Extraction is most commonly used sample preparation technique in quantitative determination of all-trans-lutein in spinach. In our study RP-HPLC was applied to identify the constituents of spinach extract and to quantify all-trans - lutein content with the mobile phase consisted of acetone and water. Due to sensitivity of all-trans-lutein, we compared effects of different extraction conditions; air and nitrogen atmosphere and ethanol, ethanol with added 0.1% TBHQ and ethanol with added 0.1% BHT as solvents. Results for the all-trans-lutein content in the spinach samples and spinach samples with standard addition obtained in air and in nitrogen confirmed the induced degradation of all-trans-lutein in oxygen from the air. Ethanol containing synthetic antioxidant TBHQ under nitrogen atmosphere gave the highest yield of extraction and recovery of all-trans-lutein from spinach.
Carotenoids are tetraterpenes (composed from eight isoprene units) which are synthesized in bacteria, algae, fungi and green plants [
Being strong antioxidants they have a beneficial effect on human health, show antioxidant activity, immunity regulation, and inhibition of tumour cells proliferation [5-7].
Xanthophylls lutein, a non-provitamin A xanthophyll (
Lutein is mostly found in dark green vegetables, such as spinach and kale [9-11]. Spinach (Spinacea olerace L.) is native to West Asia and it is widely cultivated in the world as one of the most popular vegetables. In an analytical chemistry, spinach is often used as a source of violaxanthin and neoxanthin standard since they are not commercially available [12,13].
There are some publications based on the effect of antioxidants during the preparation and analysis of lutein. The most extensively used antioxidant for keeping carotenoids stable is butylated hydroxytoluene (BHT) [
In addition, the effect of tert-butlylhydroqinone (TBHQ) (
one of the most effective antioxidants for protection of fats and oils [
Since TBHQ and BHT are cheap and commercially available we studied their effect on extraction efficiency of all-trans-lutein from the spinach in air and under nitrogen atmosphere. However, the first and principal aim of present study was to develop a simple and the most efficient analytical procedure for extraction of all-translutein from spinach and separation method for carotenoids which could be applied also in other studies.
Lutein standard was from Extrasynthèse (Genay, France). Acetone, ethanol and (TBHQ, purity ≥97%) were obtained from Sigma-Aldrich (St. Louis, MO, USA). Antioxidant 3,5-di-tert-butyl-4-hydroxytoluene (BHT, purity ≥99%) was purchased from Merck (Darmstadt, Germany). All solvents were of analytical grade. Bidistilled water was used.
The lutein stock solutions (65 µg/mL lutein in ethanol, 60 µg/mL lutein in ethanol with 0.1% TBHQ, and 57 µg/mL lutein in ethanol with 0.1% BHT) were sonicated in an ultrasonic bath (Sonis 3 GT, Iskra Pio d.o.o., Šentjernej, Slovenia) for 5 minutes. Additionally, standard solutions around 0.5 μg/mL were prepared with solvents (ethanol, ethanol with 0.1% TBHQ and ethanol with 0.1% BHT) separately. Concentration of standard solutions was checked spectrophotometrically (Lambda 45 UV/VIS, Perkin-Elmer, Massachusetts, USA) before the analysis, with their appropriate blank. Specific absorption coefficient of lutein at 445 nm in ethanol 2550 dm2/g was considered [
Four different fresh spinach samples (Spinacia oleracea L.) were bought at the local market. Leaves of spinach without stems were lyophilized for 24 hours at −50˚C in lyophilirator (Micro Modulyo IMA Edwards, Bologna, Italy) equipped with a rotary vane vacuum pump (Pfeiffer, Asslar, Germany). Dry leaves were pulverized by Mikro-Dismembrator S (Sartorius, Göttingen, Germany) using liquid nitrogen. Obtained powder was weighted and taken as the dried material of fresh spinach leaves. Powdered and dried samples were kept well closed at −80˚C until analysis.
Several samples, 10 mg of lyophilized spinach were exactly weighed, and extracted for 1 hour at room temperature, protected from the sun light with 10 mL of solvents (ethanol, ethanol with 0.1% BHT, ethanol with 0.1% TBHQ). Extractions were performed in glass tubes in air and also under nitrogen atmosphere. The apparatus Carousel 12 Plus (Radleys, Saffron Walden, UK) with magnetic stirrer was used. After the extraction at room temperature extracts were centrifuged (Centric 322A, Tehtnica, Železniki, Slovenia) for 5 minutes at 4000 rpm and the concentrations of all-trans-lutein in supernatant was measured. All experiments were done in duplicate.
Spinach samples with addition of lutein standard were performed as described above. The difference was that the spinach sample was spiked with 0.5 μg/mL of lutein standard solution. The recovery experiments were done in duplicates in glass tubes on the apparatus Carousel 12 Plus in air and under nitrogen, for all spinach samples with three different solvents (ethanol, ethanol with 0.1% TBHQ and ethanol with 0.1% BHT).
RP-HPLC was applied to identify the constituents of spinach extract and to quantify all-trans-lutein content. HPLC analysis was carried out using Surveyor Plus HPLC system (Thermo Finnigan, San Jose, CA, USA), equipped with a thermostated autosampler Surveyor Autosampler Plus, a quaternary pump Surveyor LC Pump Plus and a diode-array detector Surveyor PDA Plus. ChromQuest 4.2 software was used for the data evaluation. For the separation ProntoSIL C30 column, 250 × 4.6 mm, 5 μm particle size (Bischoff Chromatography, Leonberg, Germany), equipped with a Phenomenex C18 guard column (Torrance, California, USA) was used. Mobile phase consisted of acetone (solvent A) and water (solvent B). The following gradient was applied: 80% A to 95% A from 0 to 25 min, 95% A from 25 to 30 min, 95% to 100% A from 30 to 32 min, 100% A from 32 to 37 min, 100% A to 80% A from 37 to 40 min, and 80% A from 40 to 42 min The acquisition wavelength was set at 450 nm and the flow rate was 1 mL/min and injection volume was 20 μL. Quantitative determination of lutein was carried out using external standard method with average response factor, which was injected after every four samples.
All sample test solutions were prepared in duplicate and the mean values were calculated. Statistical analyses were conducted using SPSS software, with Duncan’s multiple range tests. The difference between the means was considered significant at a level of P < 0.05.
Considering the complexity of carotenoid profile in spinach a gradient solvent system of acetone and water was used. Typical chromatogram of carotenoids from spinach is presented in
Sample preparation is the vital step in reliable analysis of lutein. The extraction was made from the lyophilized spinach to avoid possible enzymatic changes, which may occur during the storage of the spinach samples. Powdering the plant material in liquid nitrogen with Dismembrator enabled to get a representative sample despite low weight (10 mg). Enhanced extraction efficiency from the fine particles was achieved. The saponification was not necessary, due to the fact that all-trans-lutein in spinach is in free form and not esterified with fatty acids and that our developed method had separated carotenoids with chlorophylls, which according to Dachtler and coworkers may hinder HPLC analysis [
According to the literature data, the content of all-translutein was about 3 - 13 mg per 100 g of fresh spinach [21-24].
Due to the sensitivity of carotenoids the stabilization in food and foodstuffs samples against oxidation and degradation during the sample preparation and analysis of carotenoids has always been of most importance. Because of proand antioxidant behavior of carotenoids during sample preparation effects of supplemented antioxidants on the extracting procedure were determined.
The content of all-trans-lutein in each of our four spinach samples was extracted with all three solvents. Obtained results are presented in
aContent of lutein in the lyophilized spinach samples normalised on content of lutein obtained by extraction with ethanol in air atmosphere (%).
at the same time nitrogen atmosphere protects lutein from formation of hydroperoxide and further formation of peroxyl radical adducts which could lead to autoxidation.
In our experiment lutein is protected against free radicals (Reaction 1) and also against lutein radical (Reaction 2). This antioxidant protection could not stop the formation of hydroperoxides and autoxidation of lutein when certain higher concentration of oxygen was present (Reactions 4). For this reasons the addition of antioxidants is more preferred when extraction is performed in air atmosphere. When lutein physical quenches singlet oxygen (1O2), the excited lutein molecule is not necessary destroyed. The addition of antioxidants may enable excited triplet state of lutein to safely return to lower level, from where it can undergo into further cycles of singlet oxygen quenching (Reaction 3) [
From the results it is evident that atmosphere with a low concentration of oxygen is the most relevant factor, during the extraction procedure. Antioxidants could reduce degradations of carotenoids during the extraction procedure to certain level, meanwhile the shortage of oxygen prevents formation of hydroperoxides and diminishes the autoxidation and therefore successfully minimizes degradation of all-trans-lutein.
In all four spinach samples, with three different solvents the recovery was also studied (
In recent years reports suggesting beneficial nutritional and physiological effect of carotenoids have increased interest in vegetables as an important source of bioactive carotenoids. Unfortunately, in most cases not enough attention is paid to methods used for sample preparation and analysis of the content of carotenoids. The method reported above is simple, fast and suitable for the analysis of several free major carotenoids and uses small amounts of the sample and organic solvents.
With our study we present how the degradation of lutein during the extraction procedure can be prevented. Sample preparation must be done under nitrogen, some synthetic antioxidant (TBHQ, BHT) should be added to the solvent and careful manipulation of the test solutions is necessary in order to achieve desired accuracy of alltrans-lutein quantification. The addition of synthetic antioxidants to the extraction solvent is necessary if analysis is done without nitrogen protection, nevertheless they may not totally prevent the undesired reactions of degradation of lutein, but they can improve the recovery.
Authors thank the Laboratory for Food Chemistry at National Institute of Chemistry Slovenia for the financial support.