Investigation of the Effects of Metallic Nanoparticles on Fertility Outcomes and Endocrine Modification of the Hypothalamic-Pituitary-Gonadal Axis.

Nanotechnology is a very disruptive twenty-first-century revolution that will allow social and economic welfare to increase although it also involves a significant human exposure to nanoparticles. The aim of the present study was to contribute to the elucidation on whether metallic nanoparticles have a potential to induce fertility impairments. Regulatory studies that observed official OECD guidelines 415, 416 and 422 have failed to detect any fertility alterations caused by nanoparticle exposure. However, the scientific literature provides evidence that some nanoparticles may cause gonad impairments although the actual impact on fertility remains uncertain. This aim of the present study is to revisit the previously published RNAseq studies by analyzing the effects of several nanoparticles on the transcriptome of T98G human glioblastoma cells given that glial cells are known to play a pivotal role in the regulation of gonadotropin releasing hormone neurons. We found evidence that nanoparticles impair the gonadotropin releasing hormone receptor pathway and several related biological process like, among others, the cellular response to follicular stimulating hormone, cellular response to gonadotropin stimulus, cellular response to hormone stimulus, response to steroid hormone, ovulation cycle and response to estradiol. We propose that nanoparticles interfere with the ability of glial cells to regulate gonadotropin-releasing hormone neurons and, subsequently, the hypothalamic-pituitary-gonadal axis, potentially leading to fertility impairments. To our knowledge, this is the first proposal of a mode of action based on endocrine disruption for explaining the possible effects of nanoparticles on fertility. Whether these finding can be extended to other types of nanoparticles requires further investigation.

Reference Values on Children's Hair for 28 Elements (Heavy Metals and Essential Elements) Based on a Pilot Study in a Representative Non-Contaminated Local Area.

Studies have been published, and laboratories offer services of measuring elements in hair as biomarkers of environmental exposure and/or control of essential elements (trace or macro). These reported values can have only sense if compared with adopted reference values. In this work, we propose provisional reference values based on a pilot child population. The concentrations of 28 elements were measured in children's hair samples. An observational, descriptive, cross-sectional study was conducted in a typical child population in the Mediterranean region void of excessive pollution problems to analyze 419 hair samples of children aged 3-12 years. Children were selected by a simple random method from eight primary education schools in different municipal districts, which included urban, rural and industrial areas. Samples of around 100 mg were washed and acid digested by an optimized procedure. All measures were performed using ICP-MS with Sc, Y and Re as internal standards. The statistical analysis was performed by two approaches: (a) considering all the data and (b) without outliers (second-order atypical data) to compare them with other published studies. The distribution curves in all the elements studied were asymmetric and did not fit the theoretical normality distributions. Therefore, the analysis based on percentiles was more appropriate. In most elements, only slight differences were observed with sex or age, which did not justify proposing separate reference ranges. From the results of this study, provisional reference values are proposed following two criteria: (a) simple application of the table of percentiles built by removing outlier values and (b) values after a detailed analysis case-by-case, considering other data as the distribution profile and other published data of each element. Although the pilot sample was from a limited area, it was carefully selected to be representative of a general non-contaminated population. With this limitation, the proposed reference values might be useful for researchers and physicians until a wider geographical study is available for a large number of elements.

Case study: risk associated to wearing silver or graphene nanoparticle-coated facemasks for protection against COVID-19.

The world is living a pandemic situation derived from the worldwide spreading of SARS-CoV-2 virus causing COVID-19. Facemasks have proven to be one of the most effective prophylactic measures to avoid the infection that has made that wearing of facemasks has become mandatory in most of the developed countries. Silver and graphene nanoparticles have proven to have antimicrobial properties and are used as coating of these facemasks to increase the effectivity of the textile fibres. In the case of silver nanoparticles, we have estimated that in a real scenario the systemic (internal) exposure derived from wearing these silver nanoparticle facemasks would be between 7.0 × 10-5 and 2.8 × 10-4 mg/kg bw/day. In addition, we estimated conservative systemic no effect levels between 0.075 and 0.01 mg/kg bw/day. Therefore, we estimate that the chronic exposure to silver nanoparticles derived form facemasks wearing is safe. In the case of graphene, we detected important gaps in the database, especially regarding toxicokinetics, which prevents the derivation of a systemic no effect level. Nevertheless, the qualitative approach suggests that the risk of dermal repeated exposure to graphene is very low, or even negligible. We estimated that for both nanomaterials, the risk of skin sensitisation and genotoxicity is also negligible.

A Transcriptomic Analysis of T98G Human Glioblastoma Cells after Exposure to Cadmium-Selenium Quantum Dots Mainly Reveals Alterations in Neuroinflammation Processes and Hypothalamus Regulation.

Quantum dots are nanoparticles with very promising biomedical applications. However, before these applications can be authorized, a complete toxicological assessment of quantum dots toxicity is needed. This work studied the effects of cadmium-selenium quantum dots on the transcriptome of T98G human glioblastoma cells. It was found that 72-h exposure to 40 µg/mL (a dose that reduces cell viability by less than 10%) alters the transcriptome of these cells in biological processes and molecular pathways, which address mainly neuroinflammation and hormonal control of hypothalamus via the gonadotropin-releasing hormone receptor. The biological significance of neuroinflammation alterations is still to be determined because, unlike studies performed with other nanomaterials, the expression of the genes encoding pro-inflammatory interleukins is down-regulated rather than up-regulated. The hormonal control alterations of the hypothalamus pose a new concern about a potential adverse effect of quantum dots on fertility. In any case, more studies are needed to clarify the biological relevance of these findings, and especially to assess the real risk of toxicity derived from quantum dots exposure appearing in physiologically relevant scenarios.

Titanium Dioxide, but Not Zinc Oxide, Nanoparticles Cause Severe Transcriptomic Alterations in T98G Human Glioblastoma Cells.

Titanium dioxide and zinc oxide are two of the most widely used nanomaterials. We assessed the effects of noncytotoxic doses of both nanomaterials on T98G human glioblastoma cells by omic approaches. Surprisingly, no effects on the transcriptome of T98G cells was detected after exposure to 5 µg/mL of zinc oxide nanoparticles during 72 h. Conversely, the transcriptome of the cells exposed to 20 µg/mL of titanium dioxide nanoparticles during 72 h revealed alterations in lots of biological processes and molecular pathways. Alterations to the transcriptome suggests that exposure to titanium dioxide nanoparticles might, potentially, compromise the integrity of the blood brain barrier integrity and cause neuroinflammation. The latter issue was further confirmed phenotypically with a proteomic analysis and by recording the release of interleukin 8. Titanium dioxide also caused autophagy, which was demonstrated through the increase in the expression of the autophagy-related 3 and microtubule associated protein 1 light chain 3 alpha genes. The proteomic analysis revealed that titanium dioxide nanoparticles might have anticancerigen properties by downregulating genes involved in the detoxication of anthracyclines. A risk assessment resulting from titanium dioxide exposure, focusing on the central nervous system as a potential target of toxicity, is necessary.

Effects of silver nanoparticles on T98G human glioblastoma cells.

Nanotechnology has been well developed in recent decades because it provides social progress and welfare. Consequently, exposure of population is increasing and further increases in the near future are forecasted. Therefore, assessing the safety of applications involving nanoparticles is strongly advisable. We assessed the effects of silver nanoparticles at a non-cytotoxic concentration on the performance of T98G human glioblastoma cells mainly by an omic approach. We found that silver nanoparticles are able to alter several molecular pathways related to inflammation. Cellular repair and regeneration were also affected by alterations to the fibroblast growth factor pathways operating mainly via mitogen-activated protein kinase cascades. It was concluded that, given the relevant role of glia on central nervous system maintenance homeostasis, exposure to silver nanoparticles could eventually lead to severe toxicity in the central nervous system, although current exposure levels do not pose a significant risk.

Case study: Is bisphenol S safer than bisphenol A in thermal papers?

The Risk Assessment Committee of the European Chemical Agency released a scientific opinion alerting that the risk associated with dermal occupational exposure to bisphenol A (BPA) via thermal paper might not be adequately controlled because the estimated exposure was around twice the Derived No Effect Level (DNEL) and the European Commission will effectively restrict BPA in thermal paper as soon as 2020. Bisphenol S (BPS) is currently being used as a BPA surrogate and is already widespread in thermal paper receipts. Based on publically available information in the scientific literature, we assessed the risk associated with dermal BPS exposure via thermal paper for the general and occupational populations to compare with BPA situation. We developed two exposure scenarios; one based on the total excreted BPS and another on exposure estimations by transferring BPS from the thermal paper matrix to skin. Both scenarios yielded similar exposures for the general population (0.016-0.013 µg/kg bw/day), but the exposure estimated for the workers in the second scenario (0.96 µg/kg bw/day) was around 17-fold higher than that estimated for the workers in the first scenario. The systemic DNELs for the general and workers populations were 0.45 and 0.91 µg BPS/kg bw/day, respectively, which were 4.6- and 19-fold higher than the respective dermal DNELs. Risk Characterisation Ratio (RCR) (estimated exposure through urinary excretion compared with the systemic DNEL) in the first and most reliable scenario suggested that the risk was adequately controlled. In the second scenario, however, the RCR suggests that the risk might not be adequately controlled for both the general population and workers. This work raises the necessity of generate more toxicodynamic and toxicokinetic information, specially using dermal exposures, to properly assess the risk associated to dermal BPS exposure because the situation might presumably get worse after 2020.

Interactions of human butyrylcholinesterase with phenylvalerate and acetylthiocholine as substrates and inhibitors: kinetic and molecular modeling approaches.

Phenyl valerate (PV) is a substrate for measuring the PVase activity of neuropathy target esterase (NTE), a key molecular event of organophosphorus-induced delayed neuropathy. A protein with PVase activity in chicken (model for delayed neurotoxicity) was identified as butyrylcholinesterase (BChE). Purified human butyrylcholinesterase (hBChE) showed PVase activity with a similar sensitivity to inhibitors as its cholinesterase (ChE) activity. Further kinetic and theoretical molecular simulation studies were performed. The kinetics did not fit classic competition models among substrates. Partially mixed inhibition was the best-fitting model to acetylthiocholine (AtCh) interacting with PVase activity. ChE activity showed substrate activation, and non-competitive inhibition was the best-fitting model to PV interacting with the non-activated enzyme and partial non-competitive inhibition was the best fitted model for PV interacting with the activated enzyme by excess of AtCh. The kinetic results suggest that other sites could be involved in those activities. From the theoretical docking analysis, we deduced other more favorable sites for binding PV related with Asn289 residue, situated far from the catalytic site ("PV-site"). Both substrates acethylcholine (ACh) and PV presented similar docking values in both the PV-site and catalytic site pockets, which explained some of the observed substrate interactions. Molecular dynamic simulations based on the theoretical structure of crystallized hBChE were performed. Molecular modeling studies suggested that PV has a higher potential for non-competitive inhibition, being also able to inhibit the hydrolysis of ACh through interactions with the PV-site. Further theoretical studies also suggested that PV could yet be able to promote competitive inhibition. We concluded that the kinetic and theoretical studies did not fit the simple classic competition among substrates, but were compatible with the interaction with two different binding sites.

Phenyl valerate esterase activity of human butyrylcholinesterase.

Phenyl valerate is used for detecting and measuring neuropathy target esterase (NTE) and has been used for discriminating esterases as potential target in hen model of organophosphorus delayed neuropathy. In previous studies we observed that phenyl valerate esterase (PVase) activity of an enzymatic fraction in chicken brain might be due to a butyrylcholinesterase protein (BuChE), and it was suggested that this enzymatic fraction could be related to the potentiation/promotion phenomenon of the organophosphate-induced delayed neuropathy (OPIDN). In this work, PVase activity of purified human butyrylcholinesterase (hBuChE) is demonstrated and confirms the novel observation that a relationship of BuChE with PVase activities is also relevant for humans, as is, therefore the potential role in toxicity for humans. The KM and catalytic constant (kcat) were estimated as 0.52/0.72 µM and 45,900/49,200 min-1 respectively. Furthermore, this work studies the inhibition by preincubation of PVase and cholinesterase activities of hBuChE with irreversible inhibitors (mipafox, iso-OMPA or PMSF), showing that these inhibitors interact similarly in both activities with similar second-order inhibition constants. Acethylthiocholine and phenyl valerate partly inhibit PVase and cholinesterase activities, respectively. All these observations suggest that both activities occur in the same active center. The interaction with a reversible inhibitor (ethopropazine) showed that the cholinesterase activity was more sensitive than the PVase activity, showing that the sensitivity for this reversible inhibitor is affected by the nature of the substrate. The present work definitively establishes the capacity of BuChE to hydrolyze the carboxylester phenyl valerate using a purified enzyme (hBuChE). Therefore, BuChE should be considered in the research of organophosphorus targets of toxicity related with PVase proteins.

Butyrylcholinesterase identification in a phenylvalerate esterase-enriched fraction sensitive to low mipafox concentrations in chicken brain.

Multiple epidemiological and experimental studies have demonstrated that exposure to organophosphorus compounds (OPs) is associated with a variety of neurological disorders. Some of these exposure symptoms cannot be precisely correlated with known molecular targets and mechanisms of toxicity. Most of the known molecular targets of OPs fall in the protein family of serine esterases. We have shown that three esterase components in the soluble fraction of chicken brain (an animal model frequently used in OP neurotoxicity assays) can be kinetically distinguished using paraoxon, mipafox and phenylmethyl sulfonyl fluoride as inhibitors, and phenyl valerate as a substrate; we termed them Eα, Eß and Eγ. The Eα-component, which is highly sensitive to paraoxon and mipafox and resistant to PMSF, has shown sensitivity to the substrate acetylthiocholine, and to ethopropazine and iso-OMPA (specific inhibitors of butyrylcholinesterase; BChE) but not to BW 284C51 (a specific inhibitor of acetylcholinesterase; AChE). In this work, we employed a large-scale proteomic analysis B with a LC/MS/MS TripleTOF system; 259 proteins were identified in a chromatographic fractionated sample enriched in Eα activity of the chicken brain soluble fraction. Bioinformatics analysis revealed that BChE is the only candidate protein identified to be responsible for almost all the Eα activity. This study demonstrates the potential information to be gained from combining kinetic dissection with large-scale proteomics and bioinformatics analyses for identification of proteins that are targets of OP toxicity and may be involved in detoxification of phosphoryl and carbonyl esters.

Stereospecific hydrolysis of a phosphoramidate used as an OPIDP model by human sera with PON1 192 alloforms.

O-hexyl 2,5-dichlorophenyl phosphoramidate (HDCP) is a racemic organophosphate compound (OP) that induces delayed neuropathy in vivo. The O-hexyl 2,5-dichlorophenyl phosphoramidate R (R-HDCP) isomer inhibits and ages neuropathic target esterase (NTE) in hen brain. Moreover, human serum paraoxonase-1 (PON1) is a Ca(2+)-dependent enzyme capable of hydrolyzing OPs. The enzymatic activity of PON1 against OPs depends on the genetic polymorphisms present at position 192 (glutamine or arginine). The catalytic efficiency of PON1 is an important factor that determines neurotoxic susceptibility to some OPs. In the present study, we characterized the stereospecific hydrolysis of HDCP by alloforms PON1 Q192R human serum by chiral chromatography. Forty-seven human samples were characterized for the PON1 192 polymorphism. The hydrolysis data demonstrate that the three alloforms of PON1 show an exclusive and significant stereospecific Ca(2+)-dependent hydrolysis of O-hexyl 2,5-dichlorophenyl phosphoramidate S isomer (S-HDCP) at 19-127 µM at the concentrations that remain in all the samples. This stereoselective Ca(2+)-dependent hydrolysis of S-HDCP is inhibited by EDTA and is independent of the PON1 Q192R alloform. The present research reinforces the hypothesis that R-HDCP (an isomer that inhibits and causes NTE aging) is the enantiomer that induces delayed neuropathy by this chiral phosphoramidate due to the low hydrolysis level of the R-HDCP observed in this study.

Organophosphorus pesticide chlorpyrifos and its metabolites alter the expression of biomarker genes of differentiation in D3 mouse embryonic stem cells in a comparable way to other model neurodevelopmental toxicants.

There are discrepancies about whether chlorpyrifos is able to induce neurodevelopmental toxicity or not. We previously reported alterations in the pattern of expression of biomarker genes of differentiation in D3 mouse embryonic stem cells caused by chlorpyrifos and its metabolites chlorpyrifos-oxon and 3,5,6-trichloro-2-pyridinol. Now, we reanalyze these data comparing the effects on these genes with those caused in the same genes by retinoic acid, valproic acid, and penicillin-G (model compounds considered as strong, weak, and non-neurodevelopmental toxicants, respectively). We also compare the effects of chlorpyrifos and its metabolites on the cell viability of D3 cells and 3T3 mouse fibroblasts with the effects caused in the same cells by the three model compounds. We conclude that chlorpyrifos and its metabolites act, regarding these end-points, as the weak neurodevelopmental toxicant valproic acid, and consequently, a principle of caution should be applied avoiding occupational exposures in pregnant women. A second independent experiment run with different cellular batches coming from the same clone obtained the same result as the first one.

Kinetic interactions of a neuropathy potentiator (phenylmethylsulfonyl fluoride) with the neuropathy target esterase and other membrane bound esterases.

Phenylmethylsulfonyl fluoride (PMSF) is a protease and esterase inhibitor that causes protection, or potentiation/"promotion," of organophosphorus delayed neuropathy (OPIDN), depending on whether it is dosed before or after an inducer of delayed neuropathy, such as mipafox. The molecular target of the potentiation/promotion of OPIDN has not yet been identified. The kinetic data of phenyl valerate esterase inhibition by PMSF were obtained with membrane chicken brain fractions, the animal model and tissue in which neuropathy target esterase (NTE) was first described. Data were analyzed using a kinetic model with a multienzymatic system in which inhibition, simultaneous chemical hydrolysis of the inhibitor and "ongoing inhibition" (inhibition during the substrate reaction) were considered. Three main esterase components were discriminated: two sensitive enzymatic entities representing 44 and 41 %, with I 50 (20 min) of 35 and 198 µM at 37 °C, respectively, and a resistant fraction of 15 % of activity. The estimated constant of the chemical hydrolysis of PMSF was also calculated (kh = 0.28 min(-1)). Four esterase components were globally identified considering also previously data with paraoxon and mipafox: EPα (4-8 %), highly sensitive to paraoxon and mipafox, spontaneously reactivates after inhibition with paraoxon, and resistant to PMSF; EPß (38-41 %), sensitive to paraoxon and PMSF, but practically resistant to mipafox, this esterase component has the kinetic characteristics expected for the PMSF potentiator target, even though paraoxon cannot be a potentiator in vivo due to high AChE inhibition; EPγ (NTE) (39-48 %), paraoxon-resistant and sensitive to the micromolar concentration of mipafox and PMSF; and EPδ (10 %), resistant to all the inhibitors assayed. This kinetic characterization study is needed for further isolation and molecular characterization studies, and these PMSF phenyl valerate esterase components will have to be considered in further studies of OPIDN promotion. A simple test for monitoring the four esterase components is proposed.

Genomic and phenotypic alterations of the neuronal-like cells derived from human embryonal carcinoma stem cells (NT2) caused by exposure to organophosphorus compounds paraoxon and mipafox.

Historically, only few chemicals have been identified as neurodevelopmental toxicants, however, concern remains, and has recently increased, based upon the association between chemical exposures and increased developmental disorders. Diminution in motor speed and latency has been reported in preschool children from agricultural communities. Organophosphorus compounds (OPs) are pesticides due to their acute insecticidal effects mediated by the inhibition of acetylcholinesterase, although other esterases as neuropathy target esterase (NTE) can also be inhibited. Other neurological and neurodevelopmental toxic effects with unknown targets have been reported after chronic exposure to OPs in vivo. We studied the initial stages of retinoic acid acid-triggered differentiation of pluripotent cells towards neural progenitors derived from human embryonal carcinoma stem cells to determine if neuropathic OP, mipafox, and non-neuropathic OP, paraoxon, are able to alter differentiation of neural precursor cells in vitro. Exposure to 1 µM paraoxon (non-cytotoxic concentrations) altered the expression of different genes involved in signaling pathways related to chromatin assembly and nucleosome integrity. Conversely, exposure to 5 µM mipafox, a known inhibitor of NTE activity, showed no significant changes on gene expression. We conclude that 1 µM paraoxon could affect the initial stage of in vitro neurodifferentiation possibly due to a teratogenic effect, while the absence of transcriptional alterations by mipafox exposure did not allow us to conclude a possible effect on neurodifferentiation pathways at the tested concentration.

Inhibition with simultaneous spontaneous reactivation and aging of acetylcholinesterase by organophosphorus compounds: Demeton-S-methyl as a model.

The kinetic analysis of esterase inhibition by acylating compounds (organophosphorus, carbamates and sulfonylfluorides) sometimes cannot yield consistent results by fitting simple inhibition kinetic models to experimental data of complex systems. In this work kinetic data were obtained for demeton-S-methyl (DSM) with human acetylcholinesterase in two kinds of experiments: (a) time progressive inhibition with a range of concentrations, (b) progressive spontaneous reactivation starting with pre-inhibited enzyme. DSM is an organophosphorus compound used as pesticide and considered a model for studying the dermal exposure of nerve agents such as VX gas. A kinetic model equation was deduced with four different molecular phenomena occurring simultaneously: (1) inhibition; (2) spontaneous reactivation; (3) aging; and (4) ongoing inhibition (inhibition during the substrate reaction). A 3D fit of the model was applied to analyze the inhibition experimental data. The best-fitting model is compatible with a sensitive enzymatic entity. The second-order rate constant of inhibition (ki = 0.0422 µM-1 min-1), the spontaneous reactivation constant (ks = 0.0202 min-1) and the aging constant (kg = 0.0043 min-1) were simultaneously estimated. As an example for testing the model and approach, it was tested also in the presence of 5 % ethanol (conditions as previously used in the literature), the best fitting model is compatible with two apparent sensitive enzymatic entities (17 % and 83 %) and only one spontaneously reactivates and ages. The corresponding second-order rate constants of inhibition (ki = 0.0354 and 0.0119 µM-1 min-1) and the spontaneous reactivation and aging constants for the less sensitive component (kr = 0.0203 min-1 and kg = 0.0088 min-1) were estimated. The results were also consistent with a significant ongoing inhibition. These parameters were similar to those deduced in spontaneous reactivation experiments of the pre-inhibited samples with DSM in the absence or presence of ethanol. The two apparent components fit was interpreted by an equilibrium between ethanol-free and ethanol-bound enzyme. The consistency of results in inhibition and in spontaneous reactivation experiments was considered an internal validation of the methodology and the conclusions.

Geological context and human exposures to element mixtures in mining and agricultural settings in Colombia.

Anthropogenic and natural sources contribute to chemical mixtures in air, water, and soil, posing potential risks to the environment and human health. To understand the interplay between element profiles in the human body, geographical location, and associated economic activities, we carried out an observational analytic cross-sectional study. The study recruited 199 participants from three municipalities, two of which had gold-mining as their primary economic activity, while the other was dedicated to agricultural and other local activities not related to mining. The concentrations of a total of 30 elements in human hair samples and 21 elements in environmental soil samples were measured using various spectrometry techniques. Unsupervised clustering analysis using Self-Organizing Maps was applied to human hair samples to analyze element concentrations. Distinct clusters of individuals were identified based on their hair element profiles, which were mapped to geographical location and economic activities. While higher levels of heavy metals (Ag, As, Hg, and Pb) were observed in individuals engaged in mining activities in certain clusters, individuals in agricultural areas show higher concentrations of elements found in pesticides (Ba and Sr). However, the elemental composition of hair is influenced not only by the anthropogenic activities but also by the inherent geological context where people live. Our findings highlight the significance of accounting for environmental factors when evaluating human health risks, as the intricate mixture of elements can yield valuable insights for targeted health interventions.

Chemical Element Mixtures and Kidney Function in Mining and Non-Mining Settings in Northern Colombia.

The exposure to chemical mixtures is a problem of concern in developing countries and it is well known that the kidney is the major target organ for toxic elements. This cross-sectional study aimed to estimate the individual and composite mixture effect of a large number of chemical elements on kidney function in gold-mining and surrounding non-mining populations in northeast Colombia. We measured concentrations of 36 chemical elements in hair as indicators of chronic exposure from 199 adult participants. We estimated the effect of exposure to mixtures of chemical elements on estimated glomerular filtration rate (eGFR) using weighted quantile sum regression (WQS). The WQS index of the mixture was associated with reduced eGFR (Coefficient -2.42; 95%CI: -4.69, -0.16) being Be, Cd, Pb, As, and Mn, the principal contributors of the toxic mixture. Mining activities and Hg concentration were not associated with decreased kidney function. Our results suggest that complex mixtures of chemical elements, mainly heavy metals, act as nephrotoxic in these populations and therefore the analysis of chemical element mixtures is a better approach to identify environmental and occupational chemical risks for kidney damage.

Phenylmethylsulfonyl fluoride, a potentiator of neuropathy, alters the interaction of organophosphorus compounds with soluble brain esterases.

Phenylmethylsulfonyl fluoride (PMSF) is a protease and esterase inhibitor that causes protection or potentiation/promotion of organophosphorus delayed neuropathy (OPIDN) depending on whether it is dosed before or after an inducer of delayed neuropathy. The molecular target of promotion has not yet been identified. Kinetic data of esterase inhibition were first obtained for PMSF with a soluble chicken brain fraction and then analyzed using a kinetic model with a multienzymatic system in which inhibition occurred with the simultaneous chemical hydrolysis of the inhibitor and ongoing inhibition (inhibition during the substrate reaction). The best fitting model was a model with resistant fraction, Eα (28%), and two sensitive enzymatic entities, Eß (61%) and Eγ (11%), with I(50) at 20 min of 70 and 447 µM, respectively. The estimated constant of the chemical hydrolysis of PMSF was kh = 0.23 min(-1). Eα, which is sensitive to mipafox and resistant to PMSF, became less sensitive to mipafox when the preparation was preincubated with PMSF. Its Eα I(50) (30 min) of mipafox increased with the PMSF concentration used to preincubate it. Eγ is sensitive to both PMSF and mipafox, and after preincubation with PMSF, Eγ became less sensitive to mipafox and was totally resistant after preincubation with 10 µM PMSF or more. The sensitivity of Eα to paraoxon (I(50) 30 min from 9 to 11 nM) diminished after PMSF preincubation (I(50) 30 min 185 nM) and showed no spontaneous reactivation capacity. The nature of these interactions is unknown but might be due to covalent binding at sites other than the substrate catalytic center. Such interactions should be considered to interpret the potentiation/promotion phenomenon of PMSF and to understand the effects of multiple exposures to chemicals.

Kinetics of inhibition of soluble peripheral nerve esterases by PMSF: a non-stable compound that potentiates the organophosphorus-induced delayed neurotoxicity.

The kinetic analysis of esterase inhibition by acylating compounds (organophosphorus carbamates and sulfonyl fluorides) is sometimes unable to yield consistent results by fitting simple inhibition kinetic models to experimental data of complex systems. In this work, kinetic data were obtained for phenylmethylsulfonyl fluoride (PMSF) tested at different concentrations incubated for up to 3 h with soluble fraction of chicken peripheral nerve. PMSF is a protease and esterase inhibitor causing protection or potentiation of the organophosphorus-induced delayed neuropathy and is unstable in water solution. The target of the promotion effect was proposed to be a soluble esterase not yet identified. A kinetic model equation was deduced assuming a multienzymatic system with three different molecular phenomena occurring simultaneously: (1) inhibition, (2) spontaneous chemical hydrolysis of the inhibitor and (3) ongoing inhibition (inhibition during the substrate reaction). A three-dimensional fit of the model was applied for analyzing the experimental data. The best-fitting model is compatible with a resistant component (16.5-18%) and two sensitive enzymatic entities (both 41%). The corresponding second-order rate constants of inhibition (ki = 12.04 × 10⁻² and 0.54 × 10⁻² µM⁻¹ min⁻¹, respectively) and the chemical hydrolysis constant of PMSF (kh = 0.0919 min⁻¹) were simultaneously estimated. These parameters were similar to those deduced in fixed-time inhibition experiments. The consistency of results in both experiments was considered an internal validation of the methodology. The results were also consistent with a significant ongoing inhibition. The proportion of enzymatic components showed in this work is similar to those previously observed in inhibition experiments with mipafox, S9B and paraoxon, demonstrating that this kinetic approach gives consistent results in complex enzymatic systems.

Characterization and evolution of exposure to volatile organic compounds in the Spanish shoemaking industry over a 5-year period.

This study measured inhalation exposure to 13 volatile organic compounds (VOCs) among workers in the leatherwear industry in Spain, examined the changes in those exposures over a 5-year period, and documented local exhaust ventilation practices that affected exposure. In collaboration with an occupational risk prevention company, air samples were collected from 849 workers' personal breathing zones using personal air pumps with activated charcoal tubes. VOCs were analyzed using a GC/MS-optimized method modified in our laboratory from that proposed by Spanish authorities (INSHT). Airborne concentrations were compared with occupational exposure limit (OEL) values from the European authorities. The most frequently detected VOCs were acetone (98.1%), toluene (94.8%), n-hexane (71.2%) and other C6-C7 branched alkyl hydrocarbons (97.5%). Other frequently detected VOCs were MEK (64.9%), ethylacetate (60.7%), and cyclohexane (29.3%). Benzene was detected in 24.6% of samples. Although all the samples were taken while workers performed tasks judged to have the highest VOC exposure potential, only 14% of samples showed excessive aggregate exposure, and chemical-specific OELs were exceeded in a relatively small number of cases: 7.2% for n-hexane, 2.8% for toluene, 0.6% for acetone, and 0.4% for hexane isomers. Over the study period, a diminished use of n-hexane in solvent formulations and an increased use of branched hexane and heptane isomers were observed. Six factors relating to work location conditions and types were evaluated. Most high-exposure cases were associated with three task types. The presence of local exhaust ventilation was an important exposure control, but significant exposures despite the use of local exhaust were observed. Although n-hexane exposures significantly decreased over the study period, the overall level of VOC exposure did not decrease. More effective exposure prevention measures need to be implemented.