3D-Printed Meat Paste Using Minimal Additive: Assessment of Rheological and Printing Behavior with Post-Processing Stability

IF 2.8 4区农林科学 Q2 FOOD SCIENCE & TECHNOLOGY

Food Biophysics Pub Date : 2024-07-29 DOI:10.1007/s11483-024-09866-2

Hanife Aydan Yatmaz

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Abstract

Printing foods in the desired shape with minimal additives and their stability after printing are the most important points for 3D food technology. In this study, the effects of water (5%, 10%, 15%, and 20%) and salt (0.5%, 1%, 1.5%, and 2%) on the printability of meat paste were evaluated to achieve improved textural and rheological properties. The printing parameters were examined at every stage, starting from the line thickness of the printed product, until the final 3D printed product was obtained. Accordingly, meat printability determined using different ingredient flow speed (3, 3.5, 4, 4.5, and 5), fill factor (1.2%, 1.3%, 1.4%, 1.5%, and 1.6%) and distance between layers (1.2, 1.4, and 1.6 mm). Salt addition increased the firmness and consistency of the samples, while the viscosity, storage modulus, and loss modulus decreased with the addition of water. Considering the line thickness and outer length, the most appropriate shape was obtained with 10% water and 1.5% salt. The optimal ingredient flow speed, fill factor, and distance between layers at a constant printing speed (2500 mm/min) were 3, 1.2%, and 1.4 mm, respectively. Four-layer-infilled 3D-printed samples maintained their initial shape after cooking, regardless of the cooking method. However, only baked products maintained their initial shapes among full-infilled samples. Although water and salt have different functions in meat, the use of the appropriate ratio is necessary for 3D-printed meat-based products to provide printability and post-production stability. To sum up optimum parameters and road map for printing meat and meat products including leftover meats and low-value by-products were revealed.

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使用最少添加剂的 3D 打印肉酱：流变和打印行为与后处理稳定性评估

以最少的添加剂打印出所需形状的食品以及打印后的稳定性是三维食品技术的重中之重。本研究评估了水（5%、10%、15% 和 20%）和盐（0.5%、1%、1.5% 和 2%）对肉酱可打印性的影响，以获得更好的质地和流变特性。从打印产品的线条厚度开始，直到获得最终的三维打印产品，每个阶段都对打印参数进行了检测。因此，使用不同的配料流速（3、3.5、4、4.5 和 5）、填充因子（1.2%、1.3%、1.4%、1.5% 和 1.6%）和层间距（1.2、1.4 和 1.6 毫米）确定了肉的可打印性。盐的加入增加了样品的坚固性和稠度，而粘度、储存模量和损失模量则随着水的加入而降低。考虑到线的粗细和外长，10% 的水和 1.5% 的盐能得到最合适的形状。在恒定印刷速度（2500 毫米/分钟）下，最佳配料流动速度、填充因子和层间距分别为 3、1.2% 和 1.4 毫米。无论采用哪种烹饪方法，四层填充的 3D 打印样品在烹饪后都能保持初始形状。然而，在全填充样品中，只有烘焙产品保持了初始形状。虽然水和盐在肉类中具有不同的功能，但对于三维打印的肉类产品来说，使用适当的比例是必要的，这样才能提供可打印性和生产后的稳定性。总之，该研究揭示了打印肉类和肉制品（包括剩肉和低价值副产品）的最佳参数和路线图。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Food Biophysics 工程技术-食品科技

CiteScore

5.80

自引率

3.30%

发文量

审稿时长

1 months

期刊介绍： Biophysical studies of foods and agricultural products involve research at the interface of chemistry, biology, and engineering, as well as the new interdisciplinary areas of materials science and nanotechnology. Such studies include but are certainly not limited to research in the following areas: the structure of food molecules, biopolymers, and biomaterials on the molecular, microscopic, and mesoscopic scales; the molecular basis of structure generation and maintenance in specific foods, feeds, food processing operations, and agricultural products; the mechanisms of microbial growth, death and antimicrobial action; structure/function relationships in food and agricultural biopolymers; novel biophysical techniques (spectroscopic, microscopic, thermal, rheological, etc.) for structural and dynamical characterization of food and agricultural materials and products; the properties of amorphous biomaterials and their influence on chemical reaction rate, microbial growth, or sensory properties; and molecular mechanisms of taste and smell. A hallmark of such research is a dependence on various methods of instrumental analysis that provide information on the molecular level, on various physical and chemical theories used to understand the interrelations among biological molecules, and an attempt to relate macroscopic chemical and physical properties and biological functions to the molecular structure and microscopic organization of the biological material.