by Will Burke

Figure 1: Ring net offshore aquaculture. Image: Asc1733, CC BY-SA 4.0 <https://creativecommons.org/licenses/by-sa/4.0>, via Wikimedia Commons.

A decade ago aquaculture – fish and aquatic plant farming [1] – surpassed capture as the primary source of global seafood [2] with the production rate now exceeding 110 million tonnes per year [3]. Aquaculture is therefore becoming increasingly important for both global food security [4] and the economies of several nations [5-7]. This growing reliance on aquaculture has intensified research in several areas including microplastics [8], escape [9], and production improvements [10], however, a recent paper from the Sylhet Agricultural University Bangladesh has considered the prevalence of industry substances alongside their impacts on not only fish but farmers, consumers, and the environment too [11].

The study focused on Narsingdi, Bangladesh given the nation’s aquaculture efforts – Bangladesh ranks as the world’s 5^th aquaculture producer by ton [3], and exports to over 50 countries [12], giving the quality of their fish international importance – alongside limited existing research on the Narsingdi district [11]. The study identified various substances used in Narsingdi aquaculture, and alarmingly haphazard antimicrobial and chemical use which could negatively impact future aquaculture and human health [11].

The potential implications for future aquaculture and the wider environment were discussed, with the risk of fish developing antibiotic resistance through antibiotic misuse carefully considered [11]. In these cases, bacteria can becomes resistant to treatment, increasing fish vulnerability to illness [13, 14], reducing yields [15] which could increase prices and lower food security through reduced economic access. The inappropriate use of chemicals due to limited understanding, poor regulation, and incorrect application [11] is also a cause for concern as some contribute to increased mortality for non – target species –  such as crustaceans [16] – which are vital to food chain stability [17], while others – like chlorine [11] – deal significant damage to the local environment through soil pollution [18], reducing agricultural opportunities [19], further limiting food security.

The human implications of the findings were also considered by linking aquaculture substances to potential health complications [11]. It was found that some substances remain in the food system via exposure pathways, potentially impacting farmers, handlers, and consumers [11]. Through a literature review, specific impacts were explored. Antimicrobial agents were linked to human antibiotic resistance, potentially reducing treatment efficacy, disinfectants to cancer, and pesticides to heart failure, cancer, and hypertension [11]. Alongside general well-being impacts, poor health can also reduce productivity [20], potentially further reducing food security through lower aquaculture outputs.

Aquaculture is increasingly important to food security, from the local [21] to the global [4, 12] scale. It must however pivot to more sustainable approaches – as spearheaded by nations like China through their increasing use of organic aquaculture [22], which offers reduced pesticide and antibiotic use compared to current approaches [23]  – maintaining productivity without risking future aquaculture efforts or the health of people and places throughout the global food system.

Reference List:

1. NOS (2023) What is aquaculture? https://oceanservice.noaa.gov/facts/aquaculture.html#:~:text=Aquaculture%20is%20breeding%2C%20raising%2C%20and,of%20threatened%20or%20endangered%20species. [22.11.23].

 

2. Roser, H.R.a.M. (2021) Fish and Overfishing. https://ourworldindata.org/fish-and-overfishing#article-citation [20.11.23].

 

3. OECD (2023) Aquaculture Production (Indicator). https://data.oecd.org/fish/aquaculture-production.htm [20.11.23].

 

4. Pradeepkiran, J.A. (2019) Aquaculture role in global food security with nutritional value: a review. Translational Animal Science 3, 903-910.

 

5. Economics, B. (2020) Estimation of the Wider Economic Impacts of the Aquaculture Sector in Scotland. https://www.gov.scot/publications/estimation-wider-economic-impacts-aquaculture-sector-scotland/ [21/11/23].

 

6. Johansen, U., H. Bull-Berg, L.H. Vik, A.M. Stokka, R. Richardsen, and U. Winther (2019) The Norwegian seafood industry – Importance for the national economy. Marine Policy 110.

 

7. Godfrey, M. (2019) Massive shift underway in China’s aquaculture, fisheries sectors. https://www.seafoodsource.com/news/supply-trade/massive-shift-underway-in-china-s-aquaculture-fisheries-sectors [22.11.23].

 

8. Chen, G., Y. Li, and J. Wang (2021) Occurrence and ecological impact of microplastics in aquaculture ecosystems. Chemosphere 274.

 

9. Føre, H.M. and T. Thorvaldsen (2021) Causal analysis of escape of Atlantic salmon and rainbow trout from Norwegian fish farms during 2010–2018. Aquaculture 532.

 

10. Khanjani, M.H. and M. Sharifinia (2020) Biofloc technology as a promising tool to improve aquaculture production. Reviews in Aquaculture 12, 1836-1850.

 

11. Kawsar, M.A., M.T. Alam, D. Pandit, M.M. Rahman, M. Mia, A. Talukdar, and T.A. Sumon (2022) Status of disease prevalence, drugs and antibiotics usage in pond-based aquaculture at Narsingdi district, Bangladesh: A major public health concern and strategic appraisal for mitigation. Heliyon 8, 09060.

 

12. Desk, F.O. (2023) Bangladesh exports fish and fish products to over 50 countries. https://thefinancialexpress.com.bd/trade/bangladesh-exports-fish-and-fish-products-to-over-50-countries [21.11.23].

 

13. Yu, J.E., M.Y. Cho, J.-w. Kim, and H.Y. Kang (2012) Large antibiotic-resistance plasmid of Edwardsiella tarda contributes to virulence in fish. Microbial Pathogenesis 52, 259-266.

 

14. Sherif, A.H., M. Gouda, S. Darwish, and A. Abdelmohsin (2021) Prevalence of antibiotic-resistant bacteria in freshwater fish farms. Aquaculture Research 52, 2036-2047.

 

15. Santos, L. and F. Ramos (2018) Antimicrobial resistance in aquaculture: Current knowledge and alternatives to tackle the problem. International Journal of Antimicrobial Agents 52, 135-143.

 

16. Parsons, A.E., R.H. Escobar-Lux, P.N. Sævik, O.B. Samuelsen, and A.-L. Agnalt (2020) The impact of anti-sea lice pesticides, azamethiphos and deltamethrin, on European lobster (Homarus gammarus) larvae in the Norwegian marine environment. Environmental Pollution 264, 114725.

 

17. Szaniawska, A. (2018) Function and Importance of Crustaceans. In: Baltic Crustaceans, New York: Springer, 185-188.

 

18. Parveen, N., S. Chowdhury, and S. Goel (2022) Environmental impacts of the widespread use of chlorine-based disinfectants during the COVID-19 pandemic. Environmental Science and Pollution Research 29, 85742-85760.

 

19. Geilfus, C.-M. (2019) Chloride in soil: From nutrient to soil pollutant. Environmental and Experimental Botany 157, 299-309.

 

20. Mitchell, R.J. and P. Bates (2011) Measuring health-related productivity loss. Popul Health Manag 14, 93-8.

 

21. Irwin, S., M.S. Flaherty, and J. Carolsfeld (2021) The contribution of small-scale, privately owned tropical aquaculture to food security and dietary diversity in Bolivia. Food Security 13, 199-218.

 

22. Xie, B., J. Qin, H. Yang, X. Wang, Y.-H. Wang, and T.-Y. Li (2013) Organic aquaculture in China: A review from a global perspective. Aquaculture 414-415, 243-253.

 

23. Cottee, S.Y. and P. Petersan (2009) Animal Welfare and Organic Aquaculture in Open Systems. Journal of Agricultural and Environmental Ethics 22, 437-461.