Browsing by Author "Duca, Radu-Corneliu"
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- Developing human biomonitoring as a 21st century toolbox within the European exposure science strategy 2020-2030Publication . Zare Jeddi, Maryam; Hopf, Nancy B.; Louro, Henriqueta; Viegas, Susana; Galea, Karen S.; Pasanen-Kase, Robert; Santonen, Tiina; Mustieles, Vicente; Fernandez, Mariana F.; Verhagen, Hans; Bopp, Stephanie K.; Antignac, Jean Philippe; David, Arthur; Mol, Hans; Barouki, Robert; Audouze, Karine; Duca, Radu-Corneliu; Fantke, Peter; Scheepers, Paul; Ghosh, Manosij; Van Nieuwenhuyse, An; Lobo Vicente, Joana; Trier, Xenia; Rambaud, Loïc; Fillol, Clémence; Denys, Sebastien; Conrad, André; Kolossa-Gehring, Marike; Paini, Alicia; Arnot, Jon; Schulze, Florian; Jones, Kate; Sepai, Ovnair; Ali, Imran; Brennan, Lorraine; Benfenati, Emilio; Cubadda, Francesco; Mantovani, Alberto; Bartonova, Alena; Connolly, Alison; Slobodnik, Jaroslav; Bruinen de Bruin, Yuri; van Klaveren, Jacob; Palmen, Nicole; Dirven, Hubert; Husøy, Trine; Thomsen, Cathrine; Virgolino, Ana; Röösli, Martin; Gant, Tim; von Goetz, Natalie; Bessems, JosHuman biomonitoring (HBM) is a crucial approach for exposure assessment, as emphasised in the European Commission’s Chemicals Strategy for Sustainability (CSS). HBM can help to improve chemical policies in five major key areas: (1) assessing internal and aggregate exposure in different target populations; 2) assessing exposure to chemicals across life stages; (3) assessing combined exposure to multiple chemicals (mixtures); (4) bridging regulatory silos on aggregate exposure; and (5) enhancing the effectiveness of risk management measures. In this strategy paper we propose a vision and a strategy for the use of HBM in chemical regulations and public health policy in Europe and beyond. We outline six strategic objectives and a roadmap to further strengthen HBM approaches and increase their implementation in the regulatory risk assessment of chemicals to enhance our understanding of exposure and health impacts, enabling timely and targeted policy interventions and risk management. These strategic objectives are: 1) further development of sampling strategies and sample preparation; 2) further development of chemical-analytical HBM methods; 3) improving harmonisation throughout the HBM research life cycle; 4) further development of quality control / quality assurance throughout the HBM research life cycle; 5) obtain sustained funding and reinforcement by legislation; and 6) extend target-specific communication with scientists, policymakers, citizens and other stakeholders. HBM approaches are essential in risk assessment to address scientific, regulatory and societal challenges. HBM requires full and strong support from the scientific and regulatory domain to reach its full potential in public and occupational health assessment and in regulatory decision-making.
- FAIR environmental and health registry (FAIREHR)- supporting the science to policy interface and life science research, development and innovationPublication . Zare Jeddi, Maryam; Galea, Karen S.; Viegas, Susana; Fantke, Peter; Louro, Henriqueta; Theunis, Jan; Govarts, Eva; Denys, Sébastien; Fillol, Clémence; Rambaud, Loïc; Kolossa-Gehring, Marike; Santonen, Tiina; van der Voet, Hilko; Ghosh, Manosij; Costa, Carla; Teixeira, João Paulo; Verhagen, Hans; Duca, Radu-Corneliu; Van Nieuwenhuyse, An; Jones, Kate; Sams, Craig; Sepai, Ovnair; Tranfo, Giovanna; Bakker, Martine; Palmen, Nicole; van Klaveren, Jacob; Scheepers, Paul T. J.; Paini, Alicia; Canova, Cristina; von Goetz, Natalie; Katsonouri, Andromachi; Karakitsios, Spyros; Sarigiannis, Dimosthenis A.; Bessems, Jos; Machera, Kyriaki; Harrad, Stuart; Hopf, Nancy B.The environmental impact on health is an inevitable by-product of human activity. Environmental health sciences is a multidisciplinary field addressing complex issues on how people are exposed to hazardous chemicals that can potentially affect adversely the health of present and future generations. Exposure sciences and environmental epidemiology are becoming increasingly data-driven and their efficiency and effectiveness can significantly improve by implementing the FAIR (findable, accessible, interoperable, reusable) principles for scientific data management and stewardship. This will enable data integration, interoperability and (re)use while also facilitating the use of new and powerful analytical tools such as artificial intelligence and machine learning in the benefit of public health policy, and research, development and innovation (RDI). Early research planning is critical to ensuring data is FAIR at the outset. This entails a well-informed and planned strategy concerning the identification of appropriate data and metadata to be gathered, along with established procedures for their collection, documentation, and management. Furthermore, suitable approaches must be implemented to evaluate and ensure the quality of the data. Therefore, the 'Europe Regional Chapter of the International Society of Exposure Science' (ISES Europe) human biomonitoring working group (ISES Europe HBM WG) proposes the development of a FAIR Environment and health registry (FAIREHR) (hereafter FAIREHR). FAIR Environment and health registry offers preregistration of studies on exposure sciences and environmental epidemiology using HBM (as a starting point) across all areas of environmental and occupational health globally. The registry is proposed to receive a dedicated web-based interface, to be electronically searchable and to be available to all relevant data providers, users and stakeholders. Planned Human biomonitoring studies would ideally be registered before formal recruitment of study participants. The resulting FAIREHR would contain public records of metadata such as study design, data management, an audit trail of major changes to planned methods, details of when the study will be completed, and links to resulting publications and data repositories when provided by the authors. The FAIREHR would function as an integrated platform designed to cater to the needs of scientists, companies, publishers, and policymakers by providing user-friendly features. The implementation of FAIREHR is expected to yield significant benefits in terms of enabling more effective utilization of human biomonitoring (HBM) data.
- From inequitable to sustainable e-waste processing for reduction of impact on human health and the environmentPublication . Ádám, Balázs; Göen, Thomas; Scheepers, Paul T.J.; Adliene, Diana; Batinic, Bojan; Budnik, Lygia T.; Duca, Radu-Corneliu; Ghosh, Manosij; Giurgiu, Doina I.; Godderis, Lode; Goksel, Ozlem; Hansen, Karoline K.; Kassomenos, Pavlos; Milic, Natasa; Orru, Hans; Paschalidou, Anastasia; Petrovic, Maja; Puiso, Judita; Radonic, Jelena; Sekulic, Maja T.; Teixeira, Joao Paulo; Zaid, Hilal; Au, William W.Recycling of electric and electronic waste products (e-waste) which amounted to more than 50 million metric tonnes per year worldwide is a massive and global operation. Unfortunately, an estimated 70-80% of this waste has not been properly managed because the waste went from developed to low-income countries to be dumped into landfills or informally recycled. Such recycling has been carried out either directly on landfill sites or in small, often family-run recycling shops without much regulations or oversights. The process traditionally involved manual dismantling, cleaning with hazardous solvents, burning and melting on open fires, etc., which would generate a variety of toxic substances and exposure/hazards to applicators, family members, proximate residents and the environment. The situation clearly calls for global responsibility to reduce the impact on human health and the environment, especially in developing countries where poor residents have been shouldering the hazardous burden. On the other hand, formal e-waste recycling has been mainly conducted in small scales in industrialised countries. Whether the latter process would impose less risk to populations and environment has not been determined yet. Therefore, the main objectives of this review are: 1. to address current trends and emerging threats of not only informal but also formal e-waste management practices, and 2. to propose adequate measures and interventions. A major recommendation is to conduct independent surveillance of compliance with e-waste trading and processing according to the Basel Ban Amendment. The recycling industry needs to be carefully evaluated by joint effort from international agencies, producing industries and other stakeholders to develop better processes. Subsequent transition to more sustainable and equitable e-waste management solutions should result in more effective use of natural resources, and in prevention of adverse effects on health and the environment.
- HBM4EU Diisocyanates Study-Research Protocol for a Collaborative European Human Biological Monitoring Study on Occupational ExposurePublication . Jones, Kate; Galea, Karen S.; Scholten, Bernice; Loikala, Marika; Porras, Simo P.; Bousoumah, Radia; Ndaw, Sophie; Leese, Elizabeth; Louro, Henriqueta; Silva, Maria João; Viegas, Susana; Godderis, Lode; Verdonck, Jelle; Poels, Katrien; Gӧen, Thomas; Duca, Radu-Corneliu; Santonen, Tiina; HBM4EU Diisocyanates Study TeamDiisocyanates have long been a leading cause of occupational asthma in Europe, and recently, they have been subjected to a restriction under the REACH regulations. As part of the European Human Biomonitoring project (HBM4EU), we present a study protocol designed to assessoccupational exposure to diisocyanates in five European countries. The objectives of the study are to assess exposure in a number of sectors that have not been widely reported on in the past (for example, the manufacturing of large vehicles, such as in aerospace; the construction sector, where there are potentially several sources of exposure (e.g., sprayed insulation, floor screeds); the use of MDI-based glues, and the manufacture of spray adhesives or coatings) to test the usability of different biomarkers in the assessment of exposure to diisocyanates and to provide background data for regulatory purposes. The study will collect urine samples (analysed for diisocyanate-derived diamines and acetyl–MDI–lysine), blood samples (analysed for diisocyanate-specific IgE and IgG antibodies, inflammatory markers, and diisocyanate-specific Hb adducts for MDI), and buccal cells(micronucleus analysis) and measure fractional exhaled nitric oxide. In addition, occupational hygienemeasurements (air monitoring and skin wipe samples) and questionnaire data will be collected. The protocol is harmonised across the participating countries to enable pooling of data, leading to better and more robust insights and recommendations.
- A human biomonitoring (HBM) Global Registry Framework: Further advancement of HBM research following the FAIR principlesPublication . Zare Jeddi, Maryam; Virgolino, Ana; Fantke, Peter; Hopf, Nancy B.; Galea, Karen S.; Remy, Sylvie; Viegas, Susana; Mustieles, Vicente; Fernandez, Mariana F.; von Goetz, Natalie; Vicente, Joana Lobo; Slobodnik, Jaroslav; Rambaud, Loïc; Denys, Sébastien; St-Amand, Annie; Nakayama, Shoji F.; Santonen, Tiina; Barouki, Robert; Pasanen-Kase, Robert; Mol, Hans G.J.; Vermeire, Theo; Jones, Kate; Silva, Maria João; Louro, Henriqueta; van der Voet, Hilko; Duca, Radu-Corneliu; Verhagen, Hans; Canova, Cristina; van Klaveren, Jacob; Kolossa-Gehring, Marike; Bessems, JosData generated by the rapidly evolving human biomonitoring (HBM) programmes are providing invaluable opportunities to support and advance regulatory risk assessment and management of chemicals in occupational and environmental health domains. However, heterogeneity across studies, in terms of design, terminology, biomarker nomenclature, and data formats, limits our capacity to compare and integrate data sets retrospectively (reuse). Registration of HBM studies is common for clinical trials; however, the study designs and resulting data collections cannot be traced easily. We argue that an HBM Global Registry Framework (HBM GRF) could be the solution to several of challenges hampering the (re)use of HBM (meta)data. The aim is to develop a global, host-independent HBM registry framework based on the use of harmonised open-access protocol templates from designing, undertaking of an HBM study to the use and possible reuse of the resulting HBM (meta)data. This framework should apply FAIR (Findable, Accessible, Interoperable and Reusable) principles as a core data management strategy to enable the (re)use of HBM (meta)data to its full potential through the data value chain. Moreover, we believe that implementation of FAIR principles is a fundamental enabler for digital transformation within environmental health. The HBM GRF would encompass internationally harmonised and agreed open access templates for HBM study protocols, structured web-based functionalities to deposit, find, and access harmonised protocols of HBM studies. Registration of HBM studies using the HBM GRF is anticipated to increase FAIRness of the resulting (meta)data. It is also considered that harmonisation of existing data sets could be performed retrospectively. As a consequence, data wrangling activities to make data ready for analysis will be minimised. In addition, this framework would enable the HBM (inter)national community to trace new HBM studies already in the planning phase and their results once finalised. The HBM GRF could also serve as a platform enhancing communication between scientists, risk assessors, and risk managers/policy makers. The planned European Partnership for the Assessment of Risk from Chemicals (PARC) work along these lines, based on the experience obtained in previous joint European initiatives. Therefore, PARC could very well bring a first demonstration of first essential functionalities within the development of the HBM GRF.
- Human Biomonitoring: from group to personalized exposure assessment in occupational settingsPublication . Duca, Radu-Corneliu; Viegas, Susana; Galea, Karen S.; Louro, Henriqueta; Santonen, Tiina; Jones, Kate; Sepai, OvnairThe necessity of using human biomonitoring (HBM) for chemical health risk assessment for both general population and workers has recently been brought to the fore. HBM4EU (www.hbm4eu.eu) has the main aim to coordinate and advance HBM in Europe. One of the many intended outcomes of this project is to harmonize HBM protocols and to demonstrate the utility of HBM when assessing workers exposure to chemicals. In occupational settings, analysis of environmental matrices may be insufficient to demonstrate the amount of compounds absorbed into the body. Analysis of biomarkers in biological samples to determine the internal dose is therefore an important asset in defining prevention strategies. Nevertheless, the interpretation of the HBM results might be challenging, especially at individual level, since, the absorbed dose is determined by many factors, e.g. chemical concentration, its physicochemical properties, exposure duration as well as individual factors including up-take, metabolism etc. The specificity and sensitivity of the chosen biomarker depends e.g. on its physiological half-live in the selected biological matrix. The number of compounds having recommended Biological Limit Values (BLVs) to assist in the identification of health hazards is limited. In addition, no BLVs are available for biological matrices other than urine and blood that might be related to a longer physiological half-live of the target compounds (e.g. hair) or directly related to the target organs (e.g. Exhaled Breath Condansate). However, more research is required to develop guidelines in order to choose the most appropriate biomarker and/or matrix. Within the HBM4EU occupational studies, we intend to demonstrate that the individual analysis of biomonitoring is a useful tool for personal exposure evaluation, providing information not given by inhalation and dermal exposure assessment. HBM will highlight personal working conditions and practices, taking into account individual differences and allowing more individualized measures to prevent exposure by changing individual behavior.
- Towards a systematic use of effect biomarkers in population and occupational biomonitoringPublication . Zare Jeddi, Maryam; Hopf, Nancy B.; Viegas, Susana; Price, Anna Bal; Paini, Alicia; van Thriel, Christoph; Benfenati, Emilio; Ndaw, Sophie; Bessems, Jos; Behnisch, Peter A.; Leng, Gabriele; Duca, Radu-Corneliu; Verhagen, Hans; Cubadda, Francesco; Brennan, Lorraine; Ali, Imran; David, Arthur; Mustieles, Vicente; Fernandez, Mariana F.; Louro, Henriqueta; Pasanen-Kase, RobertEffect biomarkers can be used to elucidate relationships between exposure to environmental chemicals and their mixtures with associated health outcomes, but they are often underused, as underlying biological mechanisms are not understood. We aim to provide an overview of available effect biomarkers for monitoring chemical exposures in the general and occupational populations, and highlight their potential in monitoring humans exposed to chemical mixtures. We also discuss the role of the adverse outcome pathway (AOP) framework and physiologically based kinetic and dynamic (PBK/D) modelling to strengthen the understanding of the biological mechanism of effect biomarkers, and in particular for use in regulatory risk assessments. An interdisciplinary network of experts from the European chapter of the International Society for Exposure Science (ISES Europe) and the Organization for Economic Co-operation and Development (OECD) Occupational Biomonitoring activity of Working Parties of Hazard and Exposure Assessment group worked together to map the conventional framework of biomarkers and provided recommendations for their systematic use. We summarized the key aspects of this work here, and discussed these in three parts. Part I, we inventory available effect biomarkers and promising new biomarkers for the general population based on the H2020 Human Biomonitoring for Europe (HBM4EU) initiative. Part II, we provide an overview AOP and PBK/D modelling use that improved the selection and interpretation of effect biomarkers. Part III, we describe the collected expertise from the OECD Occupational Biomonitoring subtask effect biomarkers in prioritizing relevant mode of actions (MoAs) and suitable effect biomarkers. Furthermore, we propose a tiered risk assessment approach for occupational biomonitoring. Several effect biomarkers, especially for use in occupational settings, are validated. They offer a direct assessment of the overall health risks associated with exposure to chemicals, chemical mixtures and their transformation products. Promising novel effect biomarkers are emerging for biomonitoring of the general population. Efforts are being dedicated to prioritizing molecular and biochemical effect biomarkers that can provide a causal link in exposure-health outcome associations. This mechanistic approach has great potential in improving human health risk assessment. New techniques such as in silico methods (e.g. QSAR, PBK/D modelling) as well as 'omics data will aid this process. Our multidisciplinary review represents a starting point for enhancing the identification of effect biomarkers and their mechanistic pathways following the AOP framework. This may help in prioritizing the effect biomarker implementation as well as defining threshold limits for chemical mixtures in a more structured way. Several ex vivo biomarkers have been proposed to evaluate combined effects including genotoxicity and xeno-estrogenicity. There is a regulatory need to derive effect-based trigger values using the increasing mechanistic knowledge coming from the AOP framework to address adverse health effects due to exposure to chemical mixtures. Such a mechanistic strategy would reduce the fragmentation observed in different regulations. It could also stimulate a harmonized use of effect biomarkers in a more comparable way, in particular for risk assessments to chemical mixtures.