High-pressure treatment of the green and orange Dunaliella salina biomass: effect on particle size distribution, small amplitude oscillatory shear rheology, and microstructure.

IF 3.5 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Bioprocess and Biosystems Engineering Pub Date : 2025-06-01 Epub Date: 2025-04-15 DOI:10.1007/s00449-025-03160-2

Jasim Ahmed, Vanita Vinod Kumar, Vinod Kumar, Sabah AlMomin

{"title":"High-pressure treatment of the green and orange Dunaliella salina biomass: effect on particle size distribution, small amplitude oscillatory shear rheology, and microstructure.","authors":"Jasim Ahmed, Vanita Vinod Kumar, Vinod Kumar, Sabah AlMomin","doi":"10.1007/s00449-025-03160-2","DOIUrl":null,"url":null,"abstract":"Dunaliella salina, a halophilic microalga, is well known for its ability to produce β-carotene and has significant commercial applications. The actively growing green culture turns to orange color due to photosensitization, during which there is a significant reduction in chlorophyll content (chlorophyll A and B: 16.04 and 2.80-1.70, 0.21 mg/g dry basis, respectively) with an increase in carotenoids (α- and β-carotenes: 1.60 and 4.81 mg/g dry basis). This change has been accompanied by a considerable variation in protein content (green: 34.27% and orange: 18.57%) and ash content (green: 38.37% and orange: 58.11%). To avoid extreme heat sensitivity, high-pressure (HP) processing, a nonthermal technology, has been applied to pigment-rich Dunaliella. This research aimed to examine the effects of HP treatment (300-600 MPa/15 min) on the rheological, structural, and particle size distribution of Dunaliella in two consecutive cell growth stages (e.g., green and orange). Oscillatory rheology data displayed a distinct protein denaturation at 57.87 °C for untreated green cells, whereas orange cells did not. Conversely, several denaturation peaks appeared in the HP-treated orange cell suspensions, and those peaks remained unaffected by pressure treatment. Isothermal heating exhibited liquid-like behavior for green cells, whereas the solid-like behavior was evident for orange cells. PSD displayed a shift of unimodal to bimodal distributions of Dunaliella cells after the HP treatment. Orange cells exhibited PSD parameters of Dv10: 8.60 μm, Dv50: 71.6 μm, and Dv90: 255 μm. XRD patterns of both green and orange cells are almost identical, exhibiting several peaks that were attributed to metal ions absorbed by the cells from the growth media. Overall, a significant difference in compositional and functional properties was observed between the green and orange Dunaliella biomass.","PeriodicalId":9024,"journal":{"name":"Bioprocess and Biosystems Engineering","volume":" ","pages":"1025-1037"},"PeriodicalIF":3.5000,"publicationDate":"2025-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Bioprocess and Biosystems Engineering","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1007/s00449-025-03160-2","RegionNum":3,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2025/4/15 0:00:00","PubModel":"Epub","JCR":"Q2","JCRName":"BIOTECHNOLOGY & APPLIED MICROBIOLOGY","Score":null,"Total":0}

引用次数: 0

Abstract

Dunaliella salina, a halophilic microalga, is well known for its ability to produce β-carotene and has significant commercial applications. The actively growing green culture turns to orange color due to photosensitization, during which there is a significant reduction in chlorophyll content (chlorophyll A and B: 16.04 and 2.80-1.70, 0.21 mg/g dry basis, respectively) with an increase in carotenoids (α- and β-carotenes: 1.60 and 4.81 mg/g dry basis). This change has been accompanied by a considerable variation in protein content (green: 34.27% and orange: 18.57%) and ash content (green: 38.37% and orange: 58.11%). To avoid extreme heat sensitivity, high-pressure (HP) processing, a nonthermal technology, has been applied to pigment-rich Dunaliella. This research aimed to examine the effects of HP treatment (300-600 MPa/15 min) on the rheological, structural, and particle size distribution of Dunaliella in two consecutive cell growth stages (e.g., green and orange). Oscillatory rheology data displayed a distinct protein denaturation at 57.87 °C for untreated green cells, whereas orange cells did not. Conversely, several denaturation peaks appeared in the HP-treated orange cell suspensions, and those peaks remained unaffected by pressure treatment. Isothermal heating exhibited liquid-like behavior for green cells, whereas the solid-like behavior was evident for orange cells. PSD displayed a shift of unimodal to bimodal distributions of Dunaliella cells after the HP treatment. Orange cells exhibited PSD parameters of Dv₁₀: 8.60 μm, Dv₅₀: 71.6 μm, and Dv₉₀: 255 μm. XRD patterns of both green and orange cells are almost identical, exhibiting several peaks that were attributed to metal ions absorbed by the cells from the growth media. Overall, a significant difference in compositional and functional properties was observed between the green and orange Dunaliella biomass.

查看原文本刊更多论文

高压处理绿色和橙色盐藻生物量：对粒径分布、小振幅振荡剪切流变学和微观结构的影响。

Dunaliella salina是一种嗜盐微藻，以其生产β-胡萝卜素的能力而闻名，具有重要的商业应用。生长期绿色培养因光敏作用而呈现橙色，叶绿素含量显著降低（叶绿素a和B含量分别为16.04和2.80-1.70、0.21 mg/g干基），类胡萝卜素含量显著增加（α-和β-胡萝卜素含量分别为1.60和4.81 mg/g干基）。这种变化伴随着蛋白质含量（绿色：34.27%，橙色：18.57%）和灰分含量（绿色：38.37%，橙色：58.11%）的相当大的变化。为了避免极端的热敏性，高压（HP）处理（一种非热技术）已被应用于富含色素的杜氏藻。本研究旨在研究HP处理（300-600 MPa/15 min）对杜氏藻在连续两个细胞生长阶段（如绿色和橙色）流变学、结构和粒径分布的影响。振荡流变学数据显示，未经处理的绿色细胞在57.87°C时有明显的蛋白质变性，而橙色细胞则没有。相反，在hp处理过的橙细胞悬浮液中出现了几个变性峰，这些峰不受压力处理的影响。等温加热对绿色细胞表现出液体样行为，而对橙色细胞表现出固体样行为。HP处理后，PSD显示杜氏菌细胞的单峰分布向双峰分布转变。橙色细胞的PSD参数分别为Dv10: 8.60 μm、Dv50: 71.6 μm和Dv90: 255 μm。绿色和橙色细胞的XRD谱图几乎相同，有几个峰是由细胞从生长介质中吸收的金属离子引起的。总体而言，绿色和橙色杜氏藻生物量在组成和功能特性上存在显著差异。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Bioprocess and Biosystems Engineering 工程技术-工程：化工

CiteScore

7.90

自引率

2.60%

发文量

147

审稿时长

2.6 months

期刊介绍： Bioprocess and Biosystems Engineering provides an international peer-reviewed forum to facilitate the discussion between engineering and biological science to find efficient solutions in the development and improvement of bioprocesses. The aim of the journal is to focus more attention on the multidisciplinary approaches for integrative bioprocess design. Of special interest are the rational manipulation of biosystems through metabolic engineering techniques to provide new biocatalysts as well as the model based design of bioprocesses (up-stream processing, bioreactor operation and downstream processing) that will lead to new and sustainable production processes. Contributions are targeted at new approaches for rational and evolutive design of cellular systems by taking into account the environment and constraints of technical production processes, integration of recombinant technology and process design, as well as new hybrid intersections such as bioinformatics and process systems engineering. Manuscripts concerning the design, simulation, experimental validation, control, and economic as well as ecological evaluation of novel processes using biosystems or parts thereof (e.g., enzymes, microorganisms, mammalian cells, plant cells, or tissue), their related products, or technical devices are also encouraged. The Editors will consider papers for publication based on novelty, their impact on biotechnological production and their contribution to the advancement of bioprocess and biosystems engineering science. Submission of papers dealing with routine aspects of bioprocess engineering (e.g., routine application of established methodologies, and description of established equipment) are discouraged.