Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model
The production of chemical compounds used by human beings is growing, producing great benefits in the progress of civilization and comfort in people's lives, while on the other hand it generates exposure to living beings and nature, exerting a great variety of interactions with their systems an...
- Autores:
-
García Espiñeira, María Cecilia
- Tipo de recurso:
- Doctoral thesis
- Fecha de publicación:
- 2018
- Institución:
- Universidad de Cartagena
- Repositorio:
- Repositorio Universidad de Cartagena
- Idioma:
- eng
- OAI Identifier:
- oai:repositorio.unicartagena.edu.co:11227/16530
- Acceso en línea:
- https://hdl.handle.net/11227/16530
http://dx.doi.org/10.57799/11227/11864
- Palabra clave:
- Toxicology
Química toxicológica
Organic compounds
Química orgánica
- Rights
- openAccess
- License
- Derechos Reservados - Universidad de Cartagena, 2018
id |
UCART2_d07bc0e0fa5f87e58e1d6b405d6c1beb |
---|---|
oai_identifier_str |
oai:repositorio.unicartagena.edu.co:11227/16530 |
network_acronym_str |
UCART2 |
network_name_str |
Repositorio Universidad de Cartagena |
repository_id_str |
|
dc.title.eng.fl_str_mv |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
title |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
spellingShingle |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model Toxicology Química toxicológica Organic compounds Química orgánica |
title_short |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
title_full |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
title_fullStr |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
title_full_unstemmed |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
title_sort |
Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological model |
dc.creator.fl_str_mv |
García Espiñeira, María Cecilia |
dc.contributor.advisor.none.fl_str_mv |
Olivero Verbel, Jesús |
dc.contributor.author.none.fl_str_mv |
García Espiñeira, María Cecilia |
dc.subject.armarc.none.fl_str_mv |
Toxicology Química toxicológica Organic compounds Química orgánica |
topic |
Toxicology Química toxicológica Organic compounds Química orgánica |
description |
The production of chemical compounds used by human beings is growing, producing great benefits in the progress of civilization and comfort in people's lives, while on the other hand it generates exposure to living beings and nature, exerting a great variety of interactions with their systems and toxicity. Bisphenol A is a chemical compound massively used as a plasticizer in a varied range of elements for daily use. Propylparaben and triclosan are chemical compounds that extend the half-life and avoid contamination with bacteria and fungi of personal care products. Atrazine and glyphosate, in turn, are molecules used in agriculture, as broad-spectrum herbicides. Although several negative effects have been described in animals and humans, its use in many Latin American countries is still common. Biological models are used throughout the world to determine the acute and chronic toxicity of many chemicals and have been effective in reproducing toxicity mechanisms. C. elegans, is a nematode that facilitates these studies because of its multiple advantages, among which are having a fully sequenced genome, simple maintenance in laboratory conditions, a short life cycle, small size, simple anatomy, transparency and sensitivity for acute and chronic detection of toxicity, as well as an easy understanding of the biochemical mechanisms involved, allowing a more accurate prediction of the toxicity of studied compounds. In addition, a large number of nematodes can be studied in a single experiment within a short period of time, with fewer ethical problems and comparatively cheaper compared to using other animal models. In this study, four stages are contemplated: the first evaluates the toxicity of the five molecules described in the biological model C. elegans taking into account endpoints such as mortality, growth, fertility and progeny size. The second one studies the amount of fatty acid deposits in the bodies of worms; the third was the expression of C. elegans genes related to oxidative stress, by reporter genes associated with green protein fluorescence (GFP) and the fourth one determined the adipogenic action of one of the molecules (BPA) in human adipoblasts cells. The lethality of C. elegans exposed to BPA, PPB and TCS was concentration dependent, and the LC50 after 24 h of exposure was 113.5, 261.7 and 43.2 µM, respectively. At concentrations greater than 0.5 µM, BPA, PPB and TCS caused lethality, with statistical differences related to the control. At lower concentrations, only TCS (0.05 µM) was bioactive. In solutions of BPA, PPB and TCS: body length increased slightly with BPA but did not depend on the concentration. In contrast, PPB reduced body length, whereas TCS did not have an effect on this parameter. The body width increased moderately, without a clear relationship with the concentration, although the response caused by BPA was bimodal. The relationship between body width and body length of the nematodes was moderately increased by exposure to the tested chemicals, but the PPB was the most active, suggesting a probable association with obesity in the C. elegans model. Breeding size of nematodes exposed to BPA, PPB and TCS: the largest brood size after exposure to BPA was reached at 5 µM; then, it decreased in response to higher concentrations. Similarly, the PPB increased brood size to 0.5 µM, with declining effects at higher concentrations. In contrast, TCS decreased this feature following a trend dependent on concentration. The most sensitive genes, in descending order, were sod-4, hsp4, hsp-16.2 and skn-1. These genes increased their expression after exposure to BPA, PPB and TCS, indicating a toxic response related to the generation of reactive oxygen species (ROS). There was no evidence of concentration dependence on these results. In addition, low concentrations caused the overexpression of some genes; for example, BPA at concentrations of 0.05 and 0.5 µM caused a 3-fold expression of hsp-4. However, the high concentrations also affected the expression of several genes such as sod-4, which showed a 5-fold positive regulation after exposure to PPB and TCS at a concentration of 500 µM compared to the control. The chemical compounds BPA, PPB and TCS caused an increase in the accumulation of lipids in the bodies of the exposed nematodes when staining with q-ORO. These deposits showed an increasing tendency related to the concentration. BPA caused a greater accumulation of lipids, followed by PPB and TCS. This result was consistent with the changes in the body wide-long relationship that were recorded in the worms after exposure to these molecules. In this study, four stages were contemplated: the first evaluates the toxicity of the five molecules described in the biological model C. eleganstaking into account endpoints such as mortality, growth, fertility and progeny size. The second one studies the amount of fatty acid deposits in the bodies of nematodes; the third was the expression of the biomodel genes related to oxidative stress, by reporter genes associated with green protein fluorescence (GFP) and the fourth one determined the adipogenic action of one of the molecules (BPA) in human adipoblasts cells. The lethality of C. elegans exposed to BPA, PPB and TCS was concentration dependent, and the LC50 after 24 h of exposure was 113.5, 261.7 and 43.2 µM, respectively. At concentrations greater than 0.5 µM, BPA, PPB and TCS caused lethality, with statistical differences related to the control. At lower concentrations, only TCS (0.05 µM) was bioactive. In solutions of BPA, PPB and TCS: body length increased slightly with BPA but did not depend on the concentration. In contrast, PPB reduced body length, whereas TCS did not have an effect on this parameter. The body width increased moderately, without a clear relationship with the concentration, although the response caused by BPA was bimodal. The relationship between body width and body length of the nematodes was moderately increased by exposure to the tested chemicals, but the PPB was the most active, suggesting a probable association with obesity in the C. elegans model. The most sensitive genes, in descending order, were sod-4, hsp4, hsp-16.2 and skn-1. These genes increased their expression after exposure to BPA, PPB and TCS, indicating a toxic response related to the generation of reactive oxygen species (ROS). There was no evidence of concentration dependence on these results. In addition, low concentrations caused the overexpression of some genes; for example, BPA at concentrations of 0.05 and 0.5 µM caused a 3-fold expression of hsp-4. However, the high concentrations also affected the expression of several genes such as sod-4, which showed a 5-fold positive regulation after exposure to PPB and TCS at concentrations of 500 µM compared to the control. The chemical compounds BPA, PPB and TCS caused an increase in the accumulation of lipids in the bodies of the exposed nematodes when staining with q-ORO, the deposits showed an increasing tendency related to the concentration. BPA caused a greater accumulation of lipids, followed by PPB and TCS. This result was consistent with the changes in the body wide-long relationship that were recorded in the worms after exposure to these molecules. The mean lethal concentration value for atrazine was> 600 µM, and the NOAEL and LOAEL were 0.006 and 0.06 µM, respectively. The lethality percentages for the 0.0006 and 0.006 µM solutions had no significant differences with the control, but concentrations higher than 0.06 µM induced significant lethality, reaching up to 18 % at 600 µM. The BBF decreased to 5 for a 600 µM solution following a concentration-dependent route. The length of the body did not follow a strict pattern dependent on concentration. However, concentrations higher than 60 µM inhibited body growth. In comparison with the control, the inhibition of the size of the brood was greater to a solution of 6 µM, reaching almost 100 %. However, it increased again to 60 and 600 µM, showing a modest U-shaped graph. Mean lethal concentration value for glyphosate was 6.4 µM (the NOAEL and LOAEL were 0.001 and 0.01 µM, respectively). At concentrations greater than 100 µM, total lethality was achieved. The BBF decreased from 38.2 bends in 20 s (control) to 5 at 10 µM, following a concentration-dependent trend. The body length did not register any significant change up to 1 µM, but it statistically decreased at 10 µM. The brood size followed a concentration-dependent curve, with maximum inhibition at 10 µM solution. Glyphosate concentration-response behavior was similar to that elicited by atrazine, the first been more potent. The expression of sod-1, sod-4, and gpx-4 increased at least 2-fold than the control at just 10 µM solution. The lethality for the exposure mixtures of atrazine-glyphosate was concentration-dependent. Maximum lethality occurred with glyphosate 1000 µM + atrazine 600 µM, reaching 80 %. The BBF was inhibited at the lowest tested concentrations. It followed a concentration-dependent tendency similar to that experienced by glyphosate alone. The body length was also affected by the minimum herbicide concentration, but the slope of the concentration-response curve was minimal. In the concentration addition model assay, the lethality of the mixture showed that at low concentrations the effect is additive, whereas at high concentrations the lethality of the mixture was lower than the effect of GBF alone. The gene expression behavior for tested genes of the mixture of atrazine-glyphosate was similar to that observed for individual molecules. In summary, with the obtained results it is demonstrated that the molecules atrazine, glyphosate, bisphenol A, propylparaben and triclosan exert toxicity C. elegans and its endocrine disruption effects are qualitative and quantitatively measurable on the on the biological model. |
publishDate |
2018 |
dc.date.issued.none.fl_str_mv |
2018 |
dc.date.accessioned.none.fl_str_mv |
2023-06-20T20:31:50Z |
dc.date.available.none.fl_str_mv |
2023-06-20T20:31:50Z |
dc.type.spa.fl_str_mv |
Trabajo de grado - Doctorado |
dc.type.coarversion.fl_str_mv |
http://purl.org/coar/version/c_970fb48d4fbd8a85 |
dc.type.version.spa.fl_str_mv |
info:eu-repo/semantics/publishedVersion |
dc.type.coar.spa.fl_str_mv |
http://purl.org/coar/resource_type/c_db06 |
dc.type.content.spa.fl_str_mv |
Text |
dc.type.driver.spa.fl_str_mv |
info:eu-repo/semantics/doctoralThesis |
dc.type.redcol.spa.fl_str_mv |
https://purl.org/redcol/resource_type/TD |
format |
http://purl.org/coar/resource_type/c_db06 |
status_str |
publishedVersion |
dc.identifier.uri.none.fl_str_mv |
https://hdl.handle.net/11227/16530 http://dx.doi.org/10.57799/11227/11864 |
url |
https://hdl.handle.net/11227/16530 http://dx.doi.org/10.57799/11227/11864 |
dc.language.iso.spa.fl_str_mv |
eng |
language |
eng |
dc.rights.spa.fl_str_mv |
Derechos Reservados - Universidad de Cartagena, 2018 |
dc.rights.coar.fl_str_mv |
http://purl.org/coar/access_right/c_abf2 |
dc.rights.uri.spa.fl_str_mv |
https://creativecommons.org/licenses/by-nc/4.0/ |
dc.rights.accessrights.spa.fl_str_mv |
info:eu-repo/semantics/openAccess |
dc.rights.creativecommons.spa.fl_str_mv |
Atribución-NoComercial 4.0 Internacional (CC BY-NC 4.0) |
rights_invalid_str_mv |
Derechos Reservados - Universidad de Cartagena, 2018 https://creativecommons.org/licenses/by-nc/4.0/ Atribución-NoComercial 4.0 Internacional (CC BY-NC 4.0) http://purl.org/coar/access_right/c_abf2 |
eu_rights_str_mv |
openAccess |
dc.format.mimetype.spa.fl_str_mv |
application/pdf |
dc.publisher.spa.fl_str_mv |
Universidad de Cartagena |
dc.publisher.faculty.spa.fl_str_mv |
Facultad de Ciencias Farmacéuticas |
dc.publisher.place.spa.fl_str_mv |
Cartagena de Indias |
dc.publisher.program.spa.fl_str_mv |
Doctorado en Toxicología Ambiental |
institution |
Universidad de Cartagena |
bitstream.url.fl_str_mv |
https://dspace7-unicartagena.metabuscador.org/bitstreams/acac8f80-47de-4605-bb44-dd6c6cfd1145/download https://dspace7-unicartagena.metabuscador.org/bitstreams/6fbdab12-9055-4b34-9503-b6d92a6d13fe/download https://dspace7-unicartagena.metabuscador.org/bitstreams/29b4aef8-589d-458e-8080-641b23816e01/download https://dspace7-unicartagena.metabuscador.org/bitstreams/3cb6a140-a36d-4187-976a-0c5febca77f1/download https://dspace7-unicartagena.metabuscador.org/bitstreams/defe5ae0-3178-4658-9d73-ae8f92e9798f/download https://dspace7-unicartagena.metabuscador.org/bitstreams/29e92885-8aed-4dfe-beb5-fbbdf345a0f9/download https://dspace7-unicartagena.metabuscador.org/bitstreams/0b9ee316-2523-4e18-b12e-4804fba4cba0/download |
bitstream.checksum.fl_str_mv |
f8ce5e2c01522a08117b277079d3d54a a625cfb7dc652a473eceb45f55cd192f 7b38fcee9ba3bc8639fa56f350c81be3 2f650129c14dfce33e66c6fdf83a0b8a 68b329da9893e34099c7d8ad5cb9c940 30bbd007e8fcb461cd9522e64b70108b 1f5966a7b703f7256f25214d309f487c |
bitstream.checksumAlgorithm.fl_str_mv |
MD5 MD5 MD5 MD5 MD5 MD5 MD5 |
repository.name.fl_str_mv |
Biblioteca Digital Universidad de Cartagena |
repository.mail.fl_str_mv |
bdigital@metabiblioteca.com |
_version_ |
1814214241523073024 |
spelling |
Olivero Verbel, JesúsGarcía Espiñeira, María Cecilia2023-06-20T20:31:50Z2023-06-20T20:31:50Z2018https://hdl.handle.net/11227/16530http://dx.doi.org/10.57799/11227/11864The production of chemical compounds used by human beings is growing, producing great benefits in the progress of civilization and comfort in people's lives, while on the other hand it generates exposure to living beings and nature, exerting a great variety of interactions with their systems and toxicity. Bisphenol A is a chemical compound massively used as a plasticizer in a varied range of elements for daily use. Propylparaben and triclosan are chemical compounds that extend the half-life and avoid contamination with bacteria and fungi of personal care products. Atrazine and glyphosate, in turn, are molecules used in agriculture, as broad-spectrum herbicides. Although several negative effects have been described in animals and humans, its use in many Latin American countries is still common. Biological models are used throughout the world to determine the acute and chronic toxicity of many chemicals and have been effective in reproducing toxicity mechanisms. C. elegans, is a nematode that facilitates these studies because of its multiple advantages, among which are having a fully sequenced genome, simple maintenance in laboratory conditions, a short life cycle, small size, simple anatomy, transparency and sensitivity for acute and chronic detection of toxicity, as well as an easy understanding of the biochemical mechanisms involved, allowing a more accurate prediction of the toxicity of studied compounds. In addition, a large number of nematodes can be studied in a single experiment within a short period of time, with fewer ethical problems and comparatively cheaper compared to using other animal models. In this study, four stages are contemplated: the first evaluates the toxicity of the five molecules described in the biological model C. elegans taking into account endpoints such as mortality, growth, fertility and progeny size. The second one studies the amount of fatty acid deposits in the bodies of worms; the third was the expression of C. elegans genes related to oxidative stress, by reporter genes associated with green protein fluorescence (GFP) and the fourth one determined the adipogenic action of one of the molecules (BPA) in human adipoblasts cells. The lethality of C. elegans exposed to BPA, PPB and TCS was concentration dependent, and the LC50 after 24 h of exposure was 113.5, 261.7 and 43.2 µM, respectively. At concentrations greater than 0.5 µM, BPA, PPB and TCS caused lethality, with statistical differences related to the control. At lower concentrations, only TCS (0.05 µM) was bioactive. In solutions of BPA, PPB and TCS: body length increased slightly with BPA but did not depend on the concentration. In contrast, PPB reduced body length, whereas TCS did not have an effect on this parameter. The body width increased moderately, without a clear relationship with the concentration, although the response caused by BPA was bimodal. The relationship between body width and body length of the nematodes was moderately increased by exposure to the tested chemicals, but the PPB was the most active, suggesting a probable association with obesity in the C. elegans model. Breeding size of nematodes exposed to BPA, PPB and TCS: the largest brood size after exposure to BPA was reached at 5 µM; then, it decreased in response to higher concentrations. Similarly, the PPB increased brood size to 0.5 µM, with declining effects at higher concentrations. In contrast, TCS decreased this feature following a trend dependent on concentration. The most sensitive genes, in descending order, were sod-4, hsp4, hsp-16.2 and skn-1. These genes increased their expression after exposure to BPA, PPB and TCS, indicating a toxic response related to the generation of reactive oxygen species (ROS). There was no evidence of concentration dependence on these results. In addition, low concentrations caused the overexpression of some genes; for example, BPA at concentrations of 0.05 and 0.5 µM caused a 3-fold expression of hsp-4. However, the high concentrations also affected the expression of several genes such as sod-4, which showed a 5-fold positive regulation after exposure to PPB and TCS at a concentration of 500 µM compared to the control. The chemical compounds BPA, PPB and TCS caused an increase in the accumulation of lipids in the bodies of the exposed nematodes when staining with q-ORO. These deposits showed an increasing tendency related to the concentration. BPA caused a greater accumulation of lipids, followed by PPB and TCS. This result was consistent with the changes in the body wide-long relationship that were recorded in the worms after exposure to these molecules. In this study, four stages were contemplated: the first evaluates the toxicity of the five molecules described in the biological model C. eleganstaking into account endpoints such as mortality, growth, fertility and progeny size. The second one studies the amount of fatty acid deposits in the bodies of nematodes; the third was the expression of the biomodel genes related to oxidative stress, by reporter genes associated with green protein fluorescence (GFP) and the fourth one determined the adipogenic action of one of the molecules (BPA) in human adipoblasts cells. The lethality of C. elegans exposed to BPA, PPB and TCS was concentration dependent, and the LC50 after 24 h of exposure was 113.5, 261.7 and 43.2 µM, respectively. At concentrations greater than 0.5 µM, BPA, PPB and TCS caused lethality, with statistical differences related to the control. At lower concentrations, only TCS (0.05 µM) was bioactive. In solutions of BPA, PPB and TCS: body length increased slightly with BPA but did not depend on the concentration. In contrast, PPB reduced body length, whereas TCS did not have an effect on this parameter. The body width increased moderately, without a clear relationship with the concentration, although the response caused by BPA was bimodal. The relationship between body width and body length of the nematodes was moderately increased by exposure to the tested chemicals, but the PPB was the most active, suggesting a probable association with obesity in the C. elegans model. The most sensitive genes, in descending order, were sod-4, hsp4, hsp-16.2 and skn-1. These genes increased their expression after exposure to BPA, PPB and TCS, indicating a toxic response related to the generation of reactive oxygen species (ROS). There was no evidence of concentration dependence on these results. In addition, low concentrations caused the overexpression of some genes; for example, BPA at concentrations of 0.05 and 0.5 µM caused a 3-fold expression of hsp-4. However, the high concentrations also affected the expression of several genes such as sod-4, which showed a 5-fold positive regulation after exposure to PPB and TCS at concentrations of 500 µM compared to the control. The chemical compounds BPA, PPB and TCS caused an increase in the accumulation of lipids in the bodies of the exposed nematodes when staining with q-ORO, the deposits showed an increasing tendency related to the concentration. BPA caused a greater accumulation of lipids, followed by PPB and TCS. This result was consistent with the changes in the body wide-long relationship that were recorded in the worms after exposure to these molecules. The mean lethal concentration value for atrazine was> 600 µM, and the NOAEL and LOAEL were 0.006 and 0.06 µM, respectively. The lethality percentages for the 0.0006 and 0.006 µM solutions had no significant differences with the control, but concentrations higher than 0.06 µM induced significant lethality, reaching up to 18 % at 600 µM. The BBF decreased to 5 for a 600 µM solution following a concentration-dependent route. The length of the body did not follow a strict pattern dependent on concentration. However, concentrations higher than 60 µM inhibited body growth. In comparison with the control, the inhibition of the size of the brood was greater to a solution of 6 µM, reaching almost 100 %. However, it increased again to 60 and 600 µM, showing a modest U-shaped graph. Mean lethal concentration value for glyphosate was 6.4 µM (the NOAEL and LOAEL were 0.001 and 0.01 µM, respectively). At concentrations greater than 100 µM, total lethality was achieved. The BBF decreased from 38.2 bends in 20 s (control) to 5 at 10 µM, following a concentration-dependent trend. The body length did not register any significant change up to 1 µM, but it statistically decreased at 10 µM. The brood size followed a concentration-dependent curve, with maximum inhibition at 10 µM solution. Glyphosate concentration-response behavior was similar to that elicited by atrazine, the first been more potent. The expression of sod-1, sod-4, and gpx-4 increased at least 2-fold than the control at just 10 µM solution. The lethality for the exposure mixtures of atrazine-glyphosate was concentration-dependent. Maximum lethality occurred with glyphosate 1000 µM + atrazine 600 µM, reaching 80 %. The BBF was inhibited at the lowest tested concentrations. It followed a concentration-dependent tendency similar to that experienced by glyphosate alone. The body length was also affected by the minimum herbicide concentration, but the slope of the concentration-response curve was minimal. In the concentration addition model assay, the lethality of the mixture showed that at low concentrations the effect is additive, whereas at high concentrations the lethality of the mixture was lower than the effect of GBF alone. The gene expression behavior for tested genes of the mixture of atrazine-glyphosate was similar to that observed for individual molecules. In summary, with the obtained results it is demonstrated that the molecules atrazine, glyphosate, bisphenol A, propylparaben and triclosan exert toxicity C. elegans and its endocrine disruption effects are qualitative and quantitatively measurable on the on the biological model.DoctoradoDoctor(a) en Toxicología Ambientalapplication/pdfengUniversidad de CartagenaFacultad de Ciencias FarmacéuticasCartagena de IndiasDoctorado en Toxicología AmbientalDerechos Reservados - Universidad de Cartagena, 2018https://creativecommons.org/licenses/by-nc/4.0/info:eu-repo/semantics/openAccessAtribución-NoComercial 4.0 Internacional (CC BY-NC 4.0)http://purl.org/coar/access_right/c_abf2Toxicological effects of bisphenol A, propyl paraben, triclosan, atrazine and glyphosate using Caenorhabditis elegans as a biological modelTrabajo de grado - Doctoradoinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/resource_type/c_db06Textinfo:eu-repo/semantics/doctoralThesishttps://purl.org/redcol/resource_type/TDhttp://purl.org/coar/version/c_970fb48d4fbd8a85ToxicologyQuímica toxicológicaOrganic compoundsQuímica orgánicaAbarikwu, S.O., Farombi, E.O., 2015. Atrazine induces apoptosis of SH-SY5Y human neuroblastoma cells via the regulation of Bax/Bcl-2 ratio and caspase-3-dependent pathway. Pestic. Biochem. Physiol. 118, 90–98. doi:10.1016/j.pestbp.2014.12.006Abdelhafid, R., Houot, S., Barriuso, E., 2000. How increasing availabilities of carbon and nitrogen affect atrazine behaviour in soils. Biol. Fertil. Soils 30, 333–340. doi:10.1007/s003740050012Acquavella, J.F., Alexander, B.H., Mandel, J.S., Gustin, C., Baker, B., Chapman, P., 2004. Glyphosate biomonitoring for farmers and their families: Results from the farm family exposure study. Environ. Health Perspect. 112, 321–326. doi:10.1289/ehp.6667Adeyemi, J.A., Da Cunha Martins, A., Barbosa, F., 2015. Teratogenicity, genotoxicity and oxidative stress in zebrafish embryos (Danio rerio) coexposed to arsenic and atrazine. Comp. Biochem. Physiol. Part - C Toxicol. Pharmacol. 172–173, 7–12. doi:10.1016/j.cbpc.2015.04.001Agency for Toxic Substances & Disease Registry, 2003. ToxFAQaTM for Atrazine. CAS#: 1912-24-9. (Last update: May 6, 2016). Atlanta.Ait Bali, Y., Ba-Mhamed, S., Bennis, M., 2017. Behavioral and Immunohistochemical Study of the Effects of Subchronic and Chronic Exposure to Glyphosate in Mice. Front. Behav. Neurosci. 11. doi:10.3389/fnbeh.2017.00146Aitbali, Y., Ba-M ’hamed, S., Elhidar, N., Nafis, A., Soraa, N., Bennis, M., 2018. Glyphosate based- herbicide exposure affects gut microbiota, anxiety and depression-like behaviors in mice. Neurotoxicol. Teratol. #pagerange#. doi:10.1016/j.ntt.2018.04.002Alam, M.S., Kurohmaru, M., 2014. Disruption of Sertoli cell vimentin filaments in prepubertal rats: An acute effect of butylparaben in vivo and in vitro. Acta Histochem. 116, 682–687. doi:10.1016/j.acthis.2013.12.006Allgood, O.E., Hamad, A., Fox, J., DeFrank, A., Gilley, R., Dawson, F., Sykes, B., Underwood, T.J., Naylor, R.C., Briggs, A.A., Lassiter, C.S., Bell, W.E., Turner, J.E., 2013. Estrogen prevents cardiac and vascular failure in the “listless” zebrafish (Danio rerio) developmental model. Gen. Comp. Endocrinol. 189, 33–42. doi:10.1016/j.ygcen.2013.04.016Altincicek, B., Fischer, M., Fischer, M., Lüersen, K., Boll, M., Wenzel, U., Vilcinskas, A., 2010. Role of matrix metalloproteinase ZMP-2 in pathogen resistance and development in Caenorhabditis elegans. Dev. Comp. Immunol. 34, 1160–1169. doi:10.1016/j.dci.2010.06.010An, J.H., Blackwell, T.K., 2003. SKN-1 links C. elegans mesendodermal specification to a conserved oxidative stress response. Genes Dev. 17, 1882–1893. doi:10.1101/gad.1107803Anbalagan, C., Lafayette, I., Antoniou-Kourounioti, M., Gutierrez, C., Martin, J.R., Chowdhuri, D.K., De Pomerai, D.I., 2013a. Use of transgenic GFP reporter strains of the nematode Caenorhabditis elegans to investigate the patterns of stress responses induced by pesticides and by organic extracts from agricultural soils. Ecotoxicology 22, 72–85. doi:10.1007/s10646-012-1004-2Anbalagan, C., Lafayette, I., Antoniou-Kourounioti, M., Gutierrez, C., Martin, J.R., Chowdhuri, D.K., De Pomerai, D.I., 2013b. Use of transgenic GFP reporter strains of the nematode Caenorhabditis elegans to investigate the patterns of stress responses induced by pesticides and by organic extracts from agricultural soils. Ecotoxicology 22, 72–85. doi:10.1007/s10646-012-1004-2Andersen, F.A., 2008. Final Amended Report on the Safety Assessment of Methylparaben, Ethylparaben, Propylparaben, Isopropylparaben, Butylparaben, Isobutylparaben, and Benzylparaben as used in Cosmetic Products. Int. J. Toxicol. 27, 1–82. doi:10.1080/10915810802548359Anderson, S.E., Franko, J., Kashon, M.L., Anderson, K.L., Hubbs, A.F., Lukomska, E., Jean Meade, B., 2013. Exposure to triclosan augments the allergic response to ovalbumin in a mouse model of asthma. Toxicol. Sci. 132, 96–106. doi:10.1093/toxsci/kfs328Anderson, S.E., Meade, B.J., Long, C.M., Lukomska, E., Marshall, N.B., 2016. Investigations of immunotoxicity and allergic potential induced by topical application of triclosan in mice. J. Immunotoxicol. 13, 165–172. doi:10.3109/1547691X.2015.1029146Ángeles García, M., Santaeufemia, M., Julia Melgar, M., 2012. Triazine residues in raw milk and infant formulas from Spanish northwest, by a diphasic dialysis extraction. Food Chem. Toxicol. 50, 503–510. doi:10.1016/j.fct.2011.11.019Astiz, M., Alaniz, M.J.T. de, Marra, C.A., 2009. Effect of pesticides on cell survival in liver and brain rat tissues. Ecotoxicol. Environ. Saf. 72, 2025– 2032. doi:10.1016/j.ecoenv.2009.05.001Avila, D.S., Benedetto, A., Au, C., Bornhorst, J., Aschner, M., 2016. Involvement of heat shock proteins on Mn-induced toxicity in Caenorhabditis elegans. BMC Pharmacol. Toxicol. 17, 54. doi:10.1186/s40360-016-0097-2Babić, S., Barišić, J., Bielen, A., Bošnjak, I., Sauerborn Klobučar, R., Ujević, I., Strunjak-Perović, I., Topić Popović, N., Čož-Rakovac, R., 2016. Multilevel ecotoxicity assessment of environmentally relevant bisphenol A concentrations using the soil invertebrate Eisenia fetida. J. Hazard. Mater. 318, 477–486. doi:10.1016/j.jhazmat.2016.07.017PublicationORIGINAL2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdf2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdfapplication/pdf4725445https://dspace7-unicartagena.metabuscador.org/bitstreams/acac8f80-47de-4605-bb44-dd6c6cfd1145/downloadf8ce5e2c01522a08117b277079d3d54aMD51Formato autorización Repositorio Institucional_MCGE.pdfFormato autorización Repositorio Institucional_MCGE.pdfapplication/pdf834287https://dspace7-unicartagena.metabuscador.org/bitstreams/6fbdab12-9055-4b34-9503-b6d92a6d13fe/downloada625cfb7dc652a473eceb45f55cd192fMD52LICENSElicense.txtlicense.txttext/plain; charset=utf-81756https://dspace7-unicartagena.metabuscador.org/bitstreams/29b4aef8-589d-458e-8080-641b23816e01/download7b38fcee9ba3bc8639fa56f350c81be3MD53TEXT2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdf.txt2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdf.txtExtracted texttext/plain281909https://dspace7-unicartagena.metabuscador.org/bitstreams/3cb6a140-a36d-4187-976a-0c5febca77f1/download2f650129c14dfce33e66c6fdf83a0b8aMD54Formato autorización Repositorio Institucional_MCGE.pdf.txtFormato autorización Repositorio Institucional_MCGE.pdf.txtExtracted texttext/plain1https://dspace7-unicartagena.metabuscador.org/bitstreams/defe5ae0-3178-4658-9d73-ae8f92e9798f/download68b329da9893e34099c7d8ad5cb9c940MD56THUMBNAIL2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdf.jpg2018_TESIS DE GRADO_MARIA CECILIA GARCIA ESPIÑEIRA.pdf.jpgGenerated Thumbnailimage/jpeg8347https://dspace7-unicartagena.metabuscador.org/bitstreams/29e92885-8aed-4dfe-beb5-fbbdf345a0f9/download30bbd007e8fcb461cd9522e64b70108bMD55Formato autorización Repositorio Institucional_MCGE.pdf.jpgFormato autorización Repositorio Institucional_MCGE.pdf.jpgGenerated Thumbnailimage/jpeg18365https://dspace7-unicartagena.metabuscador.org/bitstreams/0b9ee316-2523-4e18-b12e-4804fba4cba0/download1f5966a7b703f7256f25214d309f487cMD5711227/16530oai:dspace7-unicartagena.metabuscador.org:11227/165302024-08-28 17:53:40.931https://creativecommons.org/licenses/by-nc/4.0/Derechos Reservados - Universidad de Cartagena, 2018open.accesshttps://dspace7-unicartagena.metabuscador.orgBiblioteca Digital Universidad de Cartagenabdigital@metabiblioteca.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 |