Jie Li , Haohao Hu , Ruihao Niu , Qingqing Zhu , Siyu Yao , Jianwei Zhou , Donghong Liu , Enbo Xu
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引用次数: 0
摘要
为了应对个人需求、供应压力、食品安全和环境问题,三维(3D)打印鱼类模拟物正逐渐接近模拟真实鱼肉的能力。然而,利用三维食品打印技术模拟真实肉类组织的复合结构仍是一项挑战。在本研究中,我们利用双喷嘴 3D 打印技术,通过大豆分离蛋白-黄原胶-淀粉复合物(作为模拟肌肉油墨)和纳米淀粉-卡拉胶乳液凝胶(作为模拟脂肪油墨)构建了植物基大黄鱼组织模拟物。通过构建肌肉/脂肪双相三维模型和优化打印工艺,我们成功制备了具有高仿真复合结构的三维打印鱼肉。我们分析了模拟鱼肉的质地、水分分布和营养成分含量,并与真实的大黄鱼肉进行了比较,结果表明具有复合结构的三维打印植物大黄鱼肉具有良好的仿真质量。
Simulated construction of plant-based fish meat with composite structure via dual-nozzle extrusion 3D printing
Three-dimensional (3D)-printed fish analogs are gradually nearing the ability to mimic real fish meat in response to personal demand, supply pressure, food safety, and environmental concerns. However, the use of 3D food printing to simulate the composite structure of real meat tissue remains a challenge. In this study, we used dual-nozzle 3D printing technology to construct plant-based yellow croaker tissue analogs by soy protein isolate–xanthan gum-starch complex (as simulated muscle ink) and nanostarch-carrageenan emulsion gel (as simulated fat ink). We successfully prepared 3D-printed fish meat with a high simulation composite structure by constructing a muscle/fat biphasic 3D model and optimizing the printing process. The texture, moisture distribution, and nutrient content of the simulated fish meat were analyzed and compared with real yellow croaker meat, demonstrating that 3D-printed plant-based yellow croaker flesh with a composite structure had a good simulation quality.
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