CO2-triggered switchable solvent for lipid extraction from microalgal biomass

2022 ◽  
pp. 153084
Author(s):  
Oh. Kyung Choi ◽  
Jae Woo Lee
Keyword(s):  
Lipid Extraction ◽  
Microalgal Biomass

scholarly journals Processing Methodologies of Wet Microalga Biomass Toward Oil Separation: An Overview

Molecules ◽  
2021 ◽  
Vol 26 (3) ◽  
pp. 641
Author(s):  
Vânia Pôjo ◽  
Tânia Tavares ◽  
Francisco Xavier Malcata
Keyword(s):  
Food System ◽  
Lipid Extraction ◽  
High Energy ◽  
Economic Feasibility ◽  
Alternative Source ◽  
Microalgal Biomass ◽  
Energy Demands ◽  
Chemical Profiles ◽  
System Sustainability ◽  
Industrial Level

One of the main goals of Mankind is to ensure food system sustainability—including management of land, soil, water, and biodiversity. Microalgae accordingly appear as an innovative and scalable alternative source in view of the richness of their chemical profiles. In what concerns lipids in particular, microalgae can synthesize and accumulate significant amounts of fatty acids, a great fraction of which are polyunsaturated; this makes them excellent candidates within the framework of production and exploitation of lipids by various industrial and health sectors, either as bulk products or fine chemicals. Conventional lipid extraction methodologies require previous dehydration of microalgal biomass, which hampers economic feasibility due to the high energy demands thereof. Therefore, extraction of lipids directly from wet biomass would be a plus in this endeavor. Supporting processes and methodologies are still limited, and most approaches are empirical in nature—so a deeper mechanistic elucidation is a must, in order to facilitate rational optimization of the extraction processes. Besides circumventing the current high energy demands by dehydration, an ideal extraction method should be selective, sustainable, efficient, harmless, and feasible for upscale to industrial level. This review presents and discusses several pretreatments incurred in lipid extraction from wet microalga biomass, namely recent developments and integrated processes. Unfortunately, most such developments have been proven at bench-scale only—so demonstration in large facilities is still needed to confirm whether they can turn into competitive alternatives.

scholarly journals Physical Methods of Microalgal Biomass Pretreatment

2014 ◽  
Vol 28 (3) ◽  
pp. 341-348 ◽  
Author(s):  
Agata Piasecka ◽  
Izabela Krzemińska ◽  
Jerzy Tys
Keyword(s):  
Alternative Energy ◽  
Lipid Extraction ◽  
Physical Method ◽  
Extraction Methods ◽  
Biodiesel Production ◽  
Biomass Pretreatment ◽  
Microalgal Biomass ◽  
Alternative Energy Sources ◽  
Wet Biomass ◽  
Microwave Techniques

Abstract The prospect of depletion of natural energy resources on the Earth forces researchers to seek and explore new and alternative energy sources. Biomass is a composite resource that can be used in many ways leading to diversity of products. Therefore, microalgal biomass offers great potential. The main aim of this study is to find the best physical method of microalgal biomass pretreatment that guarantees efficient lipid extraction. These studies identifies biochemical composition of microalgal biomass as source for biodisel production. The influence of drying at different temperatures and lyophilization was investigated. In addition, wet and untreated biomass was examined. Cell disruption (sonication and microwave) techniques were used to improve lipid extraction from wet biomass. Additionally, two different extraction methods were carried out to select the best method of crude oil extraction. The results of this study show that wet biomass after sonication is the most suitable for extraction. The fatty acid composition of microalgal biomass includes linoleic acid (C18:2), palmitic acid (C16:0), oleic acid (C18:1), linolenic acid (C18:3), and stearic acid (C18:0), which play a key role in biodiesel production.

Influence of lipid extraction methods as pre-treatment of microalgal biomass for biogas production

2016 ◽  
Vol 59 ◽  
pp. 160-165 ◽  
Author(s):  
Viviane T. de C. Neves ◽  
Emerson Andrade Sales ◽  
Louisa W. Perelo
Keyword(s):  
Biogas Production ◽  
Lipid Extraction ◽  
Extraction Methods ◽  
Microalgal Biomass ◽  
Pre Treatment

Mechanical cell disruption for lipid extraction from microalgal biomass

2013 ◽  
Vol 140 ◽  
pp. 53-63 ◽  
Author(s):  
Ronald Halim ◽  
Thusitha W.T. Rupasinghe ◽  
Dedreia L. Tull ◽  
Paul A. Webley
Keyword(s):  
Lipid Extraction ◽  
Cell Disruption ◽  
Microalgal Biomass

scholarly journals Influence of Light Intensity and Photoperiod on the Photoautotrophic Growth and Lipid Content of the Microalgae Verrucodesmus verrucosus in a Photobioreactor

2021 ◽  
Vol 13 (12) ◽  
pp. 6606
Author(s):  
Laura Vélez-Landa ◽  
Héctor Ricardo Hernández-De León ◽  
Yolanda Del Carmen Pérez-Luna ◽  
Sabino Velázquez-Trujillo ◽  
Joel Moreira-Acosta ◽  
...  
Keyword(s):  
Fatty Acid ◽  
Lipid Accumulation ◽  
Growth Parameters ◽  
Methyl Esters ◽  
Lipid Extraction ◽  
Growth Conditions ◽  
Biodiesel Production ◽  
Microalgal Biomass ◽  
Bg11 Medium ◽  
Gas Chromatography Mass Spectroscopy

Microalgal biomass has the capacity to accumulate relatively large quantities of triacylglycerides (TAG) for the conversion of methyl esters of fatty acids (FAME) which has made microalgae a desirable alternative for the production of biofuels. In the present work Verrucodesmus verrucosus was evaluated under autotrophic growth conditions as a suitable source of oil for biodiesel production. For this purpose BG11 media were evaluated in three different light:dark photoperiods (L:D; 16:08; 12:12; 24:0) and light intensities (1000, 2000 and 3000 Lux) in a photobioreactor with a capacity of three liters; the evaluation of the microalgal biomass was carried out through the cell count with the use of the Neubauer chamber followed by the evaluation of the kinetic growth parameters. So, the lipid accumulation was determined through the lipid extraction with a Soxhlet system. Finally, the fatty acid profile of the total pooled lipids was determined using gas chromatography-mass spectroscopy (GC-MS). The results demonstrate that the best conditions are a photoperiod of 12 light hours and 12 dark hours with BG11 medium in a 3 L tubular photobioreactor with 0.3% CO2, 25 °C and 2000 Lux, allowing a lipid accumulation of 50.42%. Palmitic acid is identified as the most abundant fatty acid at 44.90%.

scholarly journals Biodiesel production from microalgae by enzymatic transesterification

2015 ◽  
Author(s):  
◽  
Abhishek Guldhe
Keyword(s):  
Energy Consumption ◽  
Production Process ◽  
Lipid Extraction ◽  
International Standards ◽  
Biodiesel Production ◽  
Enzymatic Conversion ◽  
Microalgal Biomass ◽  
Whole Cell ◽  
Immobilized Lipases ◽  
Microalgal Lipids

Main focus of this study is to investigate the enzymatic-conversion of microalgal lipids to biodiesel. However, preceding steps before conversion such as drying of microalgal biomass and extraction of lipids were also studied. Downstream processing of microalgae has several challenges and there is very little literature available in this area. S. obliquus was grown in the pilot scale open pond cultivation system for biomass production. Different techniques were studied for biomass drying and extraction of lipids from harvested microalgal biomass. Effect of these drying and extraction techniques on lipid yield and quality was assessed. Energy consumption and economic evaluation was also studied. Enzymatic conversion of microalgal lipids by extracellular and whole cell lipase application was investigated. For both applications, free and immobilized lipases from different sources were screened and selected based on biodiesel conversion. Process parameters were optimized using chosen extracellular and whole cell lipases; also step-wise methanol addition was studied to improve the biodiesel conversion. Immobilized lipase was studied for its reuse. Final biodiesel was characterized for its fuel properties and compared with the specifications given by international standards. Enzymatic conversion of microalgal lipids was compared with the conventional homogeneous acid-catalyzed conversion. Enzymatic conversion and chemical conversion were techno-economically investigated based on process cost, energy consumption and processing steps. Freeze drying was the most efficient technique, however at large scale economical sun drying could also be selected as possible drying step. Microwave assisted lipid extraction performed better compared to sonication technique. Immobilized P. fluorescens lipase in extracellular application and A. niger lipase in whole cell application showed superior biodiesel conversion. The extracellular immobilized P. fluorescens lipase showed better biodiesel conversion and yields than the immobilized A. niger whole cell lipase. Both the enzyme catalysts showed lower biodiesel conversion compared to conventional chemical catalyst and higher processing cost. However, techno-economic analysis showed that, the reuse potential of immobilized lipases can significantly improve the economics. Fewer purification steps, less wastewater generation and minimal energy input are the benefits of enzymatic route of biodiesel conversion. Microalgae as a feedstock and lipase as a catalyst for conversion makes overall biodiesel production process environmentally-friendly. Data from this study has academic as well as industrial significance. Conclusions from this study form the basis for greener and sustainable scaling-up of microalgal biodiesel production process.

scholarly journals First Report on Tertiary Amine as a Co2 Switchable Solvent for Hypersaline Trebouxiophycean Microalgae Towards Greener and Competent Lipid Extraction

2020 ◽  
Author(s):  
Susaimanickam Anto ◽  
M Premalatha ◽  
Thangavel Mathimani
Keyword(s):  
Fatty Acid ◽  
Energy Efficient ◽  
Lipid Extraction ◽  
Solvent System ◽  
Extraction Process ◽  
Extraction Time ◽  
Tertiary Amines ◽  
Microalgal Biomass ◽  
Lipid Yield ◽  
Fame Profile

Abstract Considering the momentous cost drivers in energy efficient algal biorefinery processes, a green alternative in the lipid extraction process from microalgae is anticipated. Switchable solvent system using tertiary amines namely DMBA (Dimethylbenzylamine), DMCHA (Dimethylcyclohexylamine), and DIPEA (Diisopropylethylamine) for lipid extraction from wet hypersaline microalgae was investigated in this study. Interestingly, showed that at 1:1 (v/v of fresh DMBA solvent: microalgal biomass), and for 1 h extraction time, the lipid yield was 41.9, 26.6, and 33.3% for Chlorella sp. NITT 05, Chlorella sp. NITT 02, and Picochlorum sp. NITT 04 respectively and for recovered DMBA solvent at 1:1 (v/v) and for 1 hour extraction time, the lipid yield was 40.8, 25.97, and 32%, respectively. Similarly, lipid extraction using DMCHA solvent for Chlorella sp. NITT 05, Chlorella sp. NITT 02, and Picochlorum sp. NITT 04 at 1:1 (v/v of solvent: microalgal biomass) and 1 h extraction time showed 34.28, 24.24 and 23.33% lipids, respectively for fresh solvent and 34.01, 24.24 and 23.18% for recovered solvent respectively; while DIPEA was not competent in lipid extraction from three tested microalgae. FAME profile shows the presence of major saturated fatty acid as C16:0 (~ 30%) and major unsaturated fatty acid as C18:1 (~17%).

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