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Projeto de investigação
Development of method for automatic on-line monitoring of VOC in automative plant and direct evalation of its impact on employers
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Ammonia Detection by Electronic Noses for a Safer Work Environment
Publication . Reis, Tiago; Moura, Pedro Catalão; Gonçalves, Débora; Ribeiro, Paulo A.; Vassilenko, Valentina; Fino, Maria Helena; Raposo, Maria; DF – Departamento de Física; LIBPhys-UNL; DEE - Departamento de Engenharia Electrotécnica e de Computadores; CTS - Centro de Tecnologia e Sistemas; UNINOVA-Instituto de Desenvolvimento de Novas Tecnologias; MDPI - Multidisciplinary Digital Publishing Institute
Providing employees with proper work conditions should be one of the main concerns of any employer. Even so, in many cases, work shifts chronically expose the workers to a wide range of potentially harmful compounds, such as ammonia. Ammonia has been present in the composition of products commonly used in a wide range of industries, namely production in lines, and also laboratories, schools, hospitals, and others. Chronic exposure to ammonia can yield several diseases, such as irritation and pruritus, as well as inflammation of ocular, cutaneous, and respiratory tissues. In more extreme cases, exposure to ammonia is also related to dyspnea, progressive cyanosis, and pulmonary edema. As such, the use of ammonia needs to be properly regulated and monitored to ensure safer work environments. The Occupational Safety and Health Administration and the European Agency for Safety and Health at Work have already commissioned regulations on the acceptable limits of exposure to ammonia. Nevertheless, the monitoring of ammonia gas is still not normalized because appropriate sensors can be difficult to find as commercially available products. To help promote promising methods of developing ammonia sensors, this work will compile and compare the results published so far.
Breath volatile organic compounds (VOCs) as biomarkers for the diagnosis of pathological conditions
Publication . Moura, Pedro Catalão; Raposo, Maria; Vassilenko, Valentina; LIBPhys-UNL; Elsevier BV
Normal and abnormal/pathological status of physiological processes in the human organism can be characterized through Volatile Organic Compounds (VOCs) emitted in breath. Recently, a wide range of volatile analytes has risen as biomarkers. These compounds have been addressed in the scientific and medical communities as an extremely valuable metabolic window. Once collected and analysed, VOCs can represent a tool for a rapid, accurate, non-invasive, and painless diagnosis of several diseases and health conditions. These biomarkers are released by exhaled breath, urine, faeces, skin, and several other ways, at trace concentration levels, usually in the ppbv (μg/L) range. For this reason, the analytical techniques applied for detecting and clinically exploiting the VOCs are extremely important. The present work reviews the most promising results in the field of breath biomarkers and the most common methods of detection of VOCs. A total of 16 pathologies and the respective database of compounds are addressed. An updated version of the VOCs biomarkers database can be consulted at: https://neomeditec.com/VOCdatabase/
Contemporary ion mobility spectrometry applications and future trends towards environmental, health and food research
Publication . Moura, Pedro Catalão; Vassilenko, Valentina; DF – Departamento de Física; LIBPhys-UNL; Elsevier
Ion Mobility Spectrometry (IMS) has gained relevance in the field of analytical techniques over the past decades. If compared with well-established techniques like mass spectrometry or infrared spectroscopy, IMS is considerably less developed or employed in specific fields but presents promising results and a substantial margin for improvements. Its outstanding sensitivity and selectivity, analytical flexibility, instrumental versatility and almost real-time results capacity have contributed to elevate IMS among the main analytical techniques for the detection of volatile organic compounds. Due to its growth potential, it is mandatory to assess in which scientific fields IMS has played a relevant role in the past years of academic research and understand in which areas it can become equally important in the near future. For this purpose, hundreds of scientific works from the past ten years were addressed and the most relevant were reviewed in this work. Three main categories of IMS applications were defined to group the reviewed articles: Environmental and Safety Research, Health Research and Food Research. In addition, some original studies were specifically developed for this review paper, to act as elucidative examples. The working principle of the IMS is included for clarification purposes. A glossary of all the mentioned compounds was also included. Throughout the text, it is clear how relevant IMS has become and how diverse its applicability can be, ranging from simpler topics like fraud detection to more complex ones like pathologies diagnosis. It is safe to say that IMS has been, step by step, gaining relevance as an analytical technique and its potential for supporting many diverse scientific fields is evident.
Graphene Oxide Thin Films for Detection and Quantification of Industrially Relevant Alcohols and Acetic Acid
Publication . Moura, Pedro Catalão; Pivetta, Thais Priscilla; Vassilenko, Valentina; Ribeiro, Paulo António; Raposo, Maria; DF – Departamento de Física; LIBPhys-UNL; MDPI - Multidisciplinary Digital Publishing Institute
Industrial environments are frequently composed of potentially toxic and hazardous compounds. Volatile organic compounds (VOCs) are one of the most concerning categories of analytes commonly existent in the indoor air of factories’ facilities. The sources of VOCs in the industrial context are abundant and a vast range of human health conditions and pathologies are known to be caused by both short- and long-term exposures. Hence, accurate and rapid detection, identification, and quantification of VOCs in industrial environments are mandatory issues. This work demonstrates that graphene oxide (GO) thin films can be used to distinguish acetic acid, ethanol, isopropanol, and methanol, major analytes for the field of industrial air quality, using the electronic nose concept based on impedance spectra measurements. The data were treated by principal component analysis. The sensor consists of polyethyleneimine (PEI) and GO layer-by-layer films deposited on ceramic supports coated with gold interdigitated electrodes. The electrical characterization of this sensor in the presence of the VOCs allows the identification of acetic acid in the concentration range from 24 to 120 ppm, and of ethanol, isopropanol, and methanol in a concentration range from 18 to 90 ppm, respectively. Moreover, the results allows the quantification of acetic acid, ethanol, and isopropanol concentrations with sensitivity values of (Formula presented.), (Formula presented.), and (Formula presented.) mL−1, respectively. The resolution of this sensor to detect the different analytes is lower than 0.04 ppm, which means it is an interesting sensor for use as an electronic nose for the detection of VOCs.
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Entidade financiadora
Fundação para a Ciência e a Tecnologia
Programa de financiamento
OE
Número da atribuição
PD/BDE/150627/2020