chambers. Data collected during these studies has provided valuable baseline data on equipment and instrument performance under calm air conditions. A newly constructed wind tunnel now allows researchers to evaluate industrial hygiene instruments under moving air conditions. Because the wind tunnel is capable of producing wind velocities that a worker could encounter in the occupational setting, researchers may gain insight into instrument performance under simulated field conditions. Because aerosols can be introduced into the new wind tunnel testing section, researchers can also challenge industrial hygiene equipment and instrumentation with aerosols in sizes ranges that are of interest in public health. The purpose of this dissertation research was to develop a new wind tunnel to be used for aerosol research at the University of South Florida. Three specific aims had to be met for this study to be successful. They included: (1) designing a wind tunnel based on best practice information outlined in scientific literature, (2) constructing an operable wind tunnel to be used for aerosol research, and (3) characterizing wind tunnel performance by examining the wind tunnel velocity profile, turbulence intensity, and aerosol introduction/collection. The actual wind tunnel was constructed to a length of approximately 20 feet, a height of approximately 2 feet at its tallest point, and includes an entrance filter housing, a settling chamber, a contraction, a testing section, a diffuser, an exit filter housing, a fan, and exhaust duct. All components were designed and constructed using guidelines and best practices reported in the scientific literature. Velocity profile measurements were the first way that this wind tunnel was characterized. In order to successfully obtain measurements, the wind tunnel cross section was divided into 16 equal quadrants. Five measurements were taken for each quadrant at each wind velocity. Target wind velocities for this research were 0.5 m/s, 1.0 m/s, and 2.0 m/s. Actual average wind velocities of 0.48 m/s, 1.00 m/s, and 2.04 m/s. All were within established limits reported in the scientific literature. Turbulence intensity measurements were the second way that this wind tunnel was characterized. In order to successfully obtain measurements, the wind tunnel cross section was divided into 16 equal quadrants. Five measurements were taken for each quadrant at each wind velocity. Wind tunnels are typically designed to have the lowest turbulence intensity possible, generally below 10%. The overall average turbulence intensities for this wind tunnel at wind velocities of 0.5 m/s, 1.0 m/s, and 2.0 m/s were 9%, 10%, and 8% respectively. Overall turbulence intensity measurements were at or below 10%. Isokinetic sampling was the final method used to characterize this wind tunnel by collecting and detecting aerosols traveling through the wind tunnel testing section. The wind tunnel was operated at wind velocities of 0.5 m/s, 1.0 m/s, and 2.0 m/s with isokinetic sampling flow rates of 15.4 L/min, 30.9 L/min, and 61.7 L/min respectively. Monodisperse fluorescent polystyrene latex spheres were used as the test aerosol because they are uniform in size and shape and can be detected by fluorometry. The Blaustein Multi-Jet Atomizer (BLAM) was used to generate monodisperse fluorescent polystyrene latex aerosol 0.5 µm and 2.0 µm particles from liquid suspensions. The Vilnius Aerosol Generator (VAG) was used to generate monodisperse fluorescent polystyrene latex aerosol of 6.0 µm and 12.0 µm particles from dry powders. Nitrogen gas was used for delivering test aerosols into the wind tunnel. Five experimental runs were completed for each particle size and wind velocity for a total of 60 experimental runs. Fluorescence was detected in all 60 samples with average mass concentrations ranging from 0.000050 ng/ml to 0.002703 ng/ml. Based on velocity profile measurements, turbulence intensity measurements, and isokinetic sampling, the performance of University of South Florida wind tunnel was found to be excellent, indicating that it was designed and constructed appropriately. The wind tunnel can now successfully be used by researchers interested in evaluating industrial hygiene sampling equipment with aerosols ranging from 0.5 µm to 12.0 µm in moving air with velocities ranging from 0.5 m/s to 2.0 m/s.

Fluorescent Polystyrene Latex Spheres

Fluorometry

Turbulence Intensity

Velocity Profile

Wind Tunnel

Public Health

Caractérisation de billes de latex fluorescentes pour l'élaboration de nanocapteurs

Méallet-Renault, Rachel

20 March 2000

Nous avons montré la faisabilité d 'une approche de capteur où les fonctions de détection et de signalisation sont séparées. Nous avons choisi comme supports lumineux des nanosphères fluorescentes. Elles servent de transducteurs. Nous avons exploré la modularité du capteur en essayant plusieurs molécules sondes adsorbées à la surface des billes. Nous avons montré que l'information entre la détection (sonde) et la signalisation (bille) est relayée par transfert d'énergie.

[CHIM] Chemical Sciences

billes de latex

fluorescence

nanocapteur

transfert d'énergie

microspectroscopie

bleu de méthylène

cytochrome c

TMPyP

Adhésifs nanostructurés en voie émulsion

Deplace, Fanny

11 April 2008

Nous avons étudié les propriétés d'adhésion et de déformation de films de polymères adhésifs préparés à partir de particules de latex nanostructurées. Une méthodologie basée sur deux critères rhéologiques et applicable à tout type de PSA a été proposée pour optimiser les performances adhésives. Elle nous a permis d'identifier des stratégies permettant d'améliorer le compromis entre propriétés adhésives et cohésives dans le cas particulier de PSA préparés à partir de particules de latex ayant une morphologie cœur-écorce. Une stratégie intéressante est l'activation d'une réaction de réticulation interparticule pendant le séchage du latex. Nous avons fait varier l'hétérogénéité du réseau tout en gardant constante la composition en monomères. Nous avons montré l'effet remarquable de cette réaction de réticulation sur les propriétés en grandes déformations de nos matériaux. Ces propriétés sont assez bien décrites par un modèle non-linéaire combinant le modèle de Maxwell sur convecté et le modèle de Gent. Les meilleurs résultats d'adhésion sont obtenus pour des matériaux caractérisés par un net ramollissement à déformations intermédiaires suivi d'un rhéodurcissement. Ce comportement est notamment obtenu pour des PSA préparés à partir de particules de latex ayant une fine écorce assez réticulée et un cœur très mou. Dans un registre plus industriel, des performances adhésives prometteuses ont été obtenues avec des PSA préparés à partir de latex tackifiés in situ synthétisés par polymérisation en miniémulsion.

[CHIM] Chemical Sciences

Adhésion

PSA à base aqueuse

Particule de latex

Structure hétérogène

Viscoélasticité linéaire

Influence des paramètres moléculaires du latex sur l'hydratation, la rhéologie et les propriétés mécaniques des composites ciment/latex

Goto, Tania

30 October 2006

Dans l'industrie du second œuvre, les mortiers additionnés de latex sont largement utilisés. Cependant, à côté des améliorations d'usage qu'ils confèrent aux formulations, ils sont à l'origine de temps d'hydratation des pâtes plus importants. L'objectif de cette thèse est d'expliquer l'origine de cette augmentation des temps d'hydratation et de déterminer ses répercussions sur les propriétés rhéologiques et mécaniques des composites ciment/latex. Pour cela, l'étude de l'interaction de quatre familles de latex avec un ciment gris ordinaire a été menée. Il en ressort que les charges présentes dans le système de stabilisation du latex et les molécules hydrosolubles présentes dans la phase aqueuse du latex ont une forte influence sur l'hydratation du ciment. Cette forte influence ne se retrouve cependant pas sur les propriétés rhéologiques et mécaniques de la pâte.

[SPI] Engineering Sciences

Surfactants in anionic latex films

Paakkonen, Johan

January 2010

No description available.

Surfactants

DoTAB

SDS

Brij30

Latex

Film formation

Colloids

Anionic

Cationic

Physical chemistry

Fysikalisk kemi

Performance Improvement of Latex-based PSAs Using Polymer Microstructure Control

Qie, Lili

02 February 2011

This thesis aims to improve the performance of latex-based pressure-sensitive adhesives (PSAs). PSA performance is usually evaluated by tack, peel strength and shear strength. Tack and peel strength characterize a PSA’s bonding strength to a substrate while shear strength reflects a PSA’s capability to resist shear deformation. In general, increasing shear strength leads to a decrease in tack and peel strength. While there are several commercial PSA synthesis methods, the two most important methods consist of either solvent-based or latex-based techniques. While latex-based PSAs are more environmentally compliant than solvent-based PSAs, they tend to have much lower shear strength, at similar tack and peel strength levels. Therefore, the goal in this thesis was to greatly improve the shear strength of latex-based PSAs at little to no sacrifice to tack and peel strength. In this study, controlling the polymer microstructure of latexes or their corresponding PSA films was used as the main method for improving the PSA performance. The research was sub-divided into four parts. First, the influence of chain transfer agent (CTA) and cross-linker on latex polymer microstructure was studied via seeded semi-batch emulsion polymerization of butyl acrylate (BA) and methyl methacrylate (MMA). Three techniques were used to produce the latexes: (1) adding CTA only, (2) adding cross-linker only, and (3) adding both CTA and cross-linker. It was found that using CTA and cross-linker simultaneously allows one to expand the range of latex microstructural possibilities. For example, latexes with similar gel contents but different Mc (molecular weight between cross-links) and Mw (molecular weight of sol polymers) could be produced if CTA and cross-linker concentration are both increased. However, for the corresponding PSAs with similar gel contents, the relationship between their polymer microstructure and performance was difficult to establish as almost all of the medium and high gel content PSAs showed very low tack and peel strength as well as extremely large shear strength readings. In the second part of this thesis, in order to improve the tack and peel strength of medium and high gel content PSAs, the monomer composition and emulsifier concentration were varied. It was found that changing the monomer mixture from BA/MMA to BA/acrylic acid (AA)/2-hydroxyethyl methacrylate (HEMA) while simultaneously decreasing emulsifier concentration dramatically improved the corresponding PSAs’ shear strength as well as tack and peel strength. The addition of polar groups to the PSA increased its cohesive strength due to the presence of strong hydrogen bonding; meanwhile, PSA films’ surface tension increased. In the third part, two series of BA/AA/HEMA latexes were generated by varying the amounts of CTA either in the absence or presence of cross-linker. The latexes produced in the absence of cross-linker exhibited significantly larger Mc and Mw compared to their counterparts with similar gel contents prepared with cross-linker. The PSAs with the larger Mc and Mw showed much larger shear strengths due to improved entanglements between the polymer chains. In the final part of the thesis, the performance of the BA/AA/HEMA PSAs was further improved by post-heating. Compared with original latex-based PSAs with similar gel contents, heat-treated PSAs showed not only significantly improved shear strengths, but also much larger tack and peel strengths. The different shear strengths were related to the PSAs’ gel structures, which were discrete in the original PSAs but continuous in the heat-treated PSAs. The improved tack and peel strengths were related to the PSA films’ surface smoothness. During the post-heating process, the PSA polymer flowed, resulting in much smoother surfaces than the original PSA films. In addition, the effect of post-heating was related to the polymer microstructure of the untreated PSAs. Decreasing the amount of very small or very big polymers or simultaneously increasing Mc and Mw could lead to post-treated PSAs with significantly better performance. Moreover, it was found that by optimizing the polymer microstructure of the original latex-based PSAs, it was possible to obtain a treated PSA with similar or even better performance than a solvent-based PSA with similar polymer microstructure. Our original objective was surpassed: in two cases, not only was shear strength greatly improved, but so were tack and peel strength due to the simultaneous modification of PSA bulk and surface properties.

Emulsion polymerization

Latex

Polymer microstructure

Polymer composition

Polymer rheology

Pressure sensitive adhesives (PSAs)

PSAs' performance

Performance Improvement of Latex-based PSAs Using Polymer Microstructure Control

Qie, Lili

02 February 2011

This thesis aims to improve the performance of latex-based pressure-sensitive adhesives (PSAs). PSA performance is usually evaluated by tack, peel strength and shear strength. Tack and peel strength characterize a PSA’s bonding strength to a substrate while shear strength reflects a PSA’s capability to resist shear deformation. In general, increasing shear strength leads to a decrease in tack and peel strength. While there are several commercial PSA synthesis methods, the two most important methods consist of either solvent-based or latex-based techniques. While latex-based PSAs are more environmentally compliant than solvent-based PSAs, they tend to have much lower shear strength, at similar tack and peel strength levels. Therefore, the goal in this thesis was to greatly improve the shear strength of latex-based PSAs at little to no sacrifice to tack and peel strength. In this study, controlling the polymer microstructure of latexes or their corresponding PSA films was used as the main method for improving the PSA performance. The research was sub-divided into four parts. First, the influence of chain transfer agent (CTA) and cross-linker on latex polymer microstructure was studied via seeded semi-batch emulsion polymerization of butyl acrylate (BA) and methyl methacrylate (MMA). Three techniques were used to produce the latexes: (1) adding CTA only, (2) adding cross-linker only, and (3) adding both CTA and cross-linker. It was found that using CTA and cross-linker simultaneously allows one to expand the range of latex microstructural possibilities. For example, latexes with similar gel contents but different Mc (molecular weight between cross-links) and Mw (molecular weight of sol polymers) could be produced if CTA and cross-linker concentration are both increased. However, for the corresponding PSAs with similar gel contents, the relationship between their polymer microstructure and performance was difficult to establish as almost all of the medium and high gel content PSAs showed very low tack and peel strength as well as extremely large shear strength readings. In the second part of this thesis, in order to improve the tack and peel strength of medium and high gel content PSAs, the monomer composition and emulsifier concentration were varied. It was found that changing the monomer mixture from BA/MMA to BA/acrylic acid (AA)/2-hydroxyethyl methacrylate (HEMA) while simultaneously decreasing emulsifier concentration dramatically improved the corresponding PSAs’ shear strength as well as tack and peel strength. The addition of polar groups to the PSA increased its cohesive strength due to the presence of strong hydrogen bonding; meanwhile, PSA films’ surface tension increased. In the third part, two series of BA/AA/HEMA latexes were generated by varying the amounts of CTA either in the absence or presence of cross-linker. The latexes produced in the absence of cross-linker exhibited significantly larger Mc and Mw compared to their counterparts with similar gel contents prepared with cross-linker. The PSAs with the larger Mc and Mw showed much larger shear strengths due to improved entanglements between the polymer chains. In the final part of the thesis, the performance of the BA/AA/HEMA PSAs was further improved by post-heating. Compared with original latex-based PSAs with similar gel contents, heat-treated PSAs showed not only significantly improved shear strengths, but also much larger tack and peel strengths. The different shear strengths were related to the PSAs’ gel structures, which were discrete in the original PSAs but continuous in the heat-treated PSAs. The improved tack and peel strengths were related to the PSA films’ surface smoothness. During the post-heating process, the PSA polymer flowed, resulting in much smoother surfaces than the original PSA films. In addition, the effect of post-heating was related to the polymer microstructure of the untreated PSAs. Decreasing the amount of very small or very big polymers or simultaneously increasing Mc and Mw could lead to post-treated PSAs with significantly better performance. Moreover, it was found that by optimizing the polymer microstructure of the original latex-based PSAs, it was possible to obtain a treated PSA with similar or even better performance than a solvent-based PSA with similar polymer microstructure. Our original objective was surpassed: in two cases, not only was shear strength greatly improved, but so were tack and peel strength due to the simultaneous modification of PSA bulk and surface properties.

Emulsion polymerization

Latex

Polymer microstructure

Polymer composition

Polymer rheology

Pressure sensitive adhesives (PSAs)

PSAs' performance

Direct Catalytic Hydrogenation of Unsaturated Diene-Based Polymers in Latex Form

Wei, Zhenli

January 2006

The direct catalytic hydrogenation of nitrile butadiene rubber (NBR) in latex form was studied as a model system for the development of a new latex hydrogenation process for the modification of unsaturated diene-based polymers. NBR is a synthetic rubber of copolymerized acrylonitrile and butadiene produced in latex form by emulsion polymerization. The catalytic hydrogenation of NBR is an important post-polymerization process resulting in a more stable and tougher derivative, hydrogenated NBR (HNBR), which has been widely used in the automotive and oil drilling industry. The present commercial process involves a number of cumbersome steps to obtain solid NBR from the latex and subsequent dissolution of the solid NBR in a large amount of organic solvent followed by solvent recovery after coagulation of the hydrogenated NBR. Since NBR is produced in latex form, it is very desirable to directly hydrogenate NBR in the latex form which will significantly simplify the hydrogenation process and facilitate subsequent applications. As an economical and environmentally benign alternative to the commercial processes based on the hydrogenation of NBR in organic solution, this direct latex hydrogenation process is of special interest to industry. The objective of this project is to develop an efficient catalytic system in order to realize the direct catalytic hydrogenation of NBR in latex form. OsHCl(CO)(O2)(PCy3)2 was initially used as the catalyst to investigate the possibility of hydrogenation of NBR in latex form and to understand the major factors which affect the hydrogenation operation. It was found that an organic solvent which is capable of dissolving or swelling the NBR was needed in a very small amount for the latex hydrogenation using the Os catalyst, and gel occurred in such a catalytic system during hydrogenation. Wilkinson’s catalyst, RhCl(PPh3)3, was then used for the latex hydrogenation in the presence of a small amount of solvent successfully without gel formation. Further investigation found that Wilkinson’s catalyst has a high activity for NBR latex hydrogenation without the use of any organic solvent. The influences of various operation conditions on hydrogenation rate, such as catalyst and polymer concentrations, latex system composition, agitation, reaction temperature and hydrogen pressure, have been investigated. It was found that the addition of triphenylphosphine (TPP) has a critical effect for the hydrogenation of NBR latex, and the hydrogenation rate was mainly controlled by the amount of catalyst which diffused into the polymer particles. In the presence of TPP, NBR latex can be hydrogenated to more than 95% degree of hydrogenation after about 30 hours at 160oC using Wilkinson’s catalyst with a catalyst to NBR rubber ratio of 1 wt%, without the addition of any organic solvent. The apparent activation energy for such NBR latex hydrogenation over the temperature range of 152oC to 170oC was found to be 57.0 kJ/mol. In the present study, it was also found that there are some impurities within the NBR latex which are detrimental to the hydrogenation reaction and are suspected to be water-soluble surfactant molecules. Deliberately designed solution hydrogenation experiments were conducted to study the impurity issue, and proper latex treatment methods have been found to purify the latex before hydrogenation. To improve the hydrogenation rate and to optimize the latex hydrogenation system, water soluble RhCl(TPPMS)3 catalyst (TPPMS: monosulphonated-triphenylphosphine) was used for the latex hydrogenation of NBR. The latex hydrogenation using the water soluble catalyst with TPP can achieve more than 90% degree of hydrogenation within 20 hours at 160oC. Further experiments using RhCl3 with TPP proved that the water soluble RhCl3 can be directly used as a catalyst precursor to generate the catalytic species in situ for the latex hydrogenation, and a stable NBR latex with 96% degree of hydrogenation can be produced without any gel problem within 19 hours of reaction at 160oC. The catalyst mass transport processes for these Rh based catalysts in the latex system were investigated in order to further optimize the solvent-free latex hydrogenation process. While maintaining the emulsified state of the original latex, the direct catalytic hydrogenation of NBR latex can be carried out efficiently without any cross-linking problem to more than 92% degree of hydrogenation within 8 hours at 160oC. As a result of this research project, new latex hydrogenation technologies were successfully developed to fulfill all major requirements for a solvent-free polymer latex hydrogenation route, which is a significant milestone for the improvement of this polymer modification technology. The finding of TPP’s role as the “catalyst mass transfer promoter” is a breakthrough for the research field related to the hydrogenation of unsaturated diene-based polymers in latex form.

catalytic hydrogenation

nitrile butadiene rubber

Wilkinson's catalyst

polymer latex

solvent free

triphenylphosphine

Chemical Engineering