Oil Refinery Release of Pollutants in Human and Animal Health: The Case of Priolo (Eastern Sicily) Oil Refinery

Abstract

Oil refineries have been investigated in several studies focused on soil and water pollution in proximity of refinery plants, as we reported recently for the Augusta-Priolo area (Eastern Sicily). The present study is aimed at evaluating the effects on human and animal health related to residence nearby refinery plants.

Material and Methods: A literature search was effected in PubMed, and in our previous archives combining “oil refinery”, “health” and “disease”, building an overall database.

Results: Multiple evidence was found related to residence nearby oil refineries, or occupational exposure and affecting human health, including genetic defects and cancer. Further literature was found relating the exposure to oil refinery pollution vs. multiple adverse effects in several biota, including animals along with other exposed biota.

Keywords

Oil refinery; Soil/water pollution; Health effects; Animal toxicity; Multiple biota

Introduction

Several forms of environmental pollution have been associated to oil refineries and proximate topsoil in a number of locations in Europe, Asia and America [1-8]. We have previously investigated the soil pollution endpoints in Augusta-Priolo (South East Sicily) oil refinery area, along to a previous recent report focused on marine sediment [7-9]. Inorganic analysis of topsoil was both carried for 23 metals and 16 Rare Earth Elements (REEs), which are recognized additives in oil refining additives [6,8]. Organic analyses were focused on polycyclic aromatic hydrocarbons [8,9] and total aliphatic hydrocarbons. Topsoil samples were tested for toxicity in several bioassay models, and samples collected at sites closest to petrochemical facilities suggested their contributions to topsoil environmental toxicity.

Beyond experimental toxicity testing, the present mini-review is aimed at evaluating the literature database focused on the association of oil refinery plants with human health (Figure 1), and the literature associating oil refineries with adverse effects on animal health and on a number of other biota as plants and microorganisms.

Figure 1: Augusta-Priolo oil refinery plant.

Oil refineries and human health effects

The residential or occupational exposures to the environmental pollution associated to oil refineries have been investigated in a number of epidemiological studies as summarized in Table 1.

The data were obtained from childhood severe health effects such as congenital malformations, following children or maternal residence close to a number of oil refineries across a number of locations including Sicily, Saudi Arabia, Jordan, Iran, rural Colorado, Serbia, China and Taiwan [1,2,4-6,9-11,16,17,19,22,23]. Altogether, this database testifies a general association of residential exposures to oil refineries with severe health outcomes in children and newborns. Another body of evidence may be assessed on occupational exposure in oil refineries and gas processing plants, as reported in set of extensive reviews and the occurrence of cancer and leukemias [3,14,24]. Altogether, several exposures to oil refineries can be assessed as etiologic sources of severe effects to human health.

Table 1. Reports on associations of oil refining plants with human health.

Associations of oil refineries with adverse effects in several biota

A more limited database is available focused on the adverse effects associated with oil refineries in a number of biota, namely animals, plants and microbial models, as summarized in Table 2.

Tested animals included watchdogs dwelling in oil refineries, and rodent models either submitted to pregnancy exposure or to inhalation of diesel emissions [25-27]. The results showed increased hydrocarbon bioaccumulation in blood and hair samples, adverse reproductive and developmental health outcomes, and adverse pulmonary and systemic effects of inhaled diesel emissions with cerium oxide fuel additive. Further data were reported in a tadpole model exposed to oil refinery and gas extraction [27]. Among other biota models, other adverse effects were reported in a microbial model, and in a review of Plant Health Index [29,30].

Open questions and need of further investigations

The established body of evidence associating residential or occupational in oil refinery facilities to adverse human health effects (Table 1), along with the circumstantial data relating analogous effects in dogs and rats [25,27] altogether raise the rationale for undertaking from this investigation focused on animal adverse health effects. In the frame of our study of the Augusta-Priolo oil refineries, an image of a sheep yard approached the Priolo refinery (Figure 2) should provide a well-based ground towards veterinary investigations [8,31].

Figure 2: Sheep living nearby priolo oil refinery.

Table 2. Database on associations of oil refineries in several biota (animal, plant and microbial models).

Conclusion

We consider this technique described to be a sufficient and safe novel surgical option when conservative therapy proves insufficient. This validated and established procedure in humans has now been successfully adapted for equine medicine allowing sustainable treatment of cervical radiculopathy caused by foraminal stenosis.

References

1. Di Leonardo R, et al. Highly contaminated areas as sources of pollution for adjoining ecosystems: The case of Augusta Bay (Central Mediterranean Mar Pollut Bull. 2014;89:417-426.

   [Crossref][Google Scholar][Pubmed]

2. El-Taher A, et al. Environmental impacts of heavy metals, rare earth elements and natural radionuclides in marine sediment from Ras Tanura, Saudi Arabia along the Arabian Gulf. Appl Radiat Isot. 2018;132:95-104.

   [Crossref][Google Scholar][Pubmed]

3. Fox JL, et al. A narrative review of health status and healthcare delivery in the oil and gas industry: Impacts on employees, employers, and local communities. Healthcare (Basel). 2023;11:2888.

   [Crossref][Google Scholar][Pubmed]

4. Gao P, et al. Bioaccessiblity and exposure assessment of PM (2.5)- and PM(10)-bound rare earth elements in Oil City, Northeast China. J Hazard Mater. 2020;396:122520.

   [Crossref][Google Scholar][Pubmed]

5. Li J, et al. Distribution of heavy metals in agricultural soils near a petrochemical complex in Guangzhou, China. Environ Monitor Assess. 2009;153:365-375.

   [Crossref][Google Scholar][Pubmed]

6. Naraki H, et al. Urban street dust in the Middle East oldest oil refinery zone: Oxidative potential, source apportionment and health risk assessment of potentially toxic elements. Chemosphere. 2021;268:128825.

   [Crossref][Google Scholar][Pubmed]

7. Romano E, et al. Measuring anthropogenic impacts on an industrialised coastal marine area using chemical and textural signatures in sediments: A case study of Augusta Harbour (Sicily, Italy). Sci Total Environ. 2021; 755:42683.

   [Crossref][Google Scholar][Pubmed]

8. Tommasi F, et al. Geospatial pattern of topsoil pollution and multi-endpoint toxicity in the petrochemical area of Augusta-Priolo (eastern Sicily, Italy). Chemosphere. 2023;333:138802.

   [Crossref][Google Scholar][Pubmed]

9. Wang D, et al. Distribution, origins and hazardous effects of polycyclic aromatic hydrocarbons in topsoil surrounding oil fields: A case study on the Loess Plateau, China. Int J Environ Res Public Health. 2020;17:1390.

   [Crossref][Google Scholar][Pubmed]

10. Bianchi F, et al. Congenital malformations in newborns residing in the municipality of Gela (Sicily, Italy). Epidemiol Prev. 2006;30:19-26.

    [Google Scholar][Pubmed]

11. Cernigliaro A, et al. The epidemiological surveillance in the programme of public health intervention in the national priority contaminated sites of Sicily Region (Southern Italy): Update of mortality, hospitalization, and cancer incidence. Epidemiol Prev. 2019;43:132-143.

    [Crossref][Google Scholar][Pubmed]

12. Khatatbeh M, et al. Adverse health impacts of living near an oil refinery in Jordan. Environ Health Insights. 2020;14.

    [Crossref][Google Scholar][Pubmed]

13. Deziel NC, et al. Unconventional oil and gas development and health outcomes: A scoping review of the epidemiological research. Environ Res. 2020;182:109124.

    [Crossref][Google Scholar][Pubmed]

14. Kafaei R, et al. Metal(loid)s urinary level among workers of gas refinery and petrochemical companies: Health risk assessment of metal(loid)s in drinking water and dust. J Trace Elem Med Biol. 2019;54:183-190.

    [Crossref][Google Scholar][Pubmed]

15. Lin CK, et al. Residential exposure to petrochemical industrial complexes and the risk of leukemia: A systematic review and exposure-response meta-analysis. Environ Pollut. 2019;22:113476.

    [Crossref][Google Scholar][Pubmed]

16. McKenzie LM, et al. Childhood hematologic cancer and residential proximity to oil and gas development. PLoS One. 2017;12:e0170423.

    [Crossref][Google Scholar][Pubmed]

17. Onyije FM, et al. Cancer incidence and mortality among petroleum industry workers and residents living in oil producing communities: A systematic review and meta-analysis. Int J Environ Res Public Health. 2021;18:4343.

    [Crossref][Google Scholar][Pubmed]

18. Pagano G, et al. Human exposures to rare earth elements: Present knowledge and research prospects. Environ Res. 2019;171:493-500.

    [Crossref][Google Scholar][Pubmed]

19. Relić D, et al. Pollution and health risk assessments of potentially toxic elements in soil and sediment samples in a petrochemical industry and surrounding area. Molecules. 2019;24:E2139.

    [Crossref][Google Scholar][Pubmed]

20. Webb E, et al. Potential hazards of air pollutant emissions from unconventional oil and natural gas operations on the respiratory health of children and infants. Rev Environ Health. 2016;31:225-243.

    [Crossref][Google Scholar][Pubmed]

21. Weng HH, et al. Association of childhood leukemia with residential exposure to petrochemical air pollution in Taiwan. Inhal Toxicol. 2008;20:31-36.

    [Crossref][Google Scholar][Pubmed]

22. Yuan TH, et al. Increased cancers among residents living in the neighborhood of a petrochemical complex: A 12-year retrospective cohort study. Int J Hyg Environ Health. 2018;221:308-314.

    [Crossref][Google Scholar][Pubmed]

23. Di Bella C, et al. Heavy metals and PAHs in meat, milk, and seafood from Augusta area (Southern Italy): Contamination levels, dietary intake, and human exposure assessment. Front Public Health. 2020;8:273.

    [Crossref][Google Scholar][Pubmed]

24. Snow SJ, et al. Inhaled diesel emissions generated with Cerium oxide nanoparticle fuel additive induce adverse pulmonary and systemic effects. Toxicol Sci. 2014;142:403-417.

    [Crossref][Google Scholar][Pubmed]

25. Gberindyer FA, et al. Potentially toxic metals in dust, blood, and hairs from exposed security dogs in an oil and gas industry. Vet Ital. 2022;58.

    [Crossref][Google Scholar][Pubmed]

26. Kassotis CD, et al. Adverse reproductive and developmental health outcomes following prenatal exposure to a hydraulic fracturing chemical mixture in female C57Bl/6 mice. Endocrinology 2016;157:3469-3481.

    [Crossreff][Google Scholar][Pubmed]

27. Snow SJ, et al. Inhaled diesel emissions generated with cerium oxide nanoparticle fuel additive induce adverse pulmonary and systemic effects. Toxicol Sci. 2014;142:403-417.

    [Crossref][Google Scholar][Pubmed]

28. Robert J, et al. Water contaminants associated with unconventional oil and gas extraction cause immunotoxicity to amphibian tadpoles. Toxicol Sci. 2018;166:39-50.

    [Crossref][Google Scholar][Pubmed]

29. Siddiqui Z, et al. Degradation of alkane hydrocarbons by Priestia megaterium ZS16 and sediments consortia with special reference to toxicity and oxidative stress induced by the sediments in the vicinity of an oil refinery. Chemosphere. 2023;317:137886.

    [Crossref][Google Scholar][Pubmed]

30. Al-Anzi FS, et al. Plant health index as an anomaly detection tool for oil refinery processes. Sci Rep. 2022; 12:14477.

    [Crossref][Google Scholar][Pubmed]

31. Calderon JL, et al. Managing upstream oil and gas emissions: A public health oriented approach. J Environ Manage. 2022;310:114766.

    [Crossref][Google Scholar][Pubmed]