Selectively biorefining astaxanthin and triacylglycerol co-products from microalgae with supercritical carbon dioxide extraction

[Display omitted] •Solvatochromic measurements show tunable scCO2 clustering of solutes.•Pressure changes and solute matrix can enhance/diminish solubility in scCO2.•Initial 642 mg/ml scCO2 produced a >99% TAG extract from microalgae.•Second extraction of 971 mg/ml scCO2 was compositionally 63–76...

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Published inBioresource technology Vol. 269; pp. 81 - 88
Main Authors Kwan, Thomas Alan, Kwan, Sarah Elizabeth, Peccia, Jordan, Zimmerman, Julie Beth
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.12.2018
Subjects
astaxanthin
Bio-active compounds
biorefining
carbon dioxide
coproducts
Haematococcus pluvialis
hydrogen bonding
Kamlet-Taft
microalgae
Separations
solutes
Solvatochromism
supercritical fluid extraction
triacylglycerols
Solvatochromism
Bio-active compounds
Kamlet-Taft
Haematococcus pluvialis
Separations
Online AccessGet full text
ISSN0960-8524
1873-2976
1873-2976
DOI10.1016/j.biortech.2018.08.081

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Abstract [Display omitted] •Solvatochromic measurements show tunable scCO2 clustering of solutes.•Pressure changes and solute matrix can enhance/diminish solubility in scCO2.•Initial 642 mg/ml scCO2 produced a >99% TAG extract from microalgae.•Second extraction of 971 mg/ml scCO2 was compositionally 63–76% astaxanthin.•Overall TAG yields were 83–85% and astaxanthin was 81–86%. Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π∗, and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60–76% astaxanthin by mass.
AbstractList Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π∗, and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60–76% astaxanthin by mass.
[Display omitted] •Solvatochromic measurements show tunable scCO2 clustering of solutes.•Pressure changes and solute matrix can enhance/diminish solubility in scCO2.•Initial 642 mg/ml scCO2 produced a >99% TAG extract from microalgae.•Second extraction of 971 mg/ml scCO2 was compositionally 63–76% astaxanthin.•Overall TAG yields were 83–85% and astaxanthin was 81–86%. Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π∗, and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60–76% astaxanthin by mass.
Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π , and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60-76% astaxanthin by mass.
Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π∗, and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60-76% astaxanthin by mass.Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of dipolarity/polarizability, π∗, and hydrogen-bond acceptance, β. Both parameters were decreased for supercritical carbon dioxide with TAG at low densities and with astaxanthin at high densities. These results indicated supercritical carbon dioxide could selectively extract triacylglycerides at low densities followed by astaxanthin at higher densities from microalgae. Accordingly, Haematococcus pluvialis microalgae were subject to a two-stage continuous extraction scheme where a density of 642 mg/ml was employed to extract triacylglycerides followed by a density of 971 mg/ml, by an increase in pressure, to extract astaxanthin. The first, lower density extract yielded over 78% of the total triacylglycerides and was composed of less than 1% astaxanthin. The sequential, higher density extract yielded less than 5% of the total microalgae triacylglycerides, over 70% of the total astaxanthin, and was composed of 60-76% astaxanthin by mass.
Author Peccia, Jordan
Kwan, Sarah Elizabeth
Zimmerman, Julie Beth
Kwan, Thomas Alan
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Keywords Solvatochromism
Bio-active compounds
Kamlet-Taft
Haematococcus pluvialis
Separations
Language English
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Snippet [Display omitted] •Solvatochromic measurements show tunable scCO2 clustering of solutes.•Pressure changes and solute matrix can enhance/diminish solubility in...
Clustering behavior of supercritical carbon dioxide, triacylglycerides, and astaxanthin solutes were analyzed using Kamlet-Taft solvatochromic properties of...
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SubjectTerms astaxanthin
Bio-active compounds
biorefining
carbon dioxide
coproducts
Haematococcus pluvialis
hydrogen bonding
Kamlet-Taft
microalgae
Separations
solutes
Solvatochromism
supercritical fluid extraction
triacylglycerols
Title Selectively biorefining astaxanthin and triacylglycerol co-products from microalgae with supercritical carbon dioxide extraction
URI https://dx.doi.org/10.1016/j.biortech.2018.08.081
https://www.ncbi.nlm.nih.gov/pubmed/30149258
https://www.proquest.com/docview/2095545040
https://www.proquest.com/docview/2131860700
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