Cultivation of Bovine MSCs on Plant-Based Scaffolds in a macrofluidic Single-Use Bioreactor for Cultured Meat

Gome, Gilad; Chak, Benyamin; Tawil, Shadi; Shpatz, Dafna; Giron, Jonathan; Brajzblat, Ilan; Weizman, Chen; Grishko, Andrey; Schlesinger, Sharon; Shoseyov, Oded

doi:10.20944/preprints202403.1587.v1

2024

DOI: 10.20944/preprints202403.1587.v1

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Cultivation of Bovine MSCs on Plant-Based Scaffolds in a macrofluidic Single-Use Bioreactor for Cultured Meat

Gilad Gome,

Benyamin Chak,

Shadi Tawil

et al.

Abstract: One of the main challenges of cultured meat is reducing the costs of production, often described as scaling. The main components of the cultivation process include: cells, media, scaffolds and bioreactors. This work presents an alternative to current stainless steel or glass bioreactors and uses food-grade plant-based scaffolds. Bioreactors must be sterile and leak-free to maintain a proper environment for cell growth. Thermoplastic films are a popular material for constructing these fluidic systems, but tradi… Show more

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Cited by 2 publications

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Advances in Biotechnological Strategies for Sustainable Production of Non-Animal Proteins: Challenges, Innovations, and Applications

Muniz,

Montenegro,

da Silva

et al. 2024

Fermentation

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This review explores recent advances in the design of fermentation processes for producing alternative proteins, focusing on utilizing agro-industrial waste and renewable substrates. New bioprocess strategies, such as experimental designs, optimizing bioreactors, bioprocesses, and applying precision fermentation can improve the protein yields and nutritional value. Also, unconventional substrates, such as hydrolysates derived from agro-industrial residues conversion may result in cost reduction and enhanced feasibility. The application of enzymes to produce protein-rich foods with high bioaccessibility that improve digestibility and nutritional value are also highlighted. This article addresses the importance of developing cost-effective fermentation solutions that minimize the environmental impact while addressing technical challenges such as scalability and contamination control. Furthermore, it emphasizes the growing need for innovations in fermentation process design to ensure the sustainability of industrial protein production. The review concludes that improvements in process design are fundamental in overcoming technological and regulatory barriers, particularly in increasing the efficiency and competitiveness of non-meat proteins in the global market.

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Advances in Biotechnological Strategies for Sustainable Production of Non-Animal Proteins: Challenges, Innovations, and Applications

Muniz,

Montenegro,

da Silva

et al. 2024

Fermentation

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show abstract

Design Principles for Laser-Printed Macrofluidics

Gome,

Benny,

Shoseyov

et al. 2024

Inventions

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This paper presents a novel method for fabricating fluidic circuits using laser printing technology. The method allows for rapid prototyping of macrofluidic devices with control over fluid manipulation and environmental conditions. We employed a high-resolution laser cutter to etch fluidic channels into various substrates, optimizing parameters such as laser power, speed, and substrate material. Our results demonstrate excellent performance in controlling fluid flow and maintaining environmental conditions, handling a wide range of fluids and flow rates. The devices were tested in multiple settings such as with high school students and in research laboratories in universities. We tested the laser-printed macrofluidcs mechanically for durability. We present previous works in microbiology with plants, microbial, and mammalian cell lines showing reliable operation with minimal leakage and consistent fluid dynamics. The versatility and scalability of this approach make it a promising tool for advancing research and innovation in fluidics, providing a robust platform for growing, manipulating, and experimenting with diverse biological systems from cells to whole organisms. We conclude that laser-printed macrofluidics can significantly contribute to fields such as biomedical research, synthetic biology, tissue engineering, and STEM education.

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Cultivation of Bovine MSCs on Plant-Based Scaffolds in a macrofluidic Single-Use Bioreactor for Cultured Meat

Cited by 2 publications

References 53 publications

Advances in Biotechnological Strategies for Sustainable Production of Non-Animal Proteins: Challenges, Innovations, and Applications

Advances in Biotechnological Strategies for Sustainable Production of Non-Animal Proteins: Challenges, Innovations, and Applications

Design Principles for Laser-Printed Macrofluidics

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