With decreasing available land and fresh-water resources, the oceans become attractive alternatives for the production of valuable biomass, comparable to terrestrial crops. Seaweed cultivation for food, chemicals, and fuels is already under intensive development, yet efficient technologies for separation of major components are still missing. We report a food-grade process for the extraction of proteins from a green macroalga, Ulva sp., using high-voltage pulsed electric field (PEF) cell-membrane permeabilization, coupled with mechanical pressing to separate liquid and solid phases. We showed that a PEF treatment, at 247 kJ/kg fresh Ulva, delivered through 50 pulses of 50 kV, applied at a 70.3 mm electrode gap on the 140 g fresh weight of Ulva sp., resulted in an ∼7-fold increase in the total protein extraction yield compared to extraction by osmotic shock. The PEF extract of 20% protein content showed 10−20 times higher antioxidant capacity than β-Lactoglobulin (β-Lg), bovine serum albumin, and potato protein isolates. The protein concentration per dry mass in the residual biomass after PEF treatment was increased compared to the control because of the removal of additional nonprotein compounds from the biomass during the extraction process. These results provide currently missing information and technological development for the use of macroalgae as a source of protein for promoting sustainable human nutrition and health.
There is a growing global need to shift from animal- towards plant-based diets. The main motivations are environmental/sustainability-, human health- and animal welfare concerns. The aim is to replace traditional animal-based food with various alternatives, predominantly plant-based analogs. The elevated consumption of fish and seafood, leads to negative impacts on the ecosystem, due to dwindling biodiversity, environmental damage and fish diseases related to large-scale marine farming, and increased intake of toxic substances, particularly heavy metals, which accumulate in fish due to water pollution. While these facts lead to increased awareness and rising dietary shifts towards vegetarian and vegan lifestyles, still the majority of seafood consumers seek traditional products. This encourages the development of plant-based analogs for fish and seafood, mimicking the texture and sensorial properties of fish-meat, seafood, or processed fish products. Mimicking the internal structure and texture of fish or seafood requires simulating their nanometric fibrous-gel structure. Common techniques of structuring plant-based proteins into such textures include hydrospinning, electrospinning, extrusion, and 3D printing. The conditions required in each technique, the physicochemical and functional properties of the proteins, along with the use of other non-protein functional ingredients are reviewed. Trends and possible future developments are discussed.
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