Effect of drying on bioactive compounds in Eugenia uniflora fruit pulp

IF 2.7 3区农林科学 Q3 ENGINEERING, CHEMICAL Journal of Food Process Engineering Pub Date : 2024-09-19 DOI:10.1111/jfpe.14744

Mariana Bellaver, Camyla Ribeiro Gonzaga dos Santos, Marta dos Santos Diniz Freitas, Gustavo Mendes Platt, Neusa Fernandes de Moura

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Abstract

Eugenia uniflora is a tropical species rich in bioactive compounds that are highly sensitive to processing conditions, particularly those involving heat. Drying is a widely used method for preserving fruit pulp which can affect the stability of these bioactive compounds. The aim of this study was to assess the impact of drying at different temperatures on the retention of phenolic compounds and carotenoids present in the pulp of E. uniflora, with the goal of optimizing the drying process to preserve the pulp's quality. The E. uniflora pulp was dried in an oven with air circulation at three temperatures (45, 65, and 85°C). During the drying process, the moisture content and concentration of phenolics, β-carotene, and lycopene were measured over time. After 260 min of drying, phenolic compounds decreased by 63.97% (45 and 65°C) and by 59.62% (85°C). Carotenoids losses were even more pronounced exceeding 89%, for all temperatures, with β-carotene reductions of 92.91%, 90.72%, and 91.11%, at 45, 65, and 85°C, respectively. Several well-established drying models were tested to represent the moisture content over time. Two models exhibited a high adherence to the experimental data. Zero-order, first-order, and second-order degradation models were used to describe the concentrations of phenolic compounds and carotenoids. For total carotenoids, the model that showed the best results was temperature-dependent. The first-order model provided the best fit for β-carotene and lycopene, with high R² values of 0.9852 (45°C), 0.9776 (65°C), and 0.9681(85°C) for β-carotene, and 0.9776 (45°C), 0.9715 (65°C), and 0.9659 (85°C) for lycopene. These results indicate that higher temperatures accelerate the degradation of bioactive compounds, following a predictable dynamic that can be optimized through adjustments to the drying process.

Practical applications

The fruit of Eugenia uniflora contains phenolic and carotenoid compounds with significant nutraceutical potential. However, the production of this fruit is seasonal, necessitating effective preservation methods. Drying, which involves the removal of water from the pulp, is a common procedure aimed at extending the fruit's conservation and shelf life. Despite its benefits, the drying process poses a challenge, as bioactive compounds like phenolic and carotenoids are sensitive to thermal processing. Their degradation during drying can lead to a reduction in the fruit's bioactive potential. Therefore, it is crucial to understand the kinetics of drying and the degradation of these bioactive compounds to optimize the drying process and maximize the fruit's nutraceutical value.

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干燥对 Eugenia uniflora 果肉中生物活性化合物的影响

Eugenia uniflora 是一种富含生物活性化合物的热带物种，这些化合物对加工条件非常敏感，尤其是涉及热量的加工条件。干燥是一种广泛使用的保存果肉的方法，它会影响这些生物活性化合物的稳定性。本研究的目的是评估不同温度下的干燥对保留单叶榕果肉中酚类化合物和类胡萝卜素的影响，从而优化干燥过程，保持果肉的品质。单叶榕果肉在 45、65 和 85°C 三种温度的空气循环烘箱中进行干燥。在干燥过程中，随时间测量水分含量和酚类物质、β-胡萝卜素和番茄红素的浓度。干燥 260 分钟后，酚类化合物减少了 63.97%（45 和 65°C）和 59.62%（85°C）。类胡萝卜素的损失更为明显，在所有温度下都超过了 89%，在 45、65 和 85°C 温度下，β-胡萝卜素分别减少了 92.91%、90.72% 和 91.11%。对几种成熟的干燥模型进行了测试，以表示随时间变化的水分含量。有两个模型与实验数据高度吻合。零阶、一阶和二阶降解模型用于描述酚类化合物和类胡萝卜素的浓度。对于总类胡萝卜素来说，显示最佳结果的模型与温度有关。一阶模型对β-胡萝卜素和番茄红素的拟合效果最好，β-胡萝卜素的 R2 值分别为 0.9852（45°C）、0.9776（65°C）和 0.9681（85°C），番茄红素的 R2 值分别为 0.9776（45°C）、0.9715（65°C）和 0.9659（85°C）。这些结果表明，较高的温度会加速生物活性化合物的降解，其动态可预测，可通过调整干燥过程进行优化。实际应用 Eugenia uniflora 的果实含有酚类和类胡萝卜素化合物，具有很大的营养保健潜力。然而，这种水果的生产是季节性的，因此需要有效的保存方法。干燥是一种常见的程序，它涉及去除果肉中的水分，目的是延长水果的保存期和货架期。尽管烘干过程好处多多，但也带来了挑战，因为酚类和类胡萝卜素等生物活性化合物对热加工很敏感。它们在干燥过程中的降解会导致水果的生物活性潜力降低。因此，了解干燥动力学和这些生物活性化合物的降解至关重要，以便优化干燥过程，最大限度地提高水果的营养保健价值。

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来源期刊

Journal of Food Process Engineering 工程技术-工程：化工

CiteScore

5.70

自引率

10.00%

发文量

259

审稿时长

2 months

期刊介绍： This international research journal focuses on the engineering aspects of post-production handling, storage, processing, packaging, and distribution of food. Read by researchers, food and chemical engineers, and industry experts, this is the only international journal specifically devoted to the engineering aspects of food processing. Co-Editors M. Elena Castell-Perez and Rosana Moreira, both of Texas A&M University, welcome papers covering the best original research on applications of engineering principles and concepts to food and food processes.