Abstract

Cellular agriculture is defined as the production of agricultural products from cell cultures rather than from whole plants or animals. With growing interest in cellular agriculture as a means to address the public health, environmental, and animal welfare challenges of animal agriculture, the concept of producing seafood from fish cell- and tissue-cultures is emerging as a means to address similar challenges with industrial aquaculture systems and marine capture. Cell-based seafood - as opposed to animal-based seafood - can combine developments in biomedical engineering with modern aquaculture techniques. Biomedical engineering developments such as closed-system bioreactor production of land animal cells create a basis for large scale production of marine animal cells. Aquaculture techniques such as genetic modification and closed system aquaculture have achieved marked gains in production that can pave the way for innovations in cell-based seafood production. Here, we present the current state of innovation relevant to the development of cell-based seafood across multiple species as well as specific opportunities and challenges that exist for advancing this science. The authors find that the physiological properties of fish cell- and tissue- culture may be uniquely suited to cultivation in vitro. These physiological properties, including hypoxia tolerance, high buffering capacity, and low-temperature growth conditions, make marine cell culture an attractive opportunity for scale production of cell-based seafood; perhaps even more so than mammalian and avian cell cultures for cell-based meats. This, coupled with the unique capabilities of crustacean tissue-friendly scaffolding such as chitosan, a common seafood waste product and mushroom derivative, presents great promise for cell-based seafood production via bioreactor cultivation. To become fully realized, cell-based seafood research will require more understanding of fish muscle culture and cultivation; more investigation into serum-free media formulations optimized for fish cell culture; and bioreactor designs tuned to the needs of fish cells for large scale production.

Highlights

  • It is estimated that industrialized fisheries and fishing due to marine capture have lowered ocean biomass content by up to 80% (Myers and Worm, 2003)

  • Marine cell cultures may be more forgiving in terms of temperature, pH and oxygen requirements compared to mammalian cell cultures, based on the unique characteristics of native fish muscle tissue

  • Given the progression of aquaculture toward more intensive, controlled and efficient systems, cell-based seafood production offers a new option to potentially avert the challenges associated with industrial aquaculture and marine capture

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Summary

Introduction

It is estimated that industrialized fisheries and fishing due to marine capture have lowered ocean biomass content by up to 80% (Myers and Worm, 2003). This effect, coupled with the effects of global warming on oceans, threatens to decimate wild fish populations (Funk and Brown, 2009). While some herald the rise of aquaculture as an ecological and economic boon (Tidwell and Allan, 2001), others feel that its benefits have been overstated and that it does not fundamentally solve current strains on wild fish populations (Naylor et al, 2000; Merino et al, 2012).

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