Sequential Phenolic Acid Co-pigmentation Pretreatment and Contact Ultrasound-assisted Air Drying to Intensify Blackberry Drying and Enhance Anthocyanin Retention: A Study on Mass Transfer and Phenolic Distribution

Overview

Journal Ultrason Sonochem

Specialty Radiology

Date 2021 Oct 23

PMID 34688142

Citations 4

Authors

WenJin Gong

Dandan Li

Yue Wu

Sivakumar Manickam

Xun Sun

Yongbin Han

Yang Tao

Xiaoli Liu

Affiliations

Soon will be listed here.

Abstract

In this work, the spraying of ethanol solution containing phenolic acid (ferulic acid or caffeic acid) was performed before subjecting to contact ultrasound-assisted air drying of blackberry. The mass transfer modeling results revealed that sonication intensified both internal water diffusion and external water exchange during drying, and ethanol pretreatment enhanced the effective diffusivity of water. Compared with air drying alone, the drying time for sequential ferulic acid pretreatment and drying with sonication was shortened by 89.2%. Owing to the co-pigmentation between phenolic acid and anthocyanins, the retention of anthocyanins was significantly enhanced after dehydration. At the end of drying, the total anthocyanin contents in the ultrasound-dried samples pretreated with ferulic acid and caffeic acid were 25.3% and 10.5% higher than the sonicated samples without pretreatments, respectively. Furthermore, drying simultaneously with sonication promoted the preservation of non-anthocyaninic soluble phenolics including catechin, phloretic acid, rutin in blackberry compared to air drying alone. Besides, bound phenolics in blackberry were less influences by the applied dehydration treatments. This study demonstrates that the combination of phenolic acid co-pigmentation pretreatment and ultrasound drying could be a promising method to protect anthocyanin pigments during dehydration of berry fruits.

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