3D‐Printed Prolamin Scaffolds for Cell‐Based Meat Culture

Su, Lingshan; Jing, Linzhi; Zeng, Xianjian; Chen, Tong; Liu, Huan; Kong, Yan; Wang, Xiang; Yang, Xin; Chen, Fu; Sun, Junying; Huang, Dejian

doi:10.1002/adma.202207397

Cited by 40 publications

(28 citation statements)

References 35 publications

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“…Also, Koranne et al (2022) used soy lecithin for the 3D printing of hydrolysed collagen in order to prepare a printable edible ink. Cereal prolamins have demonstrated compatibility with muscle cells and have been used to create edible scaffolds (Su et al, 2023), and bread-derived scaffolds with controllable porosity and mechanical properties have also been developed (Holmes et al, 2022). In addition, DaNAgreen Protinet-P is an edible scaffolding product made from isolated plant proteins that did not provide more information (DaNAgreen, 2023).…”

Section: Plant Protein-based Materialsmentioning

confidence: 99%

Review in edible materials for sustainable cultured meat: scaffolds and microcarriers production

Moslemy,

Sharifi,

Asadi‐Eydivand

et al. 2023

Int J of Food Sci Tech

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SummaryCultured meat, also known as lab‐grown or cell‐based meat, is a promising concept in the food industry that involves culturing animal cells in vitro to produce meat products, bypassing the need for traditional animal rearing and slaughter. This technology offers solutions to key challenges associated with conventional meat production, including environmental sustainability, animal welfare, and food security. However, the cultured meat industry must overcome significant hurdles to achieve commercial viability. Scaling up production to meet the increasing demand for meat is a considerable challenge, requiring a scalable edible scaffold, eliminating the need for separate scaffold removal, and ensuring product safety. Various edible materials, including polysaccharides and proteins, along with fabrication techniques like electrospinning and 3D printing, are explored in this review article.

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Section: Plant Protein-based Materialsmentioning

confidence: 99%

Review in edible materials for sustainable cultured meat: scaffolds and microcarriers production

Moslemy,

Sharifi,

Asadi‐Eydivand

et al. 2023

Int J of Food Sci Tech

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“…Zein protein from barley and rye have been used to develop a cereal prolamin ink for 3D printing and produce a fibrous scaffold which allows for the attachment and proliferation of C2C12 and porcine skeletal muscle satellite cells (Su et al, 2023). This is the first cell-based meat concept that uses a plant-based source for scaffold bioprinting and will motivate more studies investigating sustainable biomaterials for bioprinting.…”

Section: D Printed Scaffoldmentioning

confidence: 99%

Sculpting the future of meat: Biomaterial approaches and structural engineering for large‐scale cell‐based production

Jin,

Bennie,

Ogilvie

et al. 2023

Sustainable Food Proteins

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Novel foods are an increasing reality (and necessity) for our global food system and need to be protein‐rich for good nutrition. Cell‐based meats use the edible biomass of in vitro cultured animal cells harvested from the muscle tissue of live animals, removing the need to raise and slaughter animals. It is a viable alternative that is environmentally friendly, lowers resource consumption, and reduces health risks associated with traditional livestock farming. The cell‐based meat industry has boomed over the last 5 years with dozens of start‐ups being founded and millions of dollars in capital raised. While cell‐based meat faces technical, socio‐political, and regulatory challenges, it is a nascent technology with key technical challenges such as cell line stability, non‐animal‐derived culture media development, and bioprocessing for commercial‐scale uses. Here, we review the current field of cell‐based meat production at a lab scale and assess the feasibility and scalability of commercial production and the challenges that these production methods face. Moreover, we discuss the advancements in technologies for large‐scale manufacturing of cell‐based meat covering aspects including optimized culture media formulations, edible scaffold designs, and bioreactors for high‐density cell culture to reduce production costs.

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“…To address the hurdle, secalin, from rye, was usually incorporated evidenced by the improved flexibility and stretchability, which were attributed to higher molecular weight and longer peptide chains compared to zein. 6 The superior self-assembly behaviors also render secalin a promising scaffolding material. Moreover, the diverse types of prolamins enable the fabrication of scaffolds with appropriate stiffness for soft tissue because the molecular weight of proteins affects the mechanical properties of scaffolds.…”

Section: Introductionmentioning

confidence: 99%

3D Porous Edible Scaffolds from Rye Secalin for Cell-Based Pork Fat Tissue Culturing

Su,

Jing,

Zeng

et al. 2024

J. Agric. Food Chem.

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Cellular agriculture holds hope for a sustainable alternative to conventional meat, yet multiple technical challenges remain. These include the large-scale production of edible scaffolds and culturing methods for fat tissues, which are key to meat texture, flavor, and nutritional values. Herein. we disclose our method in the facile fabrication of sponge-like plant protein scaffolds by applying commercial sugar cubes as highly permeable templates. The prepared secalin scaffolds feature a high porosity of 85− 90%, fully interconnected pores, and high water stability. The mechanical properties of scaffolds could be tuned by varying sugar-toprotein weight ratio and post-water annealing treatment. Moreover, murine preadipocytes (3T3-L1) and porcine adipose-derived stem cells (ADSCs) readily infiltrate, adhere, proliferate, and differentiate on the secalin scaffolds to develop a fat tissue morphology. A cultured fat tissue was produced by culturing porcine ADSCs for 12 days, which remarkably resembles conventional porcine subcutaneous adipose tissue in appearance, texture, flavor, and fatty acid profiles. The research demonstrates the great potential of sponge-like secalin scaffolds for cultured fat tissue production.

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3D‐Printed Prolamin Scaffolds for Cell‐Based Meat Culture

Cited by 40 publications

References 35 publications

Review in edible materials for sustainable cultured meat: scaffolds and microcarriers production

Review in edible materials for sustainable cultured meat: scaffolds and microcarriers production

Sculpting the future of meat: Biomaterial approaches and structural engineering for large‐scale cell‐based production

3D Porous Edible Scaffolds from Rye Secalin for Cell-Based Pork Fat Tissue Culturing

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