Impacts of petroleum refinery emissions on the health and safety of local residents
,
Abstract
The World Health Organization (WHO) estimates that 25% of mortality in developing countries arises from environmental hazards. Over the years, soaring demand for humanity’s essential needs has prompted industrial-scale production and the generation of large quantities of waste. Petroleum refineries generate large quantities of waste which gives rise to health effects such as cancer, eye defects, birth defects, and reproductive defects. Furthermore, the residents living around refineries encounter several hazards arising from operations that generate noise, radiation, chemicals, vibration, dust and toxic pollutant gases. The current research landscape indicates that Petroleum Refinery Emissions or PREs pose significant risks to human health, safety and the environment. Therefore, this paper presents a concise review of the acute and chronic effects of PREs on the health and safety of residents living within the vicinity of petroleum refineries. The reviewed literature revealed that PREs cause various cancers, leukaemia, as well as cardiovascular, respiratory, and reproduction disorders. Hence, numerous approaches to mitigate, eliminate or address the short and long term effects of PREs have been proposed in the literature. The proposed approaches include the bioremediation as well
as the monitoring and evaluation of PREs to promptly detect, remediate and eliminate the hazards. However, other measures that could help address the outlined occupational health and environmental safety-related issues will go a long way in mitigating or curbing the socio-economic, environmental, health and safety impacts of PREs and industrial wastes.
1. Schwartz J. Air pollution and children’s health.
Pediatrics. 2004;113(Supplement 3):1037-43.
2. Harvey M, Pilgrim S. The new competition
for land: Food, energy, and climate change. Food
policy. 2011;36:S40-S51.
3. Popp J, Lakner Z, Harangi-Rakos M, Fari M. The
effect of bioenergy expansion: Food, energy, and
environment. Renewable and sustainable energy
reviews. 2014;32:559-78.
4. Sutton MA, Bleeker A, Howard C, Erisman J,
Abrol Y, Bekunda M, et al. Our nutrient world. The
challenge to produce more food & energy with less
pollution. Centre for Ecology & Hydrology; 2013.
5. Ladha-Sabur A, Bakalis S, Fryer PJ, LopezQuiroga E. Mapping energy consumption in
food manufacturing. Trends in Food Science &
Technology. 2019;86:270-80.
6. Munsif R, Zubair M, Aziz A, Zafar MN. Industrial
Air Emission Pollution: Potential Sources and
Sustainable Mitigation. Environmental Emissions:
IntechOpen; 2021. IntechOpen.
7. Nyakuma BB, Ivase TJ-P. Emerging trends in
sustainable treatment and valorisation technologies
for plastic wastes in Nigeria: A concise review.
Environmental Progress & Sustainable Energy.
2021:e13660.
8. Otitolaiye VO. The mediating effect of safety
management system on the relationship between
safety culture and safety performance in Lagos food
and beverage manufacturing industries (Doctoral
dissertation, Universiti Utara Malaysia). 2016.
9. El-Houjeiri HM, Brandt AR, Duffy JE. Opensource LCA tool for estimating greenhouse
gas emissions from crude oil production using
field characteristics. Environmental science &
technology. 2013;47(11):5998-6006.
10. Allen DT, Cardoso-Saldaña FJ, Kimura Y.
Variability in spatially and temporally resolved
emissions and hydrocarbon source fingerprints
for oil and gas sources in shale gas production
regions. Environmental Science & Technology.
2017;51(20):12016-26.
11. Chen Q, Dunn JB, Allen DT. Aggregation and
allocation of greenhouse gas emissions in oil and gas
production: Implications for life-cycle greenhouse
gas burdens. ACS Sustainable Chemistry &
Engineering. 2019;7(20):17065-73.
12. Speight JG. Handbook of offshore oil and gas
operations: Elsevier; 2014.
13. Devold H. Oil and gas production handbook: an
introduction to oil and gas production: Lulu. com;
2013.
14. Nyakuma BB, Ivase TJP. Emerging trends in
sustainable treatment and valorisation technologies
for plastic wastes in Nigeria: A concise review.
Environmental Progress & Sustainable Energy.
2021;40(5):e13660.
15. Sharma A, Sharma P, Sharma A, Tyagi R, Dixit
A. Hazardous Effects of Petrochemical Industries:
A. petrochemical technology. 2017;13(3):1-7.
16. Lyons WC, Plisga GJ. Standard handbook of
petroleum and natural gas engineering: Elsevier;
2011.
17. Feng Y, Xiao A, Jia R, Zhu S, Gao S, Li B,
et al. Emission characteristics and associated
assessment of volatile organic compounds from
process units in a refinery. Environmental Pollution.
2020;265:115026.
18. Marquès M, Domingo JL, Nadal M,
Schuhmacher M. Health risks for the population
living near petrochemical industrial complexes. 2.
Adverse health outcomes other than cancer. Science
of the total environment. 2020;730:139122.
19. Pascal M, Pascal L, Bidondo M-L, Cochet
A, Sarter H, Stempfelet M, et al. A review of the
epidemiological methods used to investigate
the health impacts of air pollution around major
industrial areas. Journal of environmental and public health. 2013;2013.
20. Luginaah IN, Taylor SM, Elliott SJ, Eyles JD.
A longitudinal study of the health impacts of a
petroleum refinery. Social science & medicine.
2000;50(7-8):1155-66.
21. Spitzer W, Dales R, Schechter M, Suissa S,
Tousignant P, Steinmetz N, et al. Chronic exposure
to sour gas emissions: meeting a community concern
with epidemiologic evidence. CMAJ: Canadian
Medical Association Journal. 1989;141(7):685.
22. Neutra R, Lipscomb J, Satin K, Shusterman
D. Hypotheses to explain the higher symptom
rates observed around hazardous waste sites.
Environmental Health Perspectives. 1991;94:31-8.
23. Brender JD, Maantay JA, Chakraborty J.
Residential proximity to environmental hazards
and adverse health outcomes. American journal of
public health. 2011;101(S1):S37-S52.
24. US-EPA. 2013 GHGRP Industrial Profiles
United States of America: US-Environmental
Protection Agency; 2021 [Available from: https://
bit.ly/3mtGldH.
25. Mcilvaine C. Refinery Process Air Emissions
United States: The Mcilvaine Company; 2021
[Available from: https://bit.ly/3sHoYY1.
26. WHO. Chronic respiratory diseases Geneva,
switzerland: World Health Organisation; 2021
[Available from: https://bit.ly/3z7uGoj.
27. San Sebastián M, Armstrong B, Córdoba JA,
Stephens C. Exposures and cancer incidence near oil
fields in the Amazon basin of Ecuador. Occupational
and environmental medicine. 2001;58(8):517-22.
28. Luginaah IN, Martin Taylor S, Elliott SJ, Eyles
JD. Community reappraisal of the perceived health
effects of a petroleum refinery. Social Science &
Medicine. 2002;55( 1):47-61.
29. Cetin E, Odabasi M, Seyfioglu R. Ambient
volatile organic compound (VOC) concentrations
around a petrochemical complex and a petroleum
refinery. Science of The Total Environment.
2003;312(1):103-12.
30. Lin T-Y, Sree U, Tseng S-H, Chiu KH, Wu C-H,
Lo J-G. Volatile organic compound concentrations
in ambient air of Kaohsiung petroleum
refinery in Taiwan. Atmospheric Environment.
2004;38(25):4111-22.
31. Yang C-Y, Chang C-C, Chuang H-Y, Ho C-K,
Wu T-N, Chang P-Y. Increased risk of preterm
delivery among people living near the three oil
refineries in Taiwan. Environment International.
2004;30(3):337-42.
32. Butler K, Fekete G, editors. Measuring
compliance program progress and impacts: Lessons
from USEPA’s National Petroleum Refinery
Compliance Program’. Seventh International
Conference on Environmental Compliance and
Enforcement; 2005: Citeseer.
33. Yu C-L, Wang S-F, Pan P-C, Wu M-T, Ho
C-K, Smith TJ, et al. Residential exposure to
petrochemicals and the risk of leukemia: using
geographic information system tools to estimate
individual-level residential exposure. American
journal of epidemiology. 2006;164(3):200-7.
34. Chuma P. Biosorption of Cr, Mn, Fe, Ni, Cu
and Pb metals from petroleum refinery effluent by
calcium alginate immobilized mycelia of Polyporus
squamosus. Scientific Research and Essays.
2007;2(7):217-21.
35. Rao PS, Ansari MF, Pipalatkar P, Kumar A,
Nema P, Devotta S. Measurement of particulate
phase polycyclic aromatic hydrocarbon (PAHs)
around a petroleum refinery. Environmental
Monitoring and Assessment. 2007;137(1):387.
36. Kim YJ, Choi JY, Paek D, Chung HW.
Association of the NQO1, MPO, and XRCC1
polymorphisms and chromosome damage among
workers at a petroleum refinery. Journal of
Toxicology and Environmental Health, Part A.
2008;71(5):333-41.
37. Hoshina MM, Marin-Morales MA.
Micronucleus and chromosome aberrations
induced in onion (Allium cepa) by a petroleum
refinery effluent and by river water that receives this
effluent. Ecotoxicology and Environmental Safety.
2009;72(8):2090-5.
38. Simonsen N, Scribner R, Su LJ, Williams D,
Luckett B, Yang T, et al. Environmental exposure to
emissions from petrochemical sites and lung cancer:
the lower Mississippi interagency cancer study. Journal
of environmental and public health. 2010;2010.
39. D’Andrea MA, Singh O, Reddy GK. Health
consequences of involuntary exposure to benzene
following a flaring incident at British Petroleum
refinery in Texas City. American journal of disaster
medicine. 2013;8(3):169-79.
40. Rovira E, Cuadras A, Aguilar X, Esteban L,
Borràs-Santos A, Zock J-P, et al. Asthma, respiratory
symptoms and lung function in children living
near a petrochemical site. Environmental research.
2014;133:156-63.
41. Smargiassi A, Goldberg MS, Wheeler AJ,
Plante C, Valois M-F, Mallach G, et al. Associations
between personal exposure to air pollutants and lung
function tests and cardiovascular indices among
children with asthma living near an industrial
complex and petroleum refineries. Environmental
research. 2014;132:38-45.
42. Montaño Soto MT, Garza Ocañas L. Health
effects due to exposure to polycyclic aromatic
hydrocarbons from the petroleum reining industry.
Medicina universitaria. 2014;16(64):136-40.
43. Caruso JA, Zhang K, Schroeck NJ, McCoy
B, McElmurry SP. Petroleum Coke in the Urban
Environment: A Review of Potential Health Effects.
International Journal of Environmental Research
and Public Health. 2015;12(6):6218-31.
44. Meo SA, Alrashed AH, Almana AA, Altheiban
YI, Aldosari MS, Almudarra NF, et al. Lung function
and fractional exhaled nitric oxide among petroleum
refinery workers. Journal of Occupational Medicine
and Toxicology. 2015;10(1):1-5.
45. Edokpolo B, Yu QJ, Connell D. Health Risk
Assessment for Exposure to Benzene in Petroleum
Refinery Environments. International Journal
of Environmental Research and Public Health.
2015;12(1):595-610.
46. D’Andrea MA, Reddy GK. Adverse health
effects of benzene exposure among children
following a flaring incident at the British Petroleum
Refinery in Texas City. Clinical pediatrics.
2016;55(3):219-27.
47. D’Andrea MA, Reddy GK. Detrimental health
effects of benzene exposure in adults after a flaring
disaster at the BP refinery plant in Texas City.
Disaster medicine and public health preparedness.
2016;10(2):233-9.
48. Lin C-K, Hung H-Y, Christiani DC, Forastiere
F, Lin R-T. Lung cancer mortality of residents living
near petrochemical industrial complexes: a metaanalysis. Environmental Health. 2017;16(1):1-11.
49. Varjani SJ, Gnansounou E, Pandey A.
Comprehensive review on toxicity of persistent
organic pollutants from petroleum refinery
waste and their degradation by microorganisms.
Chemosphere. 2017;188:280-91.
50. Ali MM, Zhao H, Li Z, Maglas NN.
Concentrations of TENORMs in the petroleum
industry and their environmental and health effects.
RSC Advances. 2019;9(67):39201-29.
51. Nowak P, Kucharska K, Kamiński M. Ecological
and health effects of lubricant oils emitted into the
environment. International journal of environmental
research and public health. 2019;16(16):3002.
52. Laurelta T-A, Ernest A. Toxicological Effects
of Petroleum Refinery Sludge on the Terrestial
Environment Using Bacteria and Earthworm as Bio
Indicators. Journal of Advances in Microbiology.
2020:30-40.
53. Hosseininejad M, Mirzamohammadi E,
Mohsenizadeh SA, Mohammadi S. The relationship
between occupational exposure to organic solvents
and metabolic syndrome in petroleum refinery
workers in Tehran, Iran. Diabetes & Metabolic
Syndrome: Clinical Research & Reviews.
2021;15(5):102223.
54. Lv D, Lu S, Tan X, Shao M, Xie S, Wang L.
Source profiles, emission factors and associated
contributions to secondary pollution of volatile
organic compounds (VOCs) emitted from a local
petroleum refinery in Shandong. Environmental
Pollution. 2021;274:116589
Pediatrics. 2004;113(Supplement 3):1037-43.
2. Harvey M, Pilgrim S. The new competition
for land: Food, energy, and climate change. Food
policy. 2011;36:S40-S51.
3. Popp J, Lakner Z, Harangi-Rakos M, Fari M. The
effect of bioenergy expansion: Food, energy, and
environment. Renewable and sustainable energy
reviews. 2014;32:559-78.
4. Sutton MA, Bleeker A, Howard C, Erisman J,
Abrol Y, Bekunda M, et al. Our nutrient world. The
challenge to produce more food & energy with less
pollution. Centre for Ecology & Hydrology; 2013.
5. Ladha-Sabur A, Bakalis S, Fryer PJ, LopezQuiroga E. Mapping energy consumption in
food manufacturing. Trends in Food Science &
Technology. 2019;86:270-80.
6. Munsif R, Zubair M, Aziz A, Zafar MN. Industrial
Air Emission Pollution: Potential Sources and
Sustainable Mitigation. Environmental Emissions:
IntechOpen; 2021. IntechOpen.
7. Nyakuma BB, Ivase TJ-P. Emerging trends in
sustainable treatment and valorisation technologies
for plastic wastes in Nigeria: A concise review.
Environmental Progress & Sustainable Energy.
2021:e13660.
8. Otitolaiye VO. The mediating effect of safety
management system on the relationship between
safety culture and safety performance in Lagos food
and beverage manufacturing industries (Doctoral
dissertation, Universiti Utara Malaysia). 2016.
9. El-Houjeiri HM, Brandt AR, Duffy JE. Opensource LCA tool for estimating greenhouse
gas emissions from crude oil production using
field characteristics. Environmental science &
technology. 2013;47(11):5998-6006.
10. Allen DT, Cardoso-Saldaña FJ, Kimura Y.
Variability in spatially and temporally resolved
emissions and hydrocarbon source fingerprints
for oil and gas sources in shale gas production
regions. Environmental Science & Technology.
2017;51(20):12016-26.
11. Chen Q, Dunn JB, Allen DT. Aggregation and
allocation of greenhouse gas emissions in oil and gas
production: Implications for life-cycle greenhouse
gas burdens. ACS Sustainable Chemistry &
Engineering. 2019;7(20):17065-73.
12. Speight JG. Handbook of offshore oil and gas
operations: Elsevier; 2014.
13. Devold H. Oil and gas production handbook: an
introduction to oil and gas production: Lulu. com;
2013.
14. Nyakuma BB, Ivase TJP. Emerging trends in
sustainable treatment and valorisation technologies
for plastic wastes in Nigeria: A concise review.
Environmental Progress & Sustainable Energy.
2021;40(5):e13660.
15. Sharma A, Sharma P, Sharma A, Tyagi R, Dixit
A. Hazardous Effects of Petrochemical Industries:
A. petrochemical technology. 2017;13(3):1-7.
16. Lyons WC, Plisga GJ. Standard handbook of
petroleum and natural gas engineering: Elsevier;
2011.
17. Feng Y, Xiao A, Jia R, Zhu S, Gao S, Li B,
et al. Emission characteristics and associated
assessment of volatile organic compounds from
process units in a refinery. Environmental Pollution.
2020;265:115026.
18. Marquès M, Domingo JL, Nadal M,
Schuhmacher M. Health risks for the population
living near petrochemical industrial complexes. 2.
Adverse health outcomes other than cancer. Science
of the total environment. 2020;730:139122.
19. Pascal M, Pascal L, Bidondo M-L, Cochet
A, Sarter H, Stempfelet M, et al. A review of the
epidemiological methods used to investigate
the health impacts of air pollution around major
industrial areas. Journal of environmental and public health. 2013;2013.
20. Luginaah IN, Taylor SM, Elliott SJ, Eyles JD.
A longitudinal study of the health impacts of a
petroleum refinery. Social science & medicine.
2000;50(7-8):1155-66.
21. Spitzer W, Dales R, Schechter M, Suissa S,
Tousignant P, Steinmetz N, et al. Chronic exposure
to sour gas emissions: meeting a community concern
with epidemiologic evidence. CMAJ: Canadian
Medical Association Journal. 1989;141(7):685.
22. Neutra R, Lipscomb J, Satin K, Shusterman
D. Hypotheses to explain the higher symptom
rates observed around hazardous waste sites.
Environmental Health Perspectives. 1991;94:31-8.
23. Brender JD, Maantay JA, Chakraborty J.
Residential proximity to environmental hazards
and adverse health outcomes. American journal of
public health. 2011;101(S1):S37-S52.
24. US-EPA. 2013 GHGRP Industrial Profiles
United States of America: US-Environmental
Protection Agency; 2021 [Available from: https://
bit.ly/3mtGldH.
25. Mcilvaine C. Refinery Process Air Emissions
United States: The Mcilvaine Company; 2021
[Available from: https://bit.ly/3sHoYY1.
26. WHO. Chronic respiratory diseases Geneva,
switzerland: World Health Organisation; 2021
[Available from: https://bit.ly/3z7uGoj.
27. San Sebastián M, Armstrong B, Córdoba JA,
Stephens C. Exposures and cancer incidence near oil
fields in the Amazon basin of Ecuador. Occupational
and environmental medicine. 2001;58(8):517-22.
28. Luginaah IN, Martin Taylor S, Elliott SJ, Eyles
JD. Community reappraisal of the perceived health
effects of a petroleum refinery. Social Science &
Medicine. 2002;55( 1):47-61.
29. Cetin E, Odabasi M, Seyfioglu R. Ambient
volatile organic compound (VOC) concentrations
around a petrochemical complex and a petroleum
refinery. Science of The Total Environment.
2003;312(1):103-12.
30. Lin T-Y, Sree U, Tseng S-H, Chiu KH, Wu C-H,
Lo J-G. Volatile organic compound concentrations
in ambient air of Kaohsiung petroleum
refinery in Taiwan. Atmospheric Environment.
2004;38(25):4111-22.
31. Yang C-Y, Chang C-C, Chuang H-Y, Ho C-K,
Wu T-N, Chang P-Y. Increased risk of preterm
delivery among people living near the three oil
refineries in Taiwan. Environment International.
2004;30(3):337-42.
32. Butler K, Fekete G, editors. Measuring
compliance program progress and impacts: Lessons
from USEPA’s National Petroleum Refinery
Compliance Program’. Seventh International
Conference on Environmental Compliance and
Enforcement; 2005: Citeseer.
33. Yu C-L, Wang S-F, Pan P-C, Wu M-T, Ho
C-K, Smith TJ, et al. Residential exposure to
petrochemicals and the risk of leukemia: using
geographic information system tools to estimate
individual-level residential exposure. American
journal of epidemiology. 2006;164(3):200-7.
34. Chuma P. Biosorption of Cr, Mn, Fe, Ni, Cu
and Pb metals from petroleum refinery effluent by
calcium alginate immobilized mycelia of Polyporus
squamosus. Scientific Research and Essays.
2007;2(7):217-21.
35. Rao PS, Ansari MF, Pipalatkar P, Kumar A,
Nema P, Devotta S. Measurement of particulate
phase polycyclic aromatic hydrocarbon (PAHs)
around a petroleum refinery. Environmental
Monitoring and Assessment. 2007;137(1):387.
36. Kim YJ, Choi JY, Paek D, Chung HW.
Association of the NQO1, MPO, and XRCC1
polymorphisms and chromosome damage among
workers at a petroleum refinery. Journal of
Toxicology and Environmental Health, Part A.
2008;71(5):333-41.
37. Hoshina MM, Marin-Morales MA.
Micronucleus and chromosome aberrations
induced in onion (Allium cepa) by a petroleum
refinery effluent and by river water that receives this
effluent. Ecotoxicology and Environmental Safety.
2009;72(8):2090-5.
38. Simonsen N, Scribner R, Su LJ, Williams D,
Luckett B, Yang T, et al. Environmental exposure to
emissions from petrochemical sites and lung cancer:
the lower Mississippi interagency cancer study. Journal
of environmental and public health. 2010;2010.
39. D’Andrea MA, Singh O, Reddy GK. Health
consequences of involuntary exposure to benzene
following a flaring incident at British Petroleum
refinery in Texas City. American journal of disaster
medicine. 2013;8(3):169-79.
40. Rovira E, Cuadras A, Aguilar X, Esteban L,
Borràs-Santos A, Zock J-P, et al. Asthma, respiratory
symptoms and lung function in children living
near a petrochemical site. Environmental research.
2014;133:156-63.
41. Smargiassi A, Goldberg MS, Wheeler AJ,
Plante C, Valois M-F, Mallach G, et al. Associations
between personal exposure to air pollutants and lung
function tests and cardiovascular indices among
children with asthma living near an industrial
complex and petroleum refineries. Environmental
research. 2014;132:38-45.
42. Montaño Soto MT, Garza Ocañas L. Health
effects due to exposure to polycyclic aromatic
hydrocarbons from the petroleum reining industry.
Medicina universitaria. 2014;16(64):136-40.
43. Caruso JA, Zhang K, Schroeck NJ, McCoy
B, McElmurry SP. Petroleum Coke in the Urban
Environment: A Review of Potential Health Effects.
International Journal of Environmental Research
and Public Health. 2015;12(6):6218-31.
44. Meo SA, Alrashed AH, Almana AA, Altheiban
YI, Aldosari MS, Almudarra NF, et al. Lung function
and fractional exhaled nitric oxide among petroleum
refinery workers. Journal of Occupational Medicine
and Toxicology. 2015;10(1):1-5.
45. Edokpolo B, Yu QJ, Connell D. Health Risk
Assessment for Exposure to Benzene in Petroleum
Refinery Environments. International Journal
of Environmental Research and Public Health.
2015;12(1):595-610.
46. D’Andrea MA, Reddy GK. Adverse health
effects of benzene exposure among children
following a flaring incident at the British Petroleum
Refinery in Texas City. Clinical pediatrics.
2016;55(3):219-27.
47. D’Andrea MA, Reddy GK. Detrimental health
effects of benzene exposure in adults after a flaring
disaster at the BP refinery plant in Texas City.
Disaster medicine and public health preparedness.
2016;10(2):233-9.
48. Lin C-K, Hung H-Y, Christiani DC, Forastiere
F, Lin R-T. Lung cancer mortality of residents living
near petrochemical industrial complexes: a metaanalysis. Environmental Health. 2017;16(1):1-11.
49. Varjani SJ, Gnansounou E, Pandey A.
Comprehensive review on toxicity of persistent
organic pollutants from petroleum refinery
waste and their degradation by microorganisms.
Chemosphere. 2017;188:280-91.
50. Ali MM, Zhao H, Li Z, Maglas NN.
Concentrations of TENORMs in the petroleum
industry and their environmental and health effects.
RSC Advances. 2019;9(67):39201-29.
51. Nowak P, Kucharska K, Kamiński M. Ecological
and health effects of lubricant oils emitted into the
environment. International journal of environmental
research and public health. 2019;16(16):3002.
52. Laurelta T-A, Ernest A. Toxicological Effects
of Petroleum Refinery Sludge on the Terrestial
Environment Using Bacteria and Earthworm as Bio
Indicators. Journal of Advances in Microbiology.
2020:30-40.
53. Hosseininejad M, Mirzamohammadi E,
Mohsenizadeh SA, Mohammadi S. The relationship
between occupational exposure to organic solvents
and metabolic syndrome in petroleum refinery
workers in Tehran, Iran. Diabetes & Metabolic
Syndrome: Clinical Research & Reviews.
2021;15(5):102223.
54. Lv D, Lu S, Tan X, Shao M, Xie S, Wang L.
Source profiles, emission factors and associated
contributions to secondary pollution of volatile
organic compounds (VOCs) emitted from a local
petroleum refinery in Shandong. Environmental
Pollution. 2021;274:116589
| Files | ||
| Issue | Vol 7 No 1 (2022): Winter 2022 | |
| Section | Review Article(s) | |
| DOI | https://doi.org/10.18502/japh.v7i1.8921 | |
| Keywords | ||
| Refinery residents; Acute health effects; Petroleum refinery emissions (PREs); Toxic hazards | ||
| Rights and permissions | |
|
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. |
How to Cite
1.
Otitolaiye VO, Al-Harethiya GM. Impacts of petroleum refinery emissions on the health and safety of local residents. JAPH. 2022;7(1):69-80.
