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Papers by Abby li

NeuroToxicology, 2012

A change in paradigm is needed in the prevention of toxic effects on the nervous system, moving f... more A change in paradigm is needed in the prevention of toxic effects on the nervous system, moving from its the present reliance solely on data from animal testing to a prediction model mostly based on in vitro toxicity testing and in silico modelling. According to the report published by the National Research Council (NRC) of the US National Academies of Science, high-throughput in vitro tests will provide evidence for alterations in "toxicity pathways" as the best possible method of large scale toxicity prediction. The challenges to implement this proposal are enormous, and provide much room for debate. While many efforts address the technical aspects of implementing the vision, many questions around it need also to be addressed. Is the overall strategy the only one to be pursued? How can we move from current to future paradigms? Will we ever be able to reliably model for chronic and developmental neurotoxicity in vitro?. This paper summarizes four presentations from a symposium held at the International Neurotoxicology Conference held in Xi'an, China, in June 2011. A. Li reviewed the current guidelines for neurotoxicity and developmental neurotoxicity testing, and discussed the major challenges existing to realize the NCR vision for toxicity testing. J. Llorens reviewed the biology of mammalian toxic avoidance in view of present knowledge on the physiology and molecular biology of the chemical senses, taste and smell. This background information supports the hypothesis that relating in vivo toxicity to chemical epitope descriptors that mimic the chemical encoding performed by the olfactory system may provide a way to the long term future of complete in silico toxicity prediction. S. Ceccatelli reviewed the implementation of rodent and human neural stem cells (NSCs) as models for in vitro toxicity testing that measures parameters such as cell proliferation, differentiation and migration. These appear to be sensitive endpoints that can identify substances with developmental neurotoxic potential. C. Suñol reviewed the use of primary neuronal cultures in testing for neurotoxicity of environmental pollutants, including the study of the effects of persistent exposures and/or in differentiating cells, which allow recording of effects that can be extrapolated to human developmental neurotoxicity.

Regulatory Toxicology and Pharmacology, 2014

Tertiary-butyl acetate (TBAC) was tested for subchronic toxicity in rats and mice and reproductiv... more Tertiary-butyl acetate (TBAC) was tested for subchronic toxicity in rats and mice and reproductive toxicity in rats at inhalation concentrations of 0, 100, 400 or 1600 ppm. An oral maternal toxicity study was conducted in rats at dose levels of 0, 400, 800, 1000 and 1600 mg kg À1 d À1. In the inhalation studies, hematology, clinical chemistry, urinalysis, gross pathology and the majority of body weight and feed consumption values were unaffected. Exposure to TBAC at concentrations of 400 ppm and higher caused transient hyperactivity in mice and some evidence of increased motor activity counts in male rats at the 1600 ppm exposure level. TBAC caused a 2 u-globulin accumulation in male rat kidneys from all exposure groups and increased liver weights in 1600 ppm rats and mice. Levels of thyroxin were decreased in male mice exposed to 1600 ppm TBAC for 4 weeks but otherwise thyroid endpoints were unaffected in rats and mice at either the 4 or 13 weeks time points. There was no evidence or immunotoxicity or reproductive toxicity in rats. Pregnant rats receiving 1000 mg kg À1 d À1 TBAC exhibited severe signs of acute neurotoxicity and decreased feed consumption and body weight gain. Fetal viability and growth were unaffected.

Inhalation Toxicology, 2012

An acute, whole-body inhalation study for allyl alcohol in Sprague-Dawley rats was designed to su... more An acute, whole-body inhalation study for allyl alcohol in Sprague-Dawley rats was designed to support derivation of AEGL values, with emphasis on establishing NOAELs for irreversible effects of different exposure concentrations and durations. Groups of 10 rats were exposed for 1 hour (0, 50, 200, or 400 ppm), 4 hours (0, 20, 50, or 100 ppm), or 8 hours (0, 10, 20, or 50 ppm). Clinical evaluations were performed during exposure and in an open field within 22−71 minutes after termination of exposure. Clinical pathology, gross necropsy, and histopathology (nasal tissues, larynx, trachea, lungs/bronchi, liver, and kidneys) were evaluated 14 days after exposure. Mortality was limited to 1 male exposed for 8 hours to 50 ppm. Clinical findings of gasping, rales, increased respiration noted at higher exposure levels were rapidly reversed. No treatment-related findings were observed in the liver and kidneys, or in the lungs of surviving animals. Histopathology in the nasal cavity was noted at all exposure levels following 1, 4, or 8 hours of exposure. Mild nasal inflammation was found at the lowest exposure levels (50-ppm/1-hour, 20-ppm/4-hour, and 10-ppm/8-hour). These effects were considered reversible and were not associated with related clinical signs. Severe, irreversible nasal olfactory epithelial lesions were present in 50 ppm/8-hour males. The NOELs for irreversible effects were 400-ppm/1-hour, 100-ppm/4-hour, and 20-ppm/8-hour. The incidence of severe findings was positively dependent on both concentration and the exposure duration. In contrast, the incidence of mild reversible findings did not appear to be dependent on duration.

NeuroToxicology, 2012

A change in paradigm is needed in the prevention of toxic effects on the nervous system, moving f... more A change in paradigm is needed in the prevention of toxic effects on the nervous system, moving from its the present reliance solely on data from animal testing to a prediction model mostly based on in vitro toxicity testing and in silico modelling. According to the report published by the National Research Council (NRC) of the US National Academies of Science, high-throughput in vitro tests will provide evidence for alterations in "toxicity pathways" as the best possible method of large scale toxicity prediction. The challenges to implement this proposal are enormous, and provide much room for debate. While many efforts address the technical aspects of implementing the vision, many questions around it need also to be addressed. Is the overall strategy the only one to be pursued? How can we move from current to future paradigms? Will we ever be able to reliably model for chronic and developmental neurotoxicity in vitro?. This paper summarizes four presentations from a symposium held at the International Neurotoxicology Conference held in Xi'an, China, in June 2011. A. Li reviewed the current guidelines for neurotoxicity and developmental neurotoxicity testing, and discussed the major challenges existing to realize the NCR vision for toxicity testing. J. Llorens reviewed the biology of mammalian toxic avoidance in view of present knowledge on the physiology and molecular biology of the chemical senses, taste and smell. This background information supports the hypothesis that relating in vivo toxicity to chemical epitope descriptors that mimic the chemical encoding performed by the olfactory system may provide a way to the long term future of complete in silico toxicity prediction. S. Ceccatelli reviewed the implementation of rodent and human neural stem cells (NSCs) as models for in vitro toxicity testing that measures parameters such as cell proliferation, differentiation and migration. These appear to be sensitive endpoints that can identify substances with developmental neurotoxic potential. C. Suñol reviewed the use of primary neuronal cultures in testing for neurotoxicity of environmental pollutants, including the study of the effects of persistent exposures and/or in differentiating cells, which allow recording of effects that can be extrapolated to human developmental neurotoxicity.

Regulatory Toxicology and Pharmacology, 2014

Tertiary-butyl acetate (TBAC) was tested for subchronic toxicity in rats and mice and reproductiv... more Tertiary-butyl acetate (TBAC) was tested for subchronic toxicity in rats and mice and reproductive toxicity in rats at inhalation concentrations of 0, 100, 400 or 1600 ppm. An oral maternal toxicity study was conducted in rats at dose levels of 0, 400, 800, 1000 and 1600 mg kg À1 d À1. In the inhalation studies, hematology, clinical chemistry, urinalysis, gross pathology and the majority of body weight and feed consumption values were unaffected. Exposure to TBAC at concentrations of 400 ppm and higher caused transient hyperactivity in mice and some evidence of increased motor activity counts in male rats at the 1600 ppm exposure level. TBAC caused a 2 u-globulin accumulation in male rat kidneys from all exposure groups and increased liver weights in 1600 ppm rats and mice. Levels of thyroxin were decreased in male mice exposed to 1600 ppm TBAC for 4 weeks but otherwise thyroid endpoints were unaffected in rats and mice at either the 4 or 13 weeks time points. There was no evidence or immunotoxicity or reproductive toxicity in rats. Pregnant rats receiving 1000 mg kg À1 d À1 TBAC exhibited severe signs of acute neurotoxicity and decreased feed consumption and body weight gain. Fetal viability and growth were unaffected.

Inhalation Toxicology, 2012

An acute, whole-body inhalation study for allyl alcohol in Sprague-Dawley rats was designed to su... more An acute, whole-body inhalation study for allyl alcohol in Sprague-Dawley rats was designed to support derivation of AEGL values, with emphasis on establishing NOAELs for irreversible effects of different exposure concentrations and durations. Groups of 10 rats were exposed for 1 hour (0, 50, 200, or 400 ppm), 4 hours (0, 20, 50, or 100 ppm), or 8 hours (0, 10, 20, or 50 ppm). Clinical evaluations were performed during exposure and in an open field within 22−71 minutes after termination of exposure. Clinical pathology, gross necropsy, and histopathology (nasal tissues, larynx, trachea, lungs/bronchi, liver, and kidneys) were evaluated 14 days after exposure. Mortality was limited to 1 male exposed for 8 hours to 50 ppm. Clinical findings of gasping, rales, increased respiration noted at higher exposure levels were rapidly reversed. No treatment-related findings were observed in the liver and kidneys, or in the lungs of surviving animals. Histopathology in the nasal cavity was noted at all exposure levels following 1, 4, or 8 hours of exposure. Mild nasal inflammation was found at the lowest exposure levels (50-ppm/1-hour, 20-ppm/4-hour, and 10-ppm/8-hour). These effects were considered reversible and were not associated with related clinical signs. Severe, irreversible nasal olfactory epithelial lesions were present in 50 ppm/8-hour males. The NOELs for irreversible effects were 400-ppm/1-hour, 100-ppm/4-hour, and 20-ppm/8-hour. The incidence of severe findings was positively dependent on both concentration and the exposure duration. In contrast, the incidence of mild reversible findings did not appear to be dependent on duration.