Mimicking Wagyu Beef Fat in Cultured Meat: Progress in Edible Bovine Adipose Tissue Production with Controllable Fatty Acid Composition

Overview

Journal Mater Today Bio

Specialty Biomedical Engineering

Date 2023 Jul 17

PMID 37455817

Authors

Fiona Louis

Mai Furuhashi

Haruka Yoshinuma

Shoji Takeuchi

Michiya Matsusaki

Affiliations

Soon will be listed here.

Abstract

Since the current process of livestock meat production has considerable effects on the global environment, leading to high emissions of greenhouse gases, cultured meat has recently attracted attention as a suitable alternative way to acquire animal proteins. However, while most published studies on cell-cultured meat have focused on muscle tissue culture, fat production which is an important component of the process has often been neglected from this technology, even though it can enhance the meat's final taste, aroma, tenderness, texture, and palatability. In this study, we focused on bovine muscle reconstruction by monitoring and optimizing the possible expansion rate of isolated primary bovine adipose stem cells and their adipogenesis differentiation to be fully edible for cultured meat application. After approximatively 100 days of serial passages, the bovine adipose-derived stem cells, isolated from muscle tissue, underwent 57 ± 5 doublings in the edible cell culture medium condition. This implies that by cultivating and amplifying them, a minimum of 2.9 × 10 cells can be obtained from around 10 g of fat. It was discovered that these cells retain their adipogenesis differentiation ability for at least 12 passages. Moreover, the final lipid composition could be controlled by adjusting the fatty acid composition of the culture medium during the differentiation process, resulting in organoleptic features similar to those of real fat from muscle. This was especially so for the cis isomer oleic acid percentage, an important part of high-grade Japanese Wagyu meat. These characteristics of the primary bovine adipose-derived stem cell proliferation and adipogenesis differentiation provide valuable insights for the production of meat alternatives.

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