Comparison of biological markers in aerosol-weighed workplaces

Funding Information: Funding information This work was supported by ESF project “The development of up-to-date diagnostic and research methods for the risks caused by nanoparticles and ergonomic factors at workplaces” (Agreement No. 2013/0050/1DP/1.1.1.2.0/13/ APIA/VIAA/025). Publisher Copyright: © 2019, The Author(s). Copyright: Copyright 2019 Elsevier B.V., All rights reserved.Airborne particulates present a potential hazard to health in a variety of indoor workplaces, from offices to the manufacturing floor. Dust and aerosols are two of the most common occupational risk factors in the workplace worldwide. It is very important to understand when it is sufficient to describe dust exposure only by given mass concentration that dust particles could be in the nanosized range in the workplace air even for brief exposures, such as welding aerosols. The main objective was to assess total dust and nanoparticle concentrations in the selected workplaces and to evaluate their impact on workers’ health. This project describes nanoparticle concentrations and their potential impact on workers’ health considering the exposure levels in three workplaces. Industrial and non-industrial environments have been included in the project. The office environment was used as an indicator for the background level of comparison with the metalworking and woodworking industries for measurements of dust particles including the nanoscale particles (> 100 nm). Fraction size of the samples according to a dispersity of > 10 μm, 0.25–10 μm, < 0.25 μm, and 1–100 nm was analysed in order to describe the particles’ chemical composition at the different stages. The worst working conditions (the smallest particles, 12 nm), the highest total dust concentrations, and the lowest difference between total inhalable particle and nanoparticle concentrations were detected among woodworkers. These findings provide a basis on how to evaluate nanoparticle exposure and its impact on workers’ health because the highest immune cell counts and relatively high IL-6 expression were observed among woodworkers compared with the other groups. The data show a negative tendency of nanoparticle exposure concentrations on workers’ health based on the increase of inflammatory processes and damage to airway epithelial cell functionality.Peer reviewe

Wrist hypothermia related to continuous work with a computer mouse : A digital infrared imaging pilot study

Publisher Copyright: © 2015 by the authors; licensee MDPI, Basel, Switzerland. Copyright: Copyright 2017 Elsevier B.V., All rights reserved.Computer work is characterized by sedentary static workload with low-intensity energy metabolism. The aim of our study was to evaluate the dynamics of skin surface temperature in the hand during prolonged computer mouse work under different ergonomic setups. Digital infrared imaging of the right forearm and wrist was performed during three hours of continuous computer work (measured at the start and every 15 minutes thereafter) in a laboratory with controlled ambient conditions. Four people participated in the study. Three different ergonomic computer mouse setups were tested on three different days (horizontal computer mouse without mouse pad; horizontal computer mouse with mouse pad and padded wrist support; vertical computer mouse without mouse pad). The study revealed a significantly strong negative correlation between the temperature of the dorsal surface of the wrist and time spent working with a computer mouse. Hand skin temperature decreased markedly after one hour of continuous computer mouse work. Vertical computer mouse work preserved more stable and higher temperatures of the wrist (>30 °C), while continuous use of a horizontal mouse for more than two hours caused an extremely low temperature (<28 °C) in distal parts of the hand. The preliminary observational findings indicate the significant effect of the duration and ergonomics of computer mouse work on the development of hand hypothermia.publishersversionPeer reviewe

In vitro impact preliminary assessment of airborne particulate from metalworking and woodworking industries

Funding Information: This work was supported by ESF project “Development of up-to-date diagnostic and research methods for the risks caused by nanoparticles and ergonomic factors at workplaces” Agreement No. 2013/0050/1DP/1.1.1.2.0/13/ APIA/VIAA/025. Publisher Copyright: © 2021, The Author(s).Inhalation is the main route of exposure to airborne pollutants. To evaluate the safety and assess the risks of occupational hazards different testing approaches are used. 3D airway epithelial tissues allow to mimic exposure conditions in vitro, generates human-relevant toxicology data, allows to elucidate the mode of action of pollutants. Gillian3500 pumps were used to collect the airborne particulate from woodworking and metalworking environments. EpiAirway tissues were used to model half working day (4 h), full working day (8 h), and 3 working day exposures to occupational pollutants. Tissue viability was assessed using an MTT assay. For preliminary assessment, RT-qPCR analyses were performed to analyze the expression of gelsolin, caspase-3, and IL-6. Tissue morphology was assessed by hematoxylin/eosin staining. An effect on the proliferation of lung epithelial cell line A549 was assessed. Acute exposure to workspace pollutants slightly affected tissue viability and did not change the morphology. No inhibiting effect was observed on the proliferation of A549 cells. Preliminary analysis showed that both types of particles suppressed the expression of gelsolin, with the effect of metalworking samples being more pronounced. A slight reduction in caspase-3 expression was observed. Particles from metalworking suppressed IL-6 expression.publishersversionPeer reviewe

HBM4EU Occupational Biomonitoring Study on e-Waste—Study Protocol

Funding Information: This work has received external 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: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.Workers involved in the processing of electronic waste (e-waste) are potentially exposed to toxic chemicals. If exposure occurs, this may result in uptake and potential adverse health effects. Thus, exposure surveillance is an important requirement for health risk management and prevention of occupational disease. Human biomonitoring by measurement of specific biomarkers in body fluids is considered as an effective method of exposure surveillance. The aim of this study is to investigate the internal exposure of workers processing e-waste using a human biomonitoring approach, which will stimulate improved work practices and contribute to raising awareness of potential hazards. This exploratory study in occupational exposures in e-waste processing is part of the European Human Biomonitoring Initiative (HBM4EU). Here we present a study protocol using a cross sectional survey design to study worker’s exposures and compare these to the exposure of subjects preferably employed in the same company but with no known exposure to industrial recycling of e-waste. The present study protocol will be applied in six to eight European countries to ensure standardised data collection. The target population size is 300 exposed and 150 controls. Biomarkers of exposure for the following chemicals will be used: chromium, cadmium and lead in blood and urine; brominated flame retardants and polychlorobiphenyls in blood; mercury, organophosphate flame retardants and phthalates in urine, and chromium, cadmium, lead and mercury in hair. In addition, the following effect biomarkers will be studied: micronuclei, epigenetic, oxidative stress, inflammatory markers and telomere length in blood and metabolomics in urine. Occupational hygiene sampling methods (airborne and settled dust, silicon wristbands and handwipes) and contextual information will be collected to facilitate the interpretation of the biomarker results and discuss exposure mitigating interventions to further reduce exposures if needed. This study protocol can be adapted to future European-wide occupational studiespublishersversionPeer reviewe

HBM4EU Occupational Biomonitoring Study on e-Waste—Study Protocol

Funding Information: This work has received external 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: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.Workers involved in the processing of electronic waste (e-waste) are potentially exposed to toxic chemicals. If exposure occurs, this may result in uptake and potential adverse health effects. Thus, exposure surveillance is an important requirement for health risk management and prevention of occupational disease. Human biomonitoring by measurement of specific biomarkers in body fluids is considered as an effective method of exposure surveillance. The aim of this study is to investigate the internal exposure of workers processing e-waste using a human biomonitoring approach, which will stimulate improved work practices and contribute to raising awareness of potential hazards. This exploratory study in occupational exposures in e-waste processing is part of the European Human Biomonitoring Initiative (HBM4EU). Here we present a study protocol using a cross sectional survey design to study worker’s exposures and compare these to the exposure of subjects preferably employed in the same company but with no known exposure to industrial recycling of e-waste. The present study protocol will be applied in six to eight European countries to ensure standardised data collection. The target population size is 300 exposed and 150 controls. Biomarkers of exposure for the following chemicals will be used: chromium, cadmium and lead in blood and urine; brominated flame retardants and polychlorobiphenyls in blood; mercury, organophosphate flame retardants and phthalates in urine, and chromium, cadmium, lead and mercury in hair. In addition, the following effect biomarkers will be studied: micronuclei, epigenetic, oxidative stress, inflammatory markers and telomere length in blood and metabolomics in urine. Occupational hygiene sampling methods (airborne and settled dust, silicon wristbands and handwipes) and contextual information will be collected to facilitate the interpretation of the biomarker results and discuss exposure mitigating interventions to further reduce exposures if needed. This study protocol can be adapted to future European-wide occupational studiespublishersversionPeer reviewe

African Genomic Medicine Training Initiative (AGMT)

The aim of this Professional Development Course was to provide genomics and genetics education to Nurses, Medical Doctors and Pathologists/Medical Laboratory Scientists & Technicians based in Africa. This course was provided free of charge - there was no cost associated with hosting a classroom for AGMT_2022. Further, attendance for participants and volunteer staff must be completely free-of-charge. If classrooms have running costs, they need to find alternate ways to cover these costs.  AGMT was launched in May 2016, in Senegal, by a group of stakeholders from the H3Africa Consortium and the AfSHG. AGMT course has successfully delivered a genomic medicine course to Nurses in 2017 and 2019. The 2022 iteration will deliver a genomic medicine course not only to Nurses but to Medical Doctors, Pathologists/Medical Laboratory Scientists and Technicians. There is a continuous need for genomic medicine across Africa from various health professionals. AGMT is working towards meeting this demand and accommodating different health professionals in addition to the group that it is currently accommodating.  The 1st AGMT iteration was run in 2017 with 19 classrooms in 11 countries, 1 online class, 225 students registered! The 2nd iteration was run in 2019 with 22 classrooms in 13 countries, 1 online class, 294 students registered. The 3rd iteration was run in 2022 with 24 classrooms (1 face-to-face, 3 blended and 20 online) in 11 countries and more than 800 participants with 261 students officially passing the course.</p