Ignite Creation Date:
2024-05-06 @ 8:25 PM
Last Modification Date:
2024-10-26 @ 3:27 PM
Study NCT ID:
NCT06371391
Status:
ACTIVE_NOT_RECRUITING
Last Update Posted:
2024-04-19
First Post:
2024-04-04
Brief Title:
Environmental and Occupational Noise Exposure in Relation to Incidence of Type 2 Diabetes
Sponsor:
Karolinska Institutet
Organization:
Karolinska Institutet
Study Overview
Official Title:
Environmental and Occupational Noise Exposure in Relation to Incidence of Type 2 Diabetes
Status:
ACTIVE_NOT_RECRUITING
Status Verified Date:
2024-04
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
Large parts of the population are exposed to traffic noise particularly in urban areas and high noise levels occur in many workplaces The aims of this project are to estimate exposure-response relationships for incidence of type 2 diabetes T2D related to long-term exposure to road traffic railway and aircraft noise as well as occupational noise Furthermore mediation by sleep disturbances and overweightobesity is investigated as well as interactions with air pollution and clinical biomarkers to elucidate important etiological pathways The project is based on pooled analyses of nine Scandinavian cohorts totally including more than 300 000 individuals Detailed longitudinal exposure to traffic noise from different sources air pollutants and greenness as well as occupational exposures are estimated with state-of-the-art methods and supplemented with questionnaire and registry data on risk factors as well as clinical measurements Incidence of T2D is assessed by combining information from medical examinations high quality registers questionnaires and biomarker measurements Population attributable risks are estimated by combining population data on exposure with information on exposure-response relationships In several aspects the project is unique and addresses questions which have never been studied before Our results will provide important guidance for prioritization of preventive measures to promote health sustainable urban development and safe workplaces
Detailed Description:
Study subjects
Nine Scandinavian cohorts constitute the sampling frame for the study Four cohorts were recruited in Stockholm County Stockholm Diabetes Preventive Program SDPP 60-year old men and women Sixty Twin Registry SALT and Swedish National Study of Aging and Care in Kungsholmen SNAC-K with a total of more than 22 500 participants The Malmö Diet and Cancer MDC study recruited 28 098 men and women living in the city of Malmö The Danish Diet Cancer and Health DCH cohort enrolled 57 053 subjects from the greater Copenhagen or Aarhus areas The Swedish Mammography Cohort SMC recruited 13 680 women esiding in the Uppsala area The Danish Nurse Cohort DNC included 28 731 female nurses from the whole of Denmark The Danish National Health Survey DNHS included 177 639 persons randomly selected across Denmark Overall enrollment focused on ages 16 to 99 years and occurred 1992-2013 The study subjects answered questionnaires at recruitment on lifestyle factors health status and socioeconomic characteristics
Exposure assessment
Traffic noise Transportation noise exposure is assessed based on well validated models Road traffic and railway noise are modelled using the Nordic Prediction Method or an update of this method For road traffic noise the input variables include geocodes screening by terrain and buildings and information on annual average daily traffic distribution of lightheavy traffic travel speed and road type for all major road links Railway noise is calculated for all addresses within a 1000 m buffer around all railway tracks Input variables include geocodes screening by terrain and buildings and average number of trains per period dayeveningnight train types and travel speed In addition cities with trams andor metro include these in the calculations Aircraft noise is estimated using noise maps obtained from local or national authorities
Detailed noise assessments have been performed every fifth or tenth year and noise levels for the years between those with estimates are calculated based on linear interpolation or other approximation methods For each participant the time-weighted average noise exposure from each traffic noise source during follow-up is calculated taking into account all addresses where the subject has lived and considering the duration of residence at each address In addition combined exposure to multiple traffic noise sources is estimated
Air pollution Levels of air pollution are estimated at all residential addresses during the study period for the subjects in the nine cohorts using validated high-resolution dispersion models 1 Air pollution exposure is represented by particulate matter with an aerodynamic diameter up to 25 µm PM25 which is influenced by both local and long-range transport and by nitrogen dioxide NO2 primarily reflecting local emissions such as from road traffic Interpolation of air pollution levels between years with assessments as well as calculation of individual time-weighted exposures are done using similar methodology as for transportation noise
Occupational exposures This is focused on noise and combustion particles based on occupations of the study subjects combined with information from a job-exposure-matrix JEM Occupational noise exposure is estimated based on a JEM developed in Sweden The JEM is based on occupational measurements and specifies the annual average of the daily 8-hour equivalent A-weighted sound pressure level in five exposure classes The noise level is matched on time period since noise levels differ within an occupation across time Occupational noise exposure at recruitment is used and if available exposure in certain time-windows during follow-up Occupational exposure to combustion particles is handled in the same way as noise but based on an adapted Finnish JEM
Covariates Selection of covariates is done a priori based on existing literature biological plausibility and availability of harmonizable variables across cohorts Cohort participants filled in questionnaires at recruitment with dietary and lifestyle variables including smoking status smoking intensity alcohol consumption and leisure-time physical activity Individual educational level and marital status are obtained from national registers or questionnaires and area-level small socioeconomically homogeneous areas with around 1000-2000 inhabitants mean income from registers Green areas are assessed from satellite images primarily using the normalized difference vegetation index
Outcome assessment
Incidence of T2D All relevant information collected within each cohort is used to identify prevalent cases of diabetes at baseline who will be excluded from the longitudinal analyses and incident cases during follow-up until 2020 This includes linking with the Patient and Prescribed Drug Registers as well as using self-reported diabetes in the questionnaires and biomarker measurements primarily fasting glucose and glycated hemoglobin both at baseline and during follow-up The methodology for identification of T2D cases has already been used successfully for cohorts in our project In Sweden the Patient Register has full coverage since 1987 but contains comprehensive outpatient data only since 2001 and the Prescribed Drug Register was started in 2005 In Denmark both the Patient and Prescribed Drug Registers have full coverage during virtually the whole follow-up period of their cohorts In addition there are national T2D registers in Sweden and Denmark but they do not have comprehensive coverage during most of the follow-up period Overall some registry sources for identification of T2D cases are lacking primarily for Swedish cohorts during the early part of the follow-up period However to the extent that this is unrelated to the exposures under study it will not affect the validity of the findings
Anthropometry In a majority of the cohorts measurements were performed by trained nurses of height weight and waist circumference at recruitment while corresponding information was self-reported in the remaining cohorts In two cohorts repeated measurements were performed during the during the follow-up period enabling longitudinal assessment of anthropometric characteristics In the mediation analyses overweightobesity data based on anthropometric information at recruitment will be combined with incident T2D during follow-up
Clinical biomarkers and measurements For five of the Swedish cohorts information at recruitment of study subjects is available on blood pressure based on measurements by trained nurses as well as on clinical biomarkers including serum glucose and lipids In the SNAC-K cohort measurements of glycated hemoglobin HbA1c levels were performed every 3-6 years from 2001 to 2019 For SDPP participants oral glucose tolerance tests have been made at three different occasions during follow-up The biomarker information enables accurate determination of T2D and prediabetes with due consideration of treatment and will also be used for validation of the registry and questionnaire-based information primarily to determine the degree of underdiagnosis
Population attributable risks Risk assessment is based on estimates of the population exposure to transportation noise and occupational noise in the catchment areas of the participating cohorts Aarhus Copenhagen Denmark Malmö Stockholm and Uppsala using the high-resolution modeling techniques described above This will be combined with exposure-response functions obtained in the project to estimate the number of cases of T2D attributable to transportation and occupational noise In particular assessment is made of the number of cases related to interactions between traffic noise and air pollution as well as with occupational exposures
Project organization
The project group involved in the project consists of Göran Pershagen professor at the Institute of Environmental Medicine IMM Karolinska Institutet KI with a focus on noise and air pollution epidemiology Sofia Carlsson associate professor and senior lecturer at IMM with a focus on T2D epidemiology Petter Ljungman associate professor at IMM and senior physician at the Department of Cardiology Danderyd Hospital with a focus on air pollution epidemiology and Mette Sörensen senior researcher at the Danish Cancer Society and adjunct professor Department of Natural Science and Environment Roskilde University with a focus on noise epidemiology In addition acoustician Mikael Ögren from Gothenburg University is involved as well as representatives from all participating cohorts A post-doctoral researcher will be hired for the project
Data analysis and statistics
Primarily logistic and Cox regression techniques as well as assessment of splines are used for estimation of exposure-response relationships in pooled analyses of the nine cohorts It is estimated that a total of more than 15 000 new cases of T2D will be detected during the follow-up period in the cohorts Ordinary power analyses are not meaningful since the aim is more ambitious than to merely detect a difference in risk between exposed and unexposed for which the statistical power is 100 with reasonable assumptions The main goal is to estimate exposure-response functions for traffic noise and T2D with adequate precision A study on traffic noise and stroke including 11 000 cases and based on pooled analyses of most of our cohorts showed narrow 95 confidence bands for the risk estimates within the range of common exposure to traffic noise which indicates that the study size is sufficient Furthermore analyses of interactions are performed such as between transportation noise sources and with air pollution using interaction terms as well as stratification Gender-specific results are produced in all analyses The extensive collection of information on risk factors for T2D enables careful control of confounding In particular confounding by socioeconomic factors is evaluated based on both individual and contextual data which could influence the choice of residence
Causal mediation analysis is used to explore the potential mediating role of overweightobesity in associations between transportation or occupational noise exposure and T2D incidence Two models are developed a logistic regression model for traffic noise exposure and overweightobesity and a Cox proportional hazard model for noise exposure and incident T2D conditional on overweightobesity with covariates similar to the prospective analyses The total effect the effect of traffic noise on incident T2D direct effect the effect independent of overweightobesity indirect effect the effect attributed to the impact of noise on obesityoverweight and the proportion mediated the proportion of indirect effect to total effect is calculated Similar mediation analyses will be performed for sleep disturbances in relation to the association between traffic noise and T2D
Nine Scandinavian cohorts constitute the sampling frame for the study Four cohorts were recruited in Stockholm County Stockholm Diabetes Preventive Program SDPP 60-year old men and women Sixty Twin Registry SALT and Swedish National Study of Aging and Care in Kungsholmen SNAC-K with a total of more than 22 500 participants The Malmö Diet and Cancer MDC study recruited 28 098 men and women living in the city of Malmö The Danish Diet Cancer and Health DCH cohort enrolled 57 053 subjects from the greater Copenhagen or Aarhus areas The Swedish Mammography Cohort SMC recruited 13 680 women esiding in the Uppsala area The Danish Nurse Cohort DNC included 28 731 female nurses from the whole of Denmark The Danish National Health Survey DNHS included 177 639 persons randomly selected across Denmark Overall enrollment focused on ages 16 to 99 years and occurred 1992-2013 The study subjects answered questionnaires at recruitment on lifestyle factors health status and socioeconomic characteristics
Exposure assessment
Traffic noise Transportation noise exposure is assessed based on well validated models Road traffic and railway noise are modelled using the Nordic Prediction Method or an update of this method For road traffic noise the input variables include geocodes screening by terrain and buildings and information on annual average daily traffic distribution of lightheavy traffic travel speed and road type for all major road links Railway noise is calculated for all addresses within a 1000 m buffer around all railway tracks Input variables include geocodes screening by terrain and buildings and average number of trains per period dayeveningnight train types and travel speed In addition cities with trams andor metro include these in the calculations Aircraft noise is estimated using noise maps obtained from local or national authorities
Detailed noise assessments have been performed every fifth or tenth year and noise levels for the years between those with estimates are calculated based on linear interpolation or other approximation methods For each participant the time-weighted average noise exposure from each traffic noise source during follow-up is calculated taking into account all addresses where the subject has lived and considering the duration of residence at each address In addition combined exposure to multiple traffic noise sources is estimated
Air pollution Levels of air pollution are estimated at all residential addresses during the study period for the subjects in the nine cohorts using validated high-resolution dispersion models 1 Air pollution exposure is represented by particulate matter with an aerodynamic diameter up to 25 µm PM25 which is influenced by both local and long-range transport and by nitrogen dioxide NO2 primarily reflecting local emissions such as from road traffic Interpolation of air pollution levels between years with assessments as well as calculation of individual time-weighted exposures are done using similar methodology as for transportation noise
Occupational exposures This is focused on noise and combustion particles based on occupations of the study subjects combined with information from a job-exposure-matrix JEM Occupational noise exposure is estimated based on a JEM developed in Sweden The JEM is based on occupational measurements and specifies the annual average of the daily 8-hour equivalent A-weighted sound pressure level in five exposure classes The noise level is matched on time period since noise levels differ within an occupation across time Occupational noise exposure at recruitment is used and if available exposure in certain time-windows during follow-up Occupational exposure to combustion particles is handled in the same way as noise but based on an adapted Finnish JEM
Covariates Selection of covariates is done a priori based on existing literature biological plausibility and availability of harmonizable variables across cohorts Cohort participants filled in questionnaires at recruitment with dietary and lifestyle variables including smoking status smoking intensity alcohol consumption and leisure-time physical activity Individual educational level and marital status are obtained from national registers or questionnaires and area-level small socioeconomically homogeneous areas with around 1000-2000 inhabitants mean income from registers Green areas are assessed from satellite images primarily using the normalized difference vegetation index
Outcome assessment
Incidence of T2D All relevant information collected within each cohort is used to identify prevalent cases of diabetes at baseline who will be excluded from the longitudinal analyses and incident cases during follow-up until 2020 This includes linking with the Patient and Prescribed Drug Registers as well as using self-reported diabetes in the questionnaires and biomarker measurements primarily fasting glucose and glycated hemoglobin both at baseline and during follow-up The methodology for identification of T2D cases has already been used successfully for cohorts in our project In Sweden the Patient Register has full coverage since 1987 but contains comprehensive outpatient data only since 2001 and the Prescribed Drug Register was started in 2005 In Denmark both the Patient and Prescribed Drug Registers have full coverage during virtually the whole follow-up period of their cohorts In addition there are national T2D registers in Sweden and Denmark but they do not have comprehensive coverage during most of the follow-up period Overall some registry sources for identification of T2D cases are lacking primarily for Swedish cohorts during the early part of the follow-up period However to the extent that this is unrelated to the exposures under study it will not affect the validity of the findings
Anthropometry In a majority of the cohorts measurements were performed by trained nurses of height weight and waist circumference at recruitment while corresponding information was self-reported in the remaining cohorts In two cohorts repeated measurements were performed during the during the follow-up period enabling longitudinal assessment of anthropometric characteristics In the mediation analyses overweightobesity data based on anthropometric information at recruitment will be combined with incident T2D during follow-up
Clinical biomarkers and measurements For five of the Swedish cohorts information at recruitment of study subjects is available on blood pressure based on measurements by trained nurses as well as on clinical biomarkers including serum glucose and lipids In the SNAC-K cohort measurements of glycated hemoglobin HbA1c levels were performed every 3-6 years from 2001 to 2019 For SDPP participants oral glucose tolerance tests have been made at three different occasions during follow-up The biomarker information enables accurate determination of T2D and prediabetes with due consideration of treatment and will also be used for validation of the registry and questionnaire-based information primarily to determine the degree of underdiagnosis
Population attributable risks Risk assessment is based on estimates of the population exposure to transportation noise and occupational noise in the catchment areas of the participating cohorts Aarhus Copenhagen Denmark Malmö Stockholm and Uppsala using the high-resolution modeling techniques described above This will be combined with exposure-response functions obtained in the project to estimate the number of cases of T2D attributable to transportation and occupational noise In particular assessment is made of the number of cases related to interactions between traffic noise and air pollution as well as with occupational exposures
Project organization
The project group involved in the project consists of Göran Pershagen professor at the Institute of Environmental Medicine IMM Karolinska Institutet KI with a focus on noise and air pollution epidemiology Sofia Carlsson associate professor and senior lecturer at IMM with a focus on T2D epidemiology Petter Ljungman associate professor at IMM and senior physician at the Department of Cardiology Danderyd Hospital with a focus on air pollution epidemiology and Mette Sörensen senior researcher at the Danish Cancer Society and adjunct professor Department of Natural Science and Environment Roskilde University with a focus on noise epidemiology In addition acoustician Mikael Ögren from Gothenburg University is involved as well as representatives from all participating cohorts A post-doctoral researcher will be hired for the project
Data analysis and statistics
Primarily logistic and Cox regression techniques as well as assessment of splines are used for estimation of exposure-response relationships in pooled analyses of the nine cohorts It is estimated that a total of more than 15 000 new cases of T2D will be detected during the follow-up period in the cohorts Ordinary power analyses are not meaningful since the aim is more ambitious than to merely detect a difference in risk between exposed and unexposed for which the statistical power is 100 with reasonable assumptions The main goal is to estimate exposure-response functions for traffic noise and T2D with adequate precision A study on traffic noise and stroke including 11 000 cases and based on pooled analyses of most of our cohorts showed narrow 95 confidence bands for the risk estimates within the range of common exposure to traffic noise which indicates that the study size is sufficient Furthermore analyses of interactions are performed such as between transportation noise sources and with air pollution using interaction terms as well as stratification Gender-specific results are produced in all analyses The extensive collection of information on risk factors for T2D enables careful control of confounding In particular confounding by socioeconomic factors is evaluated based on both individual and contextual data which could influence the choice of residence
Causal mediation analysis is used to explore the potential mediating role of overweightobesity in associations between transportation or occupational noise exposure and T2D incidence Two models are developed a logistic regression model for traffic noise exposure and overweightobesity and a Cox proportional hazard model for noise exposure and incident T2D conditional on overweightobesity with covariates similar to the prospective analyses The total effect the effect of traffic noise on incident T2D direct effect the effect independent of overweightobesity indirect effect the effect attributed to the impact of noise on obesityoverweight and the proportion mediated the proportion of indirect effect to total effect is calculated Similar mediation analyses will be performed for sleep disturbances in relation to the association between traffic noise and T2D
Study Oversight
Has Oversight DMC:
None
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?:
None