View clinical trials related to Pollution; Exposure.
Filter by:This is a small pilot intervention trial in which we will collect preliminary data to demonstrate the feasibility of an intervention study.
To reduce stress among urban residents, the consortium members of the European Council Horizon 2020 research program DivAirCity install different stress reducing, noise reducing and air quality improving means in the five cities of the consortium. This study measures physiological and psychological stress and health factors before and after the implementation of the project (at intervention sites) and compares the change (improvement) to the change in comparable places where no means were installed (control site).
The goal of this study was to investigate the effectiveness of three common approaches to upgrading residential mechanical ventilation systems in existing homes for improving asthma-related health outcomes, reducing indoor pollutants of both indoor and outdoor origin, and maintaining adequate environmental conditions and ventilation rates in a cohort of adult asthmatics in existing homes in Chicago, IL.
The goal of this observational study is to understand the burden and determinants of tobacco use and air pollution (AP) exposure among mid- to late adolescents in Greece, the Kyrgyz Republic, Pakistan, Romania, and Uganda. This context-specific knowledge will be crucial for selecting, adapting, and implementing preventive interventions in the next phase of the project. The main questions the investigators aim to answer are: - What is the perceived burden of tobacco use and AP exposure among adolescents? - What are the contextual drivers and behavioral determinants contributing to (prevention of) these risk factors? - How do the dynamics between stakeholders influence prevention efforts? In this study, data will be collected through interviews, focus group discussions, photovoice, document analysis, observations, personal exposure monitoring, and questionnaires.
The aim is to identify the underlying disease mechanisms driving specific asthma phenotypes as well as certain disease outcomes and their relation to impaired indoor air quality. This may also help in underpinning specific target mechanisms in order to personalize and improve current treatment options in childhood asthma and develop more successful prevention strategies. This will be done by combining data from detailed clinical phenotyping with multiple -omics data.
The goal of this observational study is to compare the effects of air pollution exposure and nutrition between neighborhoods with high and low social vulnerability scores. The main questions this study aims to answer are: - Does living in a neighborhood with high or low vulnerability influence the response of the heart, lungs, and immune system to air pollution. - Does nutritional status alter the association between air pollution exposure and changes in the heart, lungs, and immune system. Participants (age 25-70 years) that live in neighborhoods ranked high or low on the Social Vulnerability Index (SVI) will take part in 3 visits. Each visit involves the following: - Measurements of heart activity, lung function, and blood to measure changes that may be caused by air pollution. - Questionnaires about the types of food eaten and activities that may modify exposure to air pollution. - Estimation of air pollution exposure using a study iPhone. Participants will carry a study iPhone with them for 24 hours at each visit. The study iPhone runs an application (app) that estimates the amount of air pollution each participant is exposed to. - Wearing silicone wristbands for a week before each study visit. Silicone wristbands absorb air pollutants and are later measured see the types and amounts of chemicals participants are exposed to.
The primary project objective is to investigate how an individual's choices influence personal exposures to traffic-related air pollutants (TRAPs) and the corresponding acute health effects. TRAPs are a complex mixture of particulate and gaseous pollutants that vary considerably spatially and temporally. There is increasing evidence that TRAPs inflict a broad range of deleterious health effects in both health-compromised and healthy individuals, and it has been reported that traffic pollutants may cause up to half of all air pollution-related mortalities. Despite the burden from such widespread, involuntary exposures, few studies have examined the magnitude of personal exposures due to commuting exposures. Most commuters travel to and from work during two peak travel periods, which occur during weekday mornings and evenings. Public transportation, bicycling, and walking have been promoted as ways to reduce air pollution by reducing the vehicle fleet, yet few studies have examined how exposures are modified due to an intentional change in the time of commute or the subsequent health effects.
This study will evaluate the feasibility and acceptability of a household-based clean air intervention
Approximately 8% of all births occur between 30-36 weeks of gestation ('moderate-late' prematurity). Respiratory tract infections (RTI) and wheezing illnesses disproportionally affect preterm infants resulting in a 1.5-2 fold higher hospitalisation rate during the first years of life compared to term born children. Besides prematurity, several other postnatal modifiable influencing factors are associated with increased risk of respiratory morbidity and impaired pulmonary development. These factors include RTI, rapid weight gain, air pollution, tobacco smoke exposition, vitamin D deficiency, maternal stress and antibiotic usage. The investigators hypothesize that a follow-up program aiming at prevention of modifiable influencing factors can reduce respiratory morbidity in moderate and late prematurity. Objectives: To reduce respiratory disease burden in moderate-late preterm infants in the first 18 months of life
Lung cancer is the leading cause of mortality in the world, and also in Taiwan.Despite the researches and availability in new therapies, it causes the highest mortality and is one of the most preventable cancers as well. Smoking is the most common cause of lung cancer worldwide. Compared to lung cancer in smokers, lung cancer in never-smokers is associated with East Asian ethnicity, female sex, and adenocarcinoma histology. This unique risk group is likely to have distinct molecular drivers, especially EGFR, ALK, and ROS1 mutations.In National Taiwan Cancer Registry data, more than half (53%) of all newly diagnosed lung cancer patients and 93% of female patients are lifelong never-smokers. This scenario is common in East Asia. It is essential to develop a different strategy for screening lung cancer patients with other high-risk profiles. Several risk factors have been identified in never-smoking lung cancer and one of the most important factor is a lung cancer family history (LCFH) in a first-degree relative. Other high-risk occupational or environmental factors include air-pollution exposed occupations (such as traffic policeman and street cleaners) for at least 10 years, cooking index ≥ 110, defined as 2/7 * days cooking by pan frying, stir frying, or deep frying in one week * years cooking, cooking without using ventilation, passive smoke exposure, and history of pulmonary tuberculosis or chronic obstructive pulmonary disorders. As described above, three high risk groups are interested in this study, the previous heavy smokers (group 1); those who has family history (group 2) and those who have high risk occupation or environment factors (group 3). From the published researches, we assume the detection rate to be 1.1% for group 1 based on NLST results16, 2.6% for group 2 (395 out of 12,011 subjects in TALENT), and we assume the detection Group 3 to be 1% after consulting board-certified senior specialists in this field. This is a prospective, multi-center, single arm study in Taiwan of subjects who are eligible to receive LDCT screening based on recommendation of Health Promotion Administration of Taiwan. The primary objective of TRIO part A is the LDCT screening acceptance rate of high lung cancer risk subjects. The primary objective of TRIO part B is the exact lung cancer detection rates in these three groups. Other secondary objectives are also included.