Your search keyword '"vom Saal, Frederick S."' showing total 7 results

1. Correction to: Parma consensus statement on metabolic disruptors

Author

Heindel, Jerrold J., vom Saal, Frederick S., Blumberg, Bruce, Bovolin, Patrizia, Calamandrei, Gemma, Ceresini, Graziano, Cohn, Barbara A., Fabbri, Elena, Gioiosa, Laura, Kassotis, Christopher, Legler, Juliette, La Merrill, Michele, Rizzi, Laura, Machtinger, Ronit, Mantovani, Alberto, Mendez, Michelle A., Montanini, Luisa, Molteni, Laura, Nagel, Susan C., Parmigiani, Stefano, Panzica, Giancarlo, Paterlini, Silvia, Pomatto, Valentina, Ruzzin, Jérôme, Sartor, Giorgio, Schug, Thaddeus T., Street, Maria E., Suvorov, Alexander, Volpi, Riccardo, Zoeller, R. Thomas, and Palanza, Paola

Published

2017

2. Parma consensus statement on metabolic disruptors

Author

Heindel, Jerrold J., vom Saal, Frederick S., Blumberg, Bruce, Bovolin, Patrizia, Calamandrei, Gemma, Ceresini, Graziano, Cohn, Barbara A., Fabbri, Elena, Gioiosa, Laura, Kassotis, Christopher, Legler, Juliette, La Merrill, Michele, Rizzir, Laura, Machtinger, Ronit, Mantovani, Alberto, Mendez, Michelle A., Montanini, Luisa, Molteni, Laura, Nagel, Susan C., Parmigiani, Stefano, Panzica, Giancarlo, Paterlini, Silvia, Pomatto, Valentina, Ruzzin, Jérôme, Sartor, Giorgio, Schug, Thaddeus T., Street, Maria E., Suvorov, Alexander, Volpi, Riccardo, Zoeller, R. Thomas, and Palanza, Paola

Published

2015

3. Concerns over use of glyphosate-based herbicides and risks associated with exposures: a consensus statement.

Author

Myers, John Peterson, Antoniou, Michael N., Blumberg, Bruce, Carroll, Lynn, Colborn, Theo, Everett, Lorne G., Hansen, Michael, Landrigan, Philip J., Lanphear, Bruce P., Mesnage, Robin, Vandenberg, Laura N., vom Saal, Frederick S., Welshons, Wade V., and Benbrook, Charles M.

Subjects

HERBICIDE toxicology research, HERBICIDES & the environment, GLYPHOSATE -- Environmental aspects, HERBICIDE-resistant crops, TRANSGENIC plants, CARCINOGENS, CONSENSUS (Social sciences), GLYCINE, HERBICIDES, MEDICAL protocols, POLLUTANTS, RESEARCH funding, RISK assessment, TOXICITY testing, STANDARDS

Abstract

The broad-spectrum herbicide glyphosate (common trade name "Roundup") was first sold to farmers in 1974. Since the late 1970s, the volume of glyphosate-based herbicides (GBHs) applied has increased approximately 100-fold. Further increases in the volume applied are likely due to more and higher rates of application in response to the widespread emergence of glyphosate-resistant weeds and new, pre-harvest, dessicant use patterns. GBHs were developed to replace or reduce reliance on herbicides causing well-documented problems associated with drift and crop damage, slipping efficacy, and human health risks. Initial industry toxicity testing suggested that GBHs posed relatively low risks to non-target species, including mammals, leading regulatory authorities worldwide to set high acceptable exposure limits. To accommodate changes in GBH use patterns associated with genetically engineered, herbicide-tolerant crops, regulators have dramatically increased tolerance levels in maize, oilseed (soybeans and canola), and alfalfa crops and related livestock feeds. Animal and epidemiology studies published in the last decade, however, point to the need for a fresh look at glyphosate toxicity. Furthermore, the World Health Organization's International Agency for Research on Cancer recently concluded that glyphosate is "probably carcinogenic to humans." In response to changing GBH use patterns and advances in scientific understanding of their potential hazards, we have produced a Statement of Concern drawing on emerging science relevant to the safety of GBHs. Our Statement of Concern considers current published literature describing GBH uses, mechanisms of action, toxicity in laboratory animals, and epidemiological studies. It also examines the derivation of current human safety standards. We conclude that: (1) GBHs are the most heavily applied herbicide in the world and usage continues to rise; (2) Worldwide, GBHs often contaminate drinking water sources, precipitation, and air, especially in agricultural regions; (3) The half-life of glyphosate in water and soil is longer than previously recognized; (4) Glyphosate and its metabolites are widely present in the global soybean supply; (5) Human exposures to GBHs are rising; (6) Glyphosate is now authoritatively classified as a probable human carcinogen; (7) Regulatory estimates of tolerable daily intakes for glyphosate in the United States and European Union are based on outdated science. We offer a series of recommendations related to the need for new investments in epidemiological studies, biomonitoring, and toxicology studies that draw on the principles of endocrinology to determine whether the effects of GBHs are due to endocrine disrupting activities. We suggest that common commercial formulations of GBHs should be prioritized for inclusion in government-led toxicology testing programs such as the U.S. National Toxicology Program, as well as for biomonitoring as conducted by the U.S. Centers for Disease Control and Prevention. [ABSTRACT FROM AUTHOR]

Published

2016

4. Should oral gavage be abandoned in toxicity testing of endocrine disruptors?

Author

Vandenberg, Laura N., Welshons, Wade V., vom Saal, Frederick S., Toutain, Pierre-Louis, and Peterson Myers, John

Abstract

For decades, hazard assessments for environmental chemicals have used intra-gastric gavage to assess the effects of ‘oral’ exposures. It is now widely used--and in some cases required--by US federal agencies to assess potential toxicity of endocrine disrupting chemicals (EDCs). In this review we enumerate several reasons why gavage is not appropriate for the assessment of EDCs using bisphenol A (BPA) as a main example. First, whereas human dietary exposures interact with the oral mucosa, gavage exposures avoid these interactions, leading to dramatic differences in absorption, bioavailability and metabolism with implications for toxicokinetic assumptions and models. Additionally, there are well acknowledged complications associated with gavage, such as perforation of the esophagus that diminish its value in toxicological experiments. Finally, the gavage protocol itself can induce stress responses by the endocrine system and confound the assessment of EDCs. These serious flaws have not been taken into account in interpreting results of EDC research. We propose the exploration of alternatives to mimic human exposures when there are multiple exposure routes/sources and when exposures are chronic. We conclude that gavage may be preferred over other routes for some environmental chemicals in some circumstances, but it does not appropriately model human dietary exposures for many chemicals. Because it avoids exposure pathways, is stressful, and thus interferes with endocrine responses, gavage should be abandoned as the default route of administration for hazard assessments of EDCs. [ABSTRACT FROM AUTHOR]

Published

2014

5. A round robin approach to the analysis of bisphenol a (BPA) in human blood samples.

Author

Vandenberg, Laura N., Gerona, Roy R., Kannan, Kurunthachalam, Taylor, Julia A., van Breemen, Richard B., Dickenson, Carrie A., Chunyang Liao, Yang Yuan, Newbold, Retha R., Padmanabhan, Vasantha, vom Saal, Frederick S., and Woodruff, Tracey J.

Abstract

Background: Human exposure to bisphenol A (BPA) is ubiquitous, yet there are concerns about whether BPA can be measured in human blood. This Round Robin was designed to address this concern through three goals: 1) to identify collection materials, reagents and detection apparatuses that do not contribute BPA to serum; 2) to identify sensitive and precise methods to accurately measure unconjugated BPA (uBPA) and BPA-glucuronide (BPA-G), a metabolite, in serum; and 3) to evaluate whether inadvertent hydrolysis of BPA-G occurs during sample handling and processing. Methods: Four laboratories participated in this Round Robin. Laboratories screened materials to identify BPA contamination in collection and analysis materials. Serum was spiked with concentrations of uBPA and/or BPA-G ranging from 0.09-19.5 (uBPA) and 0.5-32 (BPA-G) ng/mL. Additional samples were preserved unspiked as ‘environmental’ samples. Blinded samples were provided to laboratories that used LC/MSMS to simultaneously quantify uBPA and BPA-G. To determine whether inadvertent hydrolysis of BPA metabolites occurred, samples spiked with only BPA-G were analyzed for the presence of uBPA. Finally, three laboratories compared direct and indirect methods of quantifying BPA-G. Results: We identified collection materials and reagents that did not introduce BPA contamination. In the blinded spiked sample analysis, all laboratories were able to distinguish low from high values of uBPA and BPA-G, for the whole spiked sample range and for those samples spiked with the three lowest concentrations (0.5-3.1 ng/ml). By completion of the Round Robin, three laboratories had verified methods for the analysis of uBPA and two verified for the analysis of BPA-G (verification determined by: 4 of 5 samples within 20% of spiked concentrations). In the analysis of BPA-G only spiked samples, all laboratories reported BPA-G was the majority of BPA detected (92.2--100%). Finally, laboratories were more likely to be verified using direct methods than indirect ones using enzymatic hydrolysis. Conclusions: Sensitive and accurate methods for the direct quantification of uBPA and BPA-G were developed in multiple laboratories and can be used for the analysis of human serum samples. BPA contamination can be controlled during sample collection and inadvertent hydrolysis of BPA conjugates can be avoided during sample handling. [ABSTRACT FROM AUTHOR]

Published

2014

6. Concerns over use of glyphosate-based herbicides and risks associated with exposures: a consensus statement

Author

Myers, John P, Antoniou, Michael N, Blumberg, Bruce, Carroll, Lynn, Colborn, Theo, Everett, Lorne G, Hansen, Michael, Landrigan, Philip J, Lanphear, Bruce P, Mesnage, Robin, Vandenberg, Laura N, Vom Saal, Frederick S, Welshons, Wade V, and Benbrook, Charles M

Subjects

2. Zero hunger, 13. Climate action, 3. Good health

Abstract

The broad-spectrum herbicide glyphosate (common trade name “Roundup”) was first sold to farmers in 1974. Since the late 1970s, the volume of glyphosate-based herbicides (GBHs) applied has increased approximately 100-fold. Further increases in the volume applied are likely due to more and higher rates of application in response to the widespread emergence of glyphosate-resistant weeds and new, pre-harvest, dessicant use patterns. GBHs were developed to replace or reduce reliance on herbicides causing well-documented problems associated with drift and crop damage, slipping efficacy, and human health risks. Initial industry toxicity testing suggested that GBHs posed relatively low risks to non-target species, including mammals, leading regulatory authorities worldwide to set high acceptable exposure limits. To accommodate changes in GBH use patterns associated with genetically engineered, herbicide-tolerant crops, regulators have dramatically increased tolerance levels in maize, oilseed (soybeans and canola), and alfalfa crops and related livestock feeds. Animal and epidemiology studies published in the last decade, however, point to the need for a fresh look at glyphosate toxicity. Furthermore, the World Health Organization’s International Agency for Research on Cancer recently concluded that glyphosate is “probably carcinogenic to humans.” In response to changing GBH use patterns and advances in scientific understanding of their potential hazards, we have produced a Statement of Concern drawing on emerging science relevant to the safety of GBHs. Our Statement of Concern considers current published literature describing GBH uses, mechanisms of action, toxicity in laboratory animals, and epidemiological studies. It also examines the derivation of current human safety standards. We conclude that: (1) GBHs are the most heavily applied herbicide in the world and usage continues to rise; (2) Worldwide, GBHs often contaminate drinking water sources, precipitation, and air, especially in agricultural regions; (3) The half-life of glyphosate in water and soil is longer than previously recognized; (4) Glyphosate and its metabolites are widely present in the global soybean supply; (5) Human exposures to GBHs are rising; (6) Glyphosate is now authoritatively classified as a probable human carcinogen; (7) Regulatory estimates of tolerable daily intakes for glyphosate in the United States and European Union are based on outdated science. We offer a series of recommendations related to the need for new investments in epidemiological studies, biomonitoring, and toxicology studies that draw on the principles of endocrinology to determine whether the effects of GBHs are due to endocrine disrupting activities. We suggest that common commercial formulations of GBHs should be prioritized for inclusion in government-led toxicology testing programs such as the U.S. National Toxicology Program, as well as for biomonitoring as conducted by the U.S. Centers for Disease Control and Prevention.

7. Erratum to: A round robin approach to the analysis of bisphenol a (BPA) in human blood samples.

Author

Vandenberg, Laura N, Gerona, Roy R, Kannan, Kurunthachalam, Taylor, Julia A, van Breemen, Richard B, Dickenson, Carrie A, Liao, Chunyang, Yuan, Yang, Newbold, Retha R, Padmanabhan, Vasantha, Vom Saal, Frederick S, and Woodruff, Tracey J

Subjects

BLOOD testing, BISPHENOL A, PHYSIOLOGICAL effects of chemicals

Abstract

A correction to the article "A Round Robin Approach to the Analysis of Bisphenol A (BPA) in Human Blood Samples" that was published in the 2014 issue is presented.

Published

2016