Your search keyword '"Rahkonen P"' showing total 3 results

1. Perturbation of metabolic pathways mediates the association of air pollutants with asthma and cardiovascular diseases

Author

Jeong, A., Fiorito, G., Keski-Rahkonen, P., Imboden, M., Kiss, A., Robinot, N., Gmuender, H., Vlaanderen, J., Vermeulen, R., Kyrtopoulos, S., Herceg, Z., Ghantous, A., Lovison, G., Galassi, C., Ranzi, A., Krogh, V., Grioni, S., Agnoli, C., Sacerdote, C., Mostafavi, N., Naccarati, A., Scalbert, A., Vineis, P., Probst-Hensch, N., One Health Chemisch, dIRAS RA-2, One Health Chemisch, dIRAS RA-2, Jeong, Ayoung, Fiorito, Giovanni, Keski-Rahkonen, Pekka, Imboden, Medea, Kiss, Agneta, Robinot, Nivonirina, Gmuender, Han, Vlaanderen, Jelle, Vermeulen, Roel, Kyrtopoulos, Soterio, Herceg, Zdenko, Ghantous, Akram, Lovison, Gianfranco, Galassi, Claudia, Ranzi, Andrea, Krogh, Vittorio, Grioni, Sara, Agnoli, Claudia, Sacerdote, Carlotta, Mostafavi, Nahid, Naccarati, Alessio, Scalbert, Augustin, Vineis, Paolo, and Probst-Hensch, Nicole

Subjects

Air pollution Untargeted metabolomics Metabolic pathways Adult-onset asthma Cardio-cerebrovascular diseases, 0301 basic medicine, Chronic exposure, Adult, Air pollution exposure, Air pollution, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Settore MED/01 - Statistica Medica, 03 medical and health sciences, Air pollutants, MD Multidisciplinary, medicine, Humans, 0105 earth and related environmental sciences, General Environmental Science, Asthma, Cardio-cerebrovascular diseases, Air Pollutants, Untargeted metabolomics, Odds ratio, Environmental Exposure, medicine.disease, Metabolic pathway, 030104 developmental biology, Metabolic pathways, Cardiovascular Diseases, Case-Control Studies, Immunology, EXPOsOMICS Consortium, Environmental Sciences, Metabolic Networks and Pathways, Adult-onset asthma

Abstract

Background: Epidemiologic evidence indicates common risk factors, including air pollution exposure, for respiratory and cardiovascular diseases, suggesting the involvement of common altered molecular pathways. Objectives: The goal was to find intermediate metabolites or metabolic pathways that could be associated with both air pollutants and health outcomes (“meeting-in-the-middle”), thus shedding light on mechanisms and reinforcing causality. Methods: We applied a statistical approach named ‘meet-in-the-middle’ to untargeted metabolomics in two independent case-control studies nested in cohorts on adult-onset asthma (AOA) and cardio-cerebrovascular diseases (CCVD). We compared the results to identify both common and disease-specific altered metabolic pathways. Results: A novel finding was a strong association of AOA with ultrafine particles (UFP; odds ratio 1.80 [1.26, 2.55] per increase by 5000 particles/cm3). Further, we have identified several metabolic pathways that potentially mediate the effect of air pollution on health outcomes. Among those, perturbation of Linoleate metabolism pathway was associated with air pollution exposure, AOA and CCVD. Conclusions: Our results suggest common pathway perturbations may occur as a consequence of chronic exposure to air pollution leading to increased risk for both AOA and CCVD.

Published

2018

2. Supplementary Material for: Comparison of Umbilical Serum Copeptin Relative to Erythropoietin and S100B as Asphyxia Biomarkers at Birth

Author

Summanen, M., Seikku, L., Rahkonen, P., Stefanovic, V., Teramo, K., Andersson, S., Kaila, K., and Rahkonen, L.

Subjects

reproductive and urinary physiology

Abstract

Background: Birth asphyxia, estimated to account for a million neonatal deaths annually, can cause a wide variety of neurodevelopmental impairments. There is a need to develop new, swift methods to identify those neonates who would benefit from neuroprotective treatments such as hypothermia. Objectives: To examine the utility of cord serum copeptin, a stable byproduct of arginine vasopressin release, as a biomarker of birth asphyxia based on a comparison with 2 biomarkers of hypoxia and brain trauma: erythropoietin and S100B. Methods: The study population consisted of 140 singleton, term neonates: 113 controls and 27 with birth asphyxia (2/3 criteria met: umbilical artery pH Results: Copeptin correlated in the entire study population more strongly with umbilical artery base excess than S100B and erythropoietin, and only copeptin correlated with arterial pH. Furthermore, only copeptin levels were significantly higher in cases of birth asphyxia, and in vaginally born neonates they were found to increase as a function of labor duration. Copeptin was elevated in neonates born via vacuum extraction, whereas erythropoietin levels showed a slight increase after emergency cesarean section. Conclusions: In this study population, S100B and erythropoietin were not valid biomarkers of birth asphyxia. In contrast, our work suggests that copeptin has high potential to become a routinely used biomarker for acute birth asphyxia and neonatal distress.

Published

2017

3. The impact of ambient air pollution on the human blood metabolome

Author

Vlaanderen, J.J., Janssen, N.A., Hoek, G., Keski-Rahkonen, P, Barupal, D K, Cassee, F.R., Gosens, I., Strak, M., Steenhof, M., Lan, Q., Brunekreef, B., Scalbert, Augustin, Vermeulen, R.C.H., LS IRAS EEPI GRA (Gezh.risico-analyse), Dep IRAS, LS IRAS EEPI ME (Milieu epidemiologie), LS IRAS EEPI Inhalatie Toxicologie, Sub IRAS Tox ITX (immunotoxicologie), dIRAS RA-2, dIRAS RA-1, LS IRAS EEPI GRA (Gezh.risico-analyse), Dep IRAS, LS IRAS EEPI ME (Milieu epidemiologie), LS IRAS EEPI Inhalatie Toxicologie, Sub IRAS Tox ITX (immunotoxicologie), dIRAS RA-2, and dIRAS RA-1

Subjects

0301 basic medicine, Spirometry, Male, Time Factors, Adolescent, Air pollution, Particulate matter components, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Biochemistry, 03 medical and health sciences, Young Adult, Metabolite profiling, Metabolome, medicine, Humans, 0105 earth and related environmental sciences, General Environmental Science, Netherlands, Air Pollutants, Ambient air pollution, Human blood, medicine.diagnostic_test, Chemistry, Environmental Exposure, Particulates, Peripheral blood, Cardio-respiratory health effects, 030104 developmental biology, Blood, Environmental chemistry, Female, Environmental Monitoring

Abstract

Background Biological perturbations caused by air pollution might be reflected in the compounds present in blood originating from air pollutants and endogenous metabolites influenced by air pollution (defined here as part of the blood metabolome). We aimed to assess the perturbation of the blood metabolome in response to short term exposure to air pollution. Methods We exposed 31 healthy volunteers to ambient air pollution for 5 h. We measured exposure to particulate matter, particle number concentrations, absorbance, elemental/organic carbon, trace metals, secondary inorganic components, endotoxin content, gaseous pollutants, and particulate matter oxidative potential. We collected blood from the participants 2 h before and 2 and 18 h after exposure. We employed untargeted metabolite profiling to monitor 3873 metabolic features in 493 blood samples from these volunteers. We assessed lung function using spirometry and six acute phase proteins in peripheral blood. We assessed the association of the metabolic features with the measured air pollutants and with health markers that we previously observed to be associated with air pollution in this study. Results We observed 89 robust associations between air pollutants and metabolic features two hours after exposure and 118 robust associations 18 h after exposure. Some of the metabolic features that were associated with air pollutants were also associated with acute health effects, especially changes in forced expiratory volume in 1 s. We successfully identified tyrosine, guanosine, and hypoxanthine among the associated features. Bioinformatics approach Mummichog predicted enriched pathway activity in eight pathways, among which tyrosine metabolism. Conclusions This study demonstrates for the first time the application of untargeted metabolite profiling to assess the impact of air pollution on the blood metabolome.

Published

2016