27 research outputs found
Development of the 4D program for simulation of human intrauterine frontal cortex development
The brain as a complex energy-informational system is dynamic structure, which during
intrauterine development in humans changes within each gestational week. The dramatic
introduction of endocrine disruptors in living systems on Earth is significantly reflected
in the number of diseases, obesity, and infertility. Brain due to its complexity demand
a specific scientific approach especially during intrauterine development. Development
of program, which will enable the introduction of a test platform for recognition of disturbances
within a horizontal, vertical and modular activity frames in the brain during development
caused by xenobiotics, such as endocrine disruptors, is of great significance
Environmental exposure to xenoestrogens and oestrogen related cancers: reproductive system, breast, lung, kidney, pancreas, and brain
The role of steroids in carcinogenesis has become a major concern in environmental protection, biomonitoring, and clinical research. Although historically oestrogen has been related to development of reproductive system, research over the last decade has confirmed its crucial role in the development and homeostasis of other organ systems. As a number of anthropogenic agents are xenoestrogens, environmental health research has focused on oestrogen receptor level disturbances and of aromatase polymorphisms. Oestrogen and xenoestrogens mediate critical points in carcinogenesis by binding to oestrogen receptors, whose distribution is age-, gender-, and tissue-specific. This review brings data about cancer types whose eatiology may be found in environmental exposure to xenoestrogens. Cancer types that have been well documented in literature to be related with environmental exposure include the reproductive system, breast, lung, kidney, pancreas, and brain. The results of our data mining show (a) a significant correlation between exposure to xenoestrogens and increased, gender-related, cancer risk and (b) a need to re-evaluate agents so far defined as endocrine disruptors, as they are also key molecules in carcinogenesis. This revision may be used to further research of cancer aetiology and to improvement of related legislation. Investigation of cancers caused by xenoestrogens may elucidate yet unknown mechanisms also valuable for oncology and the development of new therapies
Potential health risk of endocrine disruptors in construction sector and plastics industry: a new paradigm in occupational health
Endocrine disruptors (EDs) belong to large and diverse groups of agents that may cause
multiple biological effects associated with, for example, hormone imbalance and infertility, chronic
diseases such as diabetes, genome damage and cancer. The health risks related with the exposure to
EDs are typically underestimated, less well characterized, and not regulated to the same extent as, for
example, carcinogens. The increased production and utilization of identified or suspected EDs in
many different technological processes raises new challenges with respect to occupational exposure
settings and associated health risks. Due to the specific profile of health risk, occupational exposure
to EDs demands a new paradigm in health risk assessment, redefinition of exposure assessment, new
effects biomarkers for occupational health surveillance and definition of limit values. The construction
and plastics industries are among the strongest economic sectors, employing millions of workers
globally. They also use large quantities of chemicals that are known or suspected EDs. Focusing on
these two industries, this short communication discusses: (a) why occupational exposure to EDs
needs a more specific approach to occupational health risk assessments, (b) identifies the current
knowledge gaps, and (c) identifies and gives a rationale for a future occupational health paradigm,
which will include ED biomarkers as a relevant parameter in occupational health risk assessment,
surveillance and exposure preventioninfo:eu-repo/semantics/publishedVersio
The HBM4EU chromates study – Outcomes and impacts on EU policies and occupational health practices
Within the EU human biomonitoring initiative (HBM4EU), a targeted, multi-national study on occupational exposure to hexavalent chromium (Cr(VI)) was performed. Cr(VI) is currently regulated in EU under REACH (Registration, Evaluation, Authorisation and Restriction of Chemicals) and under occupational safety and health (OSH) legislation. It has recently been subject to regulatory actions to improve its risk management in European workplaces. Analysis of the data obtained within the HBM4EU chromates study provides support both for the implementation of these regulatory actions and for national enforcement programs and may also contribute to the updating of occupational limit values (OELs) and biological limit values for Cr(VI). It also provides useful insights on the contribution of different risk management measures (RMMs) to further reduce the exposure to Cr(VI) and may support the evaluation of applications for authorisation under REACH. Findings on chrome platers’ additional per- and polyfluoroalkyl substances (PFAS) exposure highlight the need to also pay attention to this substance group in the metals sector. A survey performed to evaluate the policy relevance of the HBM4EU chromates study findings supports the usefulness of the study results. According to the responses received from the survey, the HBM4EU chromates study was able to demonstrate the added value of the human biomonitoring (HBM) approach in assessment and management of occupational exposure to Cr(VI). For future occupational studies, we emphasise the need for engagement of policy makers and regulators throughout the whole research process to ensure awareness, relevance and uptake of the results in future policies.Highlights: Potential policy impact of the HBM4EU chromates study is presented and discussed; Surveyed policy makers confirmed policy relevance of biomonitoring results; Study considered to support national enforcement and further lowering of OELs; Added value of HBM in the management of occupational exposure to Cr(VI) was demonstrated; Close co-operation with regulators to support policy uptake is emphasised.Funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No 733032 and received co-funding from the author's organizations and/or Ministries.info:eu-repo/semantics/publishedVersio
The HBM4EU chromates study – Outcomes and impacts on EU policies and occupational health practices
Funding Information: The recently completed EU human biomonitoring initiative (HBM4EU, www.hbm4eu.eu/about-hbm4eu/), was a European Joint Programme that aimed to harmonise the collection and use of biomonitoring data to better understand human exposure to chemicals in the environment, in occupational settings and through the use of consumer products to improve chemical risk assessment and management efforts, and to support policy making (Ganzleben et al., 2017). Within the context of the HBM4EU project several priority substances were selected for investigation based on the most important needs of policy makers and risk assessors, as well as common needs of participating countries and a broad range of other stakeholders including trade unions (Ougier et al., 2021). Many of the priority substances, along with having an important economic role, also pose health risks for workers due to their occupational use. One of the priority substances was hexavalent chromium (Cr(VI)), which was the main focus of the first of a series of three different HBM4EU occupational studies (Santonen et al. 2019a, 2022), the other two being focussed on electronic waste (E-waste) and diisocyanates exposures (Jones et al., 2022; Scheepers et al., 2021). In addition to Cr(VI), it was recognised that in chrome plating activities there may also be exposure to another group of HBM4EU priority chemicals, per- and polyfluoroalkyl substances (PFASs). PFASs, including PFOS (perfluorooctane sulfonate), have been used as mist suppressants in chrome plating baths to prevent the evaporation of Cr(VI) vapours (Blepp et al., 2017; Gluge et al., 2020). Although PFOS has now been largely replaced in the EU, many of its substitutes in chrome plating activities are also PFASs which may cause similar health and environmental concerns.Occupational exposure to Cr(VI) has been associated with an increased risk of lung and sinonasal cancers and is suspected to lead to gastrointestinal tract cancers (den Braver-Sewradj et al., 2021; ECHA 2013; IARC 2012). In addition, it is a common cause of occupational asthma, allergic dermatitis and there is a concern for adverse effects on reproductive health (Sun and Costa 2022). Exposure to Cr(VI) may occur in several occupational activities, e.g., in welding, Cr(VI) electroplating and other surface treatment processes such as paint application and removal of old paint containing Cr(VI) (SCOEL 2017). In order to limit the workers’ exposure to Cr(VI) in the EU, Cr(VI) is currently regulated under both the European regulation (EC 1907/2006) on the Registration, Evaluation, Authorisation and Restriction of Chemicals (REACH) and the EU Directive 2004/37/EC on the protection of workers from the risks related to exposure to carcinogens, mutagens or reprotoxic substances at work (CMRD) (EU 2004). The current binding Occupational Exposure Limit (OEL) set under the EU Directive 2004/37/EC is 10 μg/m3 (8-h time-weighted average (8-h TWA)) until January 17, 2025. After that period, the OEL (8-h TWA) will be reduced to 5 μg/m3. For welding, plasma-cutting processes and similar work processes that generate fumes, there is a derogation with an OEL of 25 μg/m³ (8-h TWA) until January 2025; after that date the OEL (8-h TWA) of 5 μg/m3 will be applicable. France, the Netherlands and Denmark already have stricter limits, with an OEL of 1 μg/m3 (8-h TWA) for Cr(VI) in all uses (Beskæftigelsesministeriet 2020; Ministère du travail, 2012; MinSZW 2016). In the US, the American Conference of Governmental Industrial Hygienists (ACGIH) has published, for inhalable Cr(VI) compounds, a threshold limit value (TLV) of 0.2 μg/m3 (8-h TWA) and a TLV Short-Term Exposure Limit (STEL) of 0.5 μg/m3 (ACGIH 2021). No EU-wide biological limit values (BLVs) for Cr(VI) are available, however some Member States have set BLVs for occupational exposure to Cr(VI), measured as urinary chromium (U–Cr). For example, France and Finland have derived BLVs of 2.5 μg/L and 10 μg/L corresponding to their respective OELs of 1 μg/m3 and 5 μg/m3 for Cr(VI) (ANSES 2017; STM 2020). The German Research Foundation (DFG 2020) has established biological exposure equivalents for carcinogenic substances (EKA values), ranging from 12 to 40 μg/L for U–Cr. These correspond to exposures ranging between 30 and 100 μg/m3 soluble alkaline chromate and/or Cr(VI) containing welding fumes over an 8-h work shift (Bolt and Lewalter 2012). Since these current national BLVs are mainly based on studies from plating workers, they include uncertainties especially concerning their applicability to workplaces other than the electroplating industry. One of the main aims of the HBM4EU chromates study was to provide EU relevant data on the current occupational Cr(VI) exposure to support the regulatory risk assessment and decision-making process. In addition, exposure to PFASs was evaluated in a subset of workers performing chrome plating activities.This project has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement No 733032 and received co-funding from the author's organizations and/or Ministries. The project team would like to thank all the companies and workers who participated in the HBM4EU chromates study and all the experts who have contributed to the conduct of the study. Participants of the HBM4EU chromates study workshop and policy questionnaires are also acknowledged. Mr. Jouko Remes and Dr. Kia Gluschkoff (Finnish Institute of Occupational Health) are acknowledged for their assistance with the statistical analyses and figures. Funding Information: This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No 733032 and received co-funding from the author's organizations and/or Ministries. Publisher Copyright: © 2022 The AuthorsWithin the EU human biomonitoring initiative (HBM4EU), a targeted, multi-national study on occupational exposure to hexavalent chromium (Cr(VI)) was performed. Cr(VI) is currently regulated in EU under REACH (Registration, Evaluation, Authorisation and Restriction of Chemicals) and under occupational safety and health (OSH) legislation. It has recently been subject to regulatory actions to improve its risk management in European workplaces. Analysis of the data obtained within the HBM4EU chromates study provides support both for the implementation of these regulatory actions and for national enforcement programs and may also contribute to the updating of occupational limit values (OELs) and biological limit values for Cr(VI). It also provides useful insights on the contribution of different risk management measures (RMMs) to further reduce the exposure to Cr(VI) and may support the evaluation of applications for authorisation under REACH. Findings on chrome platers’ additional per- and polyfluoroalkyl substances (PFAS) exposure highlight the need to also pay attention to this substance group in the metals sector. A survey performed to evaluate the policy relevance of the HBM4EU chromates study findings supports the usefulness of the study results. According to the responses received from the survey, the HBM4EU chromates study was able to demonstrate the added value of the human biomonitoring (HBM) approach in assessment and management of occupational exposure to Cr(VI). For future occupational studies, we emphasise the need for engagement of policy makers and regulators throughout the whole research process to ensure awareness, relevance and uptake of the results in future policies.publishersversionepub_ahead_of_prin
Izloženost genotoksičnim agensima iz životnog okoliša tijekom prenatalnog razvoja i djetinjstva
Health disorders and diseases related to environmental exposure in children such as cancer and immunologic disturbances (asthma, allergies) are on the rise. However, complex transplacental and prepubertal genotoxicology is given very limited consideration, even though intrauterine development and early childhood may be critical for elucidating the cancer aetiology. The foetus is transplacentally exposed to contaminants in food and environment such as various chemicals, drugs, radiochemically contaminated water and air. Target organs of xenobiotic action may differ between the mother and the foetus due to specific stage of developmental physiology and enzyme distribution. This in turn may lead to different levels of clastogenic and aneugenic metabolites of the same xenobiotic in the mother and the foetus. Adult’s protective behaviour is not sufficient to isolate children from radioisotopes, pesticides, toxic metals and metalloids, environmental tobacco smoke, endocrine disrupting chemicals, and various food contaminants, which are just a part of the stressors present in a polluted environment. In order to improve legislation related to foetus and child exposure to genotoxic and possibly carcinogenic agents, oncologists, paediatricians, environmental health specialists, and genotoxicologists should work together much more closely to make a more effective use of accumulated scientific data, with the final aim to lower cancer incidence and mortality.Unatoč velikim naporima da se smanji okolišna izloženost u djece se dalje bilježi trend porasta pojavnosti karcinoma i imunosnih poremećaja (astma, alergije). Premda su intrauterini razvoj i rano djetinjstvo kritično razdoblje za tumačenje etiologije nastanka karcinoma, transplacentalna i prepubertetna genotoksikologija
do danas su slabo istražene. Fetus je transplacentalno izložen brojnim fizikalnim i kemijskim čimbenicima: kontaminantima iz hrane i okoliša, radiokemijski kontaminiranoj vodi, zraku te lijekovima. Ciljna tkiva za djelovanje ksenobiotika mogu biti različita u majke i fetusa zbog različitosti u razvojnoj fiziologiji i distribuciji enzima. Zbog toga u organizmu majke i fetusa mogu nastati različite razine klastogenih i aneugenih metabolita istog ksenobiotika.
Zaštitna uloga odraslih u namjeri da spriječe negativne utjecaje onečišćenog okoliša na djetetovo zdravlje često je ograničena jer su radioizotopi, olovo, PCB, pasivno pušenje, živa, endokrino aktivne tvari, pesticidi i kontaminanti prisutni u svim životnim područjima tijekom razvoja i rasta djeteta. Kako bi se poboljšalo zakonodavstvo vezano uz izloženost djece genotoksičnim i vjerojatno kancerogenim tvarima, tijekom razvoja potrebna je bolja suradnja onkologa, pedijatara, stručnjaka zdravstvene ekologije i genotoksikologa.
Na taj način ostvarilo bi se uspješnije iskorištavanje postojećih znanstvenih podataka u cilju smanjenja incidencije karcinoma i mortaliteta
um estudo no âmbito da Iniciativa Europeia em Biomonitorização Humana
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