Your search keyword '"Bi, Peng"' showing total 10 results

1. Using the excess heat factor to indicate heatwave-related urinary disease: a case study in Adelaide, South Australia

Author

Borg, Matthew, Nitschke, Monika, Williams, Susan, McDonald, Stephen, Nairn, John, and Bi, Peng

Published

2019

2. Heatwave and work-related injuries and illnesses in Adelaide, Australia: a case-crossover analysis using the Excess Heat Factor (EHF) as a universal heatwave index

Author

Varghese, Blesson M., Hansen, Alana, Nitschke, Monika, Nairn, John, Hanson-Easey, Scott, Bi, Peng, and Pisaniello, Dino

Published

2019

3. Heatwaves differentially affect risk of Salmonella serotypes.

Author

Milazzo, Adriana, Giles, Lynne C., Zhang, Ying, Koehler, Ann P., Hiller, Janet E., and Bi, Peng

Subjects

ANIMAL experimentation, CHAOS theory, HEAT, HOSPITAL care, HOSPITAL emergency services, REGRESSION analysis, SALMONELLA, SEASONS, TEMPERATURE, PHENOMENOLOGICAL biology, SALMONELLA diseases, SEROTYPES, PHYSIOLOGY

Abstract

Objectives: Given increasing frequency of heatwaves and growing public health concerns associated with foodborne disease, we examined the relationship between heatwaves and salmonellosis in Adelaide, Australia.Methods: Poisson regression analysis with Generalised Estimating Equations was used to estimate the effect of heatwaves and the impact of intensity, duration and timing on salmonellosis and specific serotypes notified from 1990 to 2012. Distributed lag non-linear models were applied to assess the non-linear and delayed effects of temperature during heatwaves on Salmonella cases.Results: Salmonella typhimurium PT135 notifications were sensitive to the effects of heatwaves with a twofold (IRR 2.08, 95% CI 1.14-3.79) increase in cases relative to non-heatwave days. Heatwave intensity had a significant effect on daily counts of overall salmonellosis with a 34% increase in risk of infection (IRR 1.34, 95% CI 1.01-1.78) at >41 °C. The effects of temperature during heatwaves on Salmonella cases and serotypes were found at lags of up to 14 days.Conclusion: This study confirms heatwaves have a significant effect on Salmonella cases, and for the first time, identifies its impact on specific serotypes and phage types. These findings will contribute to the understanding of the impact of heatwaves on salmonellosis and provide insights that could mitigate their impact. [ABSTRACT FROM AUTHOR]

Published

2016

4. The impact of heatwaves on workers׳ health and safety in Adelaide, South Australia.

Author

Xiang, Jianjun, Bi, Peng, Pisaniello, Dino, and Hansen, Alana

Subjects

*TIME series analysis, *GENERALIZED estimating equations, *HEAT waves (Meteorology), *TEAMS in the workplace

Abstract

This study aims to investigate the impact of heatwaves on worker׳s health and safety; to identify workers at higher risk of prevalent illnesses and injuries due to heatwaves; and to provide evidence for policy-makers and service providers. South Australian workers׳ compensation claims data for 2001–2010 were transformed into time series format, merged with meteorological data and analysed using generalized estimating equation (GEE) models. For total injury claims there was no significant difference detected between heatwave and non-heatwave periods. However, for outdoor industries, daily claims increased significantly by 6.2% during heatwaves. Over-represented in hot weather were male labourers and tradespersons aged ≥55 years, and those employed in ‘agriculture, forestry and fishing’ and ‘electricity, gas and water’. Occupational burns, wounds, lacerations, and amputations as well as heat illnesses were significantly associated with heatwaves. Similarly, moving objects, contact with chemicals, and injuries related to environmental factors increased significantly during heatwaves, especially among middle-aged and older male workers. With the predicted increase of extremely hot weather, there is a need for relevant adaptation and prevention measures at both practice and policy levels for vulnerable work groups. [ABSTRACT FROM AUTHOR]

Published

2014

5. Current and projected heatwave-attributable occupational injuries, illnesses, and associated economic burden in Australia.

Author

Borg, Matthew A., Xiang, Jianjun, Anikeeva, Olga, Ostendorf, Bertram, Varghese, Blesson, Dear, Keith, Pisaniello, Dino, Hansen, Alana, Zander, Kerstin, Sim, Malcolm R., and Bi, Peng

Subjects

*WORK-related injuries, *WORKERS' compensation claims, *HEAT waves (Meteorology), *HEAT adaptation

Abstract

The costs of global warming are substantial. These include expenses from occupational illnesses and injuries (OIIs), which have been associated with increases during heatwaves. This study estimated retrospective and projected future heatwave-attributable OIIs and their costs in Australia. Climate and workers' compensation claims data were extracted from seven Australian capital cities representing OIIs from July 2005 to June 2018. Heatwaves were defined using the Excess Heat Factor. OIIs and associated costs were estimated separately per city and pooled to derive national estimates. Results were projected to 2030 (2016–2045) and 2050 (2036–2065). The risk of OIIs and associated costs increased during heatwaves, with the risk increasing during severe and particularly extreme heatwaves. Of all OIIs, 0.13% (95% empirical confidence interval [eCI]: 0.11–0.16%) were heatwave-attributable, equivalent to 120 (95%eCI:70–181) OIIs annually. 0.25% of costs were heatwave-attributable (95%eCI: 0.18–0.34%), equal to $AU4.3 (95%eCI: 1.4–7.4) million annually. Estimates of heatwave-attributable OIIs by 2050, under Representative Concentration Pathway [RCP]4.5 and RCP8.5, were 0.17% (95%eCI: 0.10–0.27%) and 0.23% (95%eCI: 0.13–0.37%), respectively. National costs estimates for 2030 under RCP4.5 and RCP8.5 were 0.13% (95%eCI: 0.27-0.46%) and 0.04% (95%eCI: 0.66-0.60), respectively. These estimates for extreme heatwaves were 0.04% (95%eCI: 0.02–0.06%) and 0.04% (95%eCI: 0.01–0.07), respectively. Cost-AFs in 2050 were, under RCP4.5, 0.127% (95%eCI: 0.27-0.46) for all heatwaves and 0.04% (95%eCI: 0.01-0.09%) for extreme heatwaves. Attributable fractions were approximately similar to baseline when assuming theoretical climate adaptation. Heatwaves represent notable and preventable portions of preventable OIIs and economic burden. OIIs are likely to increase in the future, and costs during extreme heatwaves in 2030. Workplace and public health policies aimed at heat adaptation can reduce heat-attributable morbidity and costs. [Display omitted] • Limited research on expenses from work injuries and illnesses during heatwaves. • Assessment of heatwave-attributable occupational injuries, illnesses and costs. • Increased injuries and illnesses during heatwaves both retrospectively and future. • Costs increased during heatwaves, with some evidence for projected increases. • Climate adaptation can potentially reduce occupational burden. [ABSTRACT FROM AUTHOR]

Published

2023

6. Association between high temperature and heatwaves with heat-related illnesses: A systematic review and meta-analysis.

Author

Faurie, Clare, Varghese, Blesson M., Liu, Jingwen, and Bi, Peng

Published

2022

7. The impact of summer temperatures and heatwaves on mortality and morbidity in Perth, Australia 1994–2008

Author

Williams, Susan, Nitschke, Monika, Weinstein, Philip, Pisaniello, Dino L., Parton, Kevin A., and Bi, Peng

Subjects

*ENVIRONMENTAL impact analysis, *TEMPERATURE effect, *CLIMATE change, *PUBLIC health, *HOSPITAL admission & discharge, *AIR pollution, *NITROGEN dioxide & the environment, *PARTICULATE matter, *ATMOSPHERIC ozone

Abstract

Abstract: Climate change projections have drawn attention to the risks of extreme heat and the importance of public health interventions to minimise the impact. The city of Perth, Western Australia, frequently experiences hot summer conditions, with recent summers showing above average temperatures. Daily maximum and minimum temperatures, mortality, emergency department (ED) presentations and hospital admissions data were acquired for Perth for the period 1994 to 2008. Using an observed/expected analysis, the temperature thresholds for mortality were estimated at 34–36°C (maximum) and 20°C (minimum). Generalised estimating equations (GEEs) were used to estimate the percentage increase in mortality and morbidity outcomes with a 10°C increment in temperature, with adjustment for air pollutants. Effect estimates are reported as incidence rate ratios (IRRs). The health impact of heatwave days (three or more days of ≥35°C) was also investigated. A 9.8% increase in daily mortality (IRR 1.098; 95%CI: 1.007–1.196) was associated with a 10°C increase in maximum temperature above threshold. Total ED presentations increased by 4.4% (IRR 1.044; 95%CI: 1.033–1.054) and renal-related ED presentations by 10.2% (IRR 1.102; 95%CI: 1.071–1.135) per 10°C increase in maximum temperature. Heatwave days were associated with increases in daily mortality and ED presentations, while total hospital admissions were decreased on heatwave days. Public health interventions will be increasingly important to minimise the adverse health impacts of hot weather in Perth, particularly if the recent trend of rising average temperatures and more hot days continues as projected. [Copyright &y& Elsevier]

Published

2012

8. Hot weather as a risk factor for kidney disease outcomes: A systematic review and meta-analysis of epidemiological evidence.

Author

Liu, Jingwen, Varghese, Blesson M., Hansen, Alana, Borg, Matthew A., Zhang, Ying, Driscoll, Timothy, Morgan, Geoffrey, Dear, Keith, Gourley, Michelle, Capon, Anthony, and Bi, Peng

Published

2021

9. Is there an association between hot weather and poor mental health outcomes? A systematic review and meta-analysis.

Author

Liu, Jingwen, Varghese, Blesson M., Hansen, Alana, Xiang, Jianjun, Zhang, Ying, Dear, Keith, Gourley, Michelle, Driscoll, Timothy, Morgan, Geoffrey, Capon, Anthony, and Bi, Peng

Subjects

*HEAT waves (Meteorology), *META-analysis, *NEUROBEHAVIORAL disorders, *HOT weather conditions, *MENTAL health, *SCIENTIFIC literature, *PUBLIC health

Abstract

• Evaluated short-term associations of heat on mental health-related outcomes. • A 2.2% increase in mental health-related mortality per 1 °C rise in temperature. • A 0.9% increase in mental health-related morbidity per 1 °C rise in temperature. • Heatwaves increase the risk of mental health-related outcomes. • Higher risks for elderly, and those living in Tropical and Subtropical climates. Mental health is an important public health issue globally. A potential link between heat exposure and mental health outcomes has been recognised in the scientific literature; however, the associations between heat exposure (both high ambient temperatures and heatwaves) and mental health-related mortality and morbidity vary between studies and locations. To fill gaps in knowledge, this systematic review aims to summarize the epidemiological evidence and investigate the quantitative effects of high ambient temperatures and heatwaves on mental health-related mortality and morbidity outcomes, while exploring sources of heterogeneity. A systematic search of peer-reviewed epidemiological studies on heat exposure and mental health outcomes published between January 1990 and November 2020 was conducted using five databases (PubMed, Embase, Scopus, Web of Science and PsycINFO). We included studies that examined the association between high ambient temperatures and/or heatwaves and mental health-related mortality and morbidity (e.g. hospital admissions and emergency department visits) in the general population. A range of mental health conditions were defined using ICD-10 classifications. We performed random effects meta-analysis to summarize the relative risks (RRs) in mental health outcomes per 1 °C increase in temperature, and under different heatwaves definitions. We further evaluated whether variables such as age, sex, socioeconomic status, and climate zone may explain the observed heterogeneity. The keyword search yielded 4560 citations from which we identified 53 high temperatures/heatwaves studies that comprised over 1.7 million mental health-related mortality and 1.9 million morbidity cases in total. Our findings suggest associations between heat exposures and a range of mental health-related outcomes. Regarding high temperatures, our meta-analysis of study findings showed that for each 1 °C increase in temperature, the mental health-related mortality and morbidity increased with a RR of 1.022 (95%CI: 1.015–1.029) and 1.009 (95%CI: 1.007–1.015), respectively. The greatest mortality risk was attributed to substance-related mental disorders (RR, 1.046; 95%CI: 0.991–1.101), followed by organic mental disorders (RR, 1.033; 95%CI: 1.020–1.046). A 1 °C temperature rise was also associated with a significant increase in morbidity such as mood disorders, organic mental disorders, schizophrenia, neurotic and anxiety disorders. Findings suggest evidence of vulnerability for populations living in tropical and subtropical climate zones, and for people aged more than 65 years. There were significant moderate and high heterogeneities between effect estimates in overall mortality and morbidity categories, respectively. Lower heterogeneity was noted in some subgroups. The magnitude of the effect estimates for heatwaves varied depending on definitions used. The highest effect estimates for mental health-related morbidity was observed when heatwaves were defined as "mean temperature ≥90th percentile for ≥3 days" (RR, 1.753; 95%CI: 0.567–5.421), and a significant effect was also observed when the definition was "mean temperature ≥95th percentile for ≥3 days", with a RR of 1.064 (95%CI: 1.006–1.123). Our findings support the hypothesis of a positive association between elevated ambient temperatures and/or heatwaves and adverse mental health outcomes. This problem will likely increase with a warming climate, especially in the context of climate change. Further high-quality studies are needed to identify modifying factors of heat impacts. [ABSTRACT FROM AUTHOR]

Published

2021

10. Extreme heat and occupational injuries in different climate zones: A systematic review and meta-analysis of epidemiological evidence.

Author

Fatima, Syeda Hira, Rothmore, Paul, Giles, Lynne C., Varghese, Blesson M., and Bi, Peng

Subjects

*HEAT waves (Meteorology), *YOUNG workers, *MARINE west coast climate, *MALE employees, *MEDITERRANEAN climate, *HEAT, *WORK-related injuries

Abstract

• 24 studies assessed the effects of heat exposure on occupational injuries. • Both hot temperatures and heatwaves increase the risk of occupational injuries. • High-risk climate zones include Humid Subtropical and Oceanic Climates. • Young workers and male workers were identified as high-risk workers. • High-risk industries include agriculture, forestry, construction and manufacturing. The link between heat exposure and adverse health outcomes in workers is well documented and a growing body of epidemiological evidence from various countries suggests that extreme heat may also contribute to increased risk of occupational injuries (OI). Previously, there have been no comparative reviews assessing the risk of OI due to extreme heat within a wide range of global climate zones. The present review therefore aims to summarise the existing epidemiological evidence on the impact of extreme heat (hot temperatures and heatwaves (HW)) on OI in different climate zones and to assess the individual risk factors associated with workers and workplace that contribute to heat-associated OI risks. A systematic review of published peer-reviewed articles that assessed the effects of extreme heat on OI among non-military workers was undertaken using three databases (PubMed, Embase and Scopus) without temporal or geographical limits from database inception until July 2020. Extreme heat exposure was assessed in terms of hot temperatures and HW periods. For hot temperatures, the effect estimates were converted to relative risks (RR) associated with 1 °C increase in temperature above reference values, while for HW, effect estimates were RR comparing heatwave with non-heatwave periods. The patterns of heat associated OI risk were investigated in different climate zones (according to Köppen Geiger classification) based on the study locations and were estimated using random-effects meta-analysis models. Subgroup analyses according to workers' characteristics (e.g. gender, age group, experience), nature of work (e.g. physical demands, location of work i.e. indoor/outdoor) and workplace characteristics (e.g. industries, business size) were also conducted. A total of 24 studies published between 2005 and 2020 were included in the review. Among these, 22 studies met the eligibility criteria, representing almost 22 million OI across six countries (Australia, Canada, China, Italy, Spain, and USA) and were included in the meta-analysis. The pooled results suggested that the overall risk of OI increased by 1% (RR 1.010, 95% CI: 1.009–1.011) for 1 °C increase in temperature above reference values and 17.4% (RR 1.174, 95% CI: 1.057–1.291) during HW. Among different climate zones, the highest risk of OI during hot temperatures was identified in Humid Subtropical Climates (RR 1.017, 95% CI: 1.014–1.020) followed by Oceanic (RR 1.010, 95% CI: 1.008–1.012) and Hot Mediterranean Climates (RR 1.009, 95% CI: 1.008–1.011). Similarly, Oceanic (RR 1.218, 95% CI: 1.093–1.343) and Humid Subtropical Climates (RR 1.213, 95% CI: 0.995–1.431) had the highest risk of OI during HW periods. No studies assessing the risk of OI in Tropical regions were found. The effects of hot temperatures on the risk of OI were acute with a lag effect of 1–2 days in all climate zones. Young workers (age < 35 years), male workers and workers in agriculture, forestry or fishing, construction and manufacturing industries were at high risk of OI during hot temperatures. Further young workers (age < 35 years), male workers and those working in electricity, gas and water and manufacturing industries were found to be at high risk of OI during HW. This review strengthens the evidence on the risk of heat-associated OI in different climate zones. The risk of OI associated with extreme heat is not evenly distributed and is dependent on underlying climatic conditions, workers' attributes, the nature of work and workplace characteristics. The differences in the risk of OI across different climate zones and worker subgroups warrant further investigation along with the development of climate and work-specific intervention strategies. [ABSTRACT FROM AUTHOR]

Published

2021