Determination of organic acids and mineral anions in wines by Ionic chromatography
RESOLUTION OENO 23/2004
DETERMINATION OF ORGANIC ACIDS AND MINERAL ANIONS IN WINES BY IONIC CHROMATOGRAPHY
THE GENERAL ASSEMBLY,
IN VIEW of Article 2 paragraph 2 iv of the Agreement of 3 April 2001 establishing the International Organisation of Vine and Wine,
UPON PROPOSAL of the Sub-Commission of methods of analysis and appraisal of wine,
DECIDES to complete Annex A of the Compendium of international methods of analysis of wines and musts, by the following IV type method:
DETERMINATION OF ORGANIC ACIDS AND MINERAL ANIONS IN WINES BY IONIC CHROMATOGRAPHY
Preamble
The development of high performance ionic chromatography in laboratories has enabled the study the determination of organic acids and mineral anions in alcoholic and non alcoholic beverages by this technique.
Particularly concerning the analysis of wines, the results of intercomparison test trials and the measurements of recovery rates have enabled us to validate an analytical methodology.
The major interest of this method is that the ion exchange columns allow the separation of most organic acids and anions, and the detection by conductimetry frees the analysis from interferences due to the presence of phenolic compounds. This type of interference is very notable in chromatographic methods that include detection in ultra-violet radiation at 210 nm.
1. OBJECT AND FIELD OF APPLICATION
This method for mineral anions and organic acids by ionic chromatography is applicable to alcoholic beverages (wines, wine spirits and liqueurs). It enables the determination of organic acids in the ranges of concentration listed in table 1; these concentrations are obtained by diluting samples.
Table 1: range of concentration of anions for their analysis by ionic chromatography
Sulfate |
0.1 to 10 mg/l |
Ortho-phosphate |
0.2 to 10 mg/l |
Malic acid |
1 to 20 mg/l |
Tartaric acid |
1 to 20 mg/l |
Citric acid |
1 to 20 mg/l |
Isocitric acid |
0.5 to 5 mg/l |
The ranges of the above-mentioned work are given as an example. They include the methods of calibration commonly practiced and are therefore adaptable according to the type of apparatus used (nature of column, sensitivity of the detector, etc.) and procedure (volume of sample injected, dilution, etc.).
2. PRINCIPLE
Separation of mineral and organic anions on an ion exchanger resin.
Detection by conductimetry.
Identification after the retention time and quantification using the calibration curve.
3. REAGENTS
All the reagents used during the analysis must be of analytical quality. The water used for the preparation of solutions must be distilled or deionised water of a conductivity lower than 0.06 µS, free from anions determined at thresholds compatible with the detection limits of the apparatus used.
3.1. Eluant
The composition of the eluant depends on the nature of the separation column and the nature of the sample to be analysed. Nevertheless it is always prepared using aqueous solutions of sodium hydroxide.
The performances of the chromatographic analysis are alternated by carbonation of the sodium hydroxide solution; consequently, the mobile phase flasks are swept with helium before adding sodium hydroxide and all precautions should be taken in order to avoid contaminating them with room air.
Lastly, commercial concentrated sodium hydroxide solutions will be used.
Remark
The table in chapter 9 mentions the main interferents susceptible of being present in the samples.
It is therefore necessary to know beforehand if they coelute with the ions to be determined and if they are present at such a concentration that the analysis is disrupted.
Fermented drinks contain succinic acid which can interfere with the malic acid determination. To this effect, it is necessary to add methanol to the eluant in order to improve the resolution of the column for these two substances (20% of methanol).
3.2. Calibration reference solutions
Prepare calibration reference solutions of precise concentrations close to those indicated in the following table. Dissolve in water, quantities of salts or corresponding acids in 1000 ml volumetric flasks. (Table 2)
Table 2: Concentration of anions determined in calibration reference solutions
Anions and acids |
Compounds weighed |
Concentration final (mg/l) |
Quantity weighed (mg) |
Sulphate |
500 |
738.5 |
|
Orthophosphate |
700 |
1003.1 |
|
Malic acid |
Malic acid |
1000 |
1000.0 |
Tartaric acid |
Tartaric acid |
1000 |
1000.0 |
Citric acid |
Citric acid, |
1000 |
1093.8 |
Isocitric acid |
Isocitrate 3Na, 2 |
400 |
612.4 |
Remark
The laboratory must take the necessary precautions regarding the hygroscopic character of certain salts.
3.3. Calibration solutions
The calibration solutions are obtained by diluting the reference solutions of each ion or acid in water.
These solutions should contain all the ions or acids determined in a range of concentrations covering those corresponding to the samples to be analysed. They must be prepared the day of their use.
At least two calibration solutions and a blank must be analysed so as to establish, for each substance, the calibration curves using three points (0, maximum semi-concentration, maximum concentration).
Remark
Table 1 gives indications on the maximum concentrations of anions and acids in calibration solutions but the performances of the chromatographic columns are better with very diluted solutions.
So the best adequation possible between the performances of the column and the level of dilution of the samples should be looked for.
In general, the sample is diluted between 50 and 200 times maximum except for particular cases.
For prolonging the life span of the dilution solutions, it is preferable to prepare them in a water/methanol solution (80/20).
4. APPARATUS
4.1. Instrument system for ionic chromatography including:
4.1.1. Eluant reservoir(s)
4.1.2. Constant-stroke pump, without pulsing action
4.1.3. Injector, either manual or automatic with a loop sampling valve (for example 25 or 50 µl)
4.1.4. Separation columns
System made up of an anion exchanger column of controlled performance, possibly a precolumn of the same type as the main column. For example, it is possible to use the AS11 columns and DIONEX® AG11 precolumn.
4.1.5. Detection system
Circulation conductivity cell of very low volume connected to a conductivity meter with several ranges of sensitivity.
In order to lower the conductivity of the eluant, a chemical suppression mechanism, a cation exchanger is installed in front of the conductivity cell.
4.1.6. Recorder, integrator or other device for the treatment of signals.
4.2. Precise balance to 1 mg
4.3. Volumetric flasks from 10 to 1000 m
4.4. Calibrated pipettes from 1 to 50 ml
4.5. Filtrating membranes with an average pore diameter of 0.45 µm.
5. SAMPLING
The samples are diluted while taking into account the mineral anions and organic acids that are to be determined.
If their concentration is very variable in the sample, two levels of dilution will be necessary in order to respect the ranges of concentration covered by the calibration solutions.
6. PROCEDURE
Turn on the apparatus by following the manufacturer’s instructions.
Adjust the pumping (eluant flux) and detection conditions so as to obtain good separations of the peaks in the range of concentrations of ions to be analysed.
Allow the system to balance until a stable base line is obtained.
6.1. Calibration
Prepare the calibration solutions as indicated in 3.3.
Inject the calibration solutions so that the volume injected is at least 5 times that of the sampling loop to allow the rinsing of the system.
Trace the calibration curves for each ion. These must normally be straight.
6.2. Blank trial
Inject the water used for the preparation of the calibration solutions and samples.
Control the absence of parasite peaks and quantify the mineral anions present (chloride, sulphate, etc.).
6.3. Analysis
Dilute the sample possibly at two different levels as indicated in 5, so that the anions and acids to be determined are present in the range of concentrations of the calibration solutions.
Filter the diluted sample on a filtrating membrane (4.5) before injection.
Then proceed as for the calibration (6.1).
7. REPEATABILITY, REPRODUCIBILITY
An interlaboratory circuit tested this method, but this does not constitue a formal validation according to The OIV protocol (Oeno 6/99).
A repeatability limit and a reproducibility limit for the determination of each ion in wine were calculated according to the ISO 5725 standard.
Each analysis was repeated 3 times.
Number of participating laboratories: 11; the results were as follows:
White wine |
||||
No labs |
Average (mg/l) |
Repeatability (mg/l) |
Reproducibility (mg/l) |
|
Malic acid |
11/11 |
2745 |
110 |
559 |
Citric acid |
9/11 |
124 |
13 |
37 |
Tartaric acid |
10/11 |
2001 |
96 |
527 |
Sulphate |
10/11 |
253 |
15 |
43 |
O. phosphate |
9/11 |
57 |
5 |
18 |
Red wine |
||||
No labs |
Average (mg/l) |
Repeatability (mg/l) |
Reproducibility (mg/l) |
|
Malic acid |
8/11 |
128 |
16 |
99 |
Citric acid |
8/10 |
117 |
8 |
44 |
Tartaric acid |
9/11 |
2154 |
48 |
393 |
Sulphate |
10/11 |
324 |
17 |
85 |
O. phosphate |
10/11 |
269 |
38 |
46 |
8. CALCULATION OF RECOVERY RATE
The supplemented sample is a white wine.
Determination |
No labs |
Concentration initial (mg/l) |
Real addition (mg/l) |
Measured addition (mg/l) |
Recovery rate (%) |
Citric acid |
11/11 |
122 |
25.8 |
24.2 |
93.8 |
Malic acid |
11/11 |
2746 |
600 |
577 |
96.2 |
Tartaric acid |
11/11 |
2018 |
401 |
366 |
91.3 |
9. RISKS OF INTERFERENCES
Any substance whose retention time coincides with that of one of the ions analysed can constitute an interference.
The most common interference include the following:
Anions or acids |
Interferents |
Nitrate |
Bromide |
Sulphate |
Oxalate, maleate |
Orthophosphate |
Phtalate |
Malic acid |
Succinic acid, Citrmalic acid |
Tartric acid |
Malonic acid |
Citric acid |
- |
Isocitric acid |
- |
Remark
The addition of methanol in the mobile phase can resolve certain analytical problems.
For example:
- The presence of methanol in the mobile phase is not always required; however it is necessary for obtaining a suitable resolution between succinic acid and malic acid during the analysis of wines.
- The oxalate and sulphate ions coelute with most chromatographic conditions; 13% of methanol is needed in the mobile phase for separating them.
- The resolution of peaks corresponding to acetic and lactic acids is satisfactory if a gradient elution in sodium hydroxide without methanol is performed.
10. EXAMPLES OF CHROMATOGRAMMES
Annex (a)
Chromatogramme of a calibration solution for organic acids and mineral anions: chloride (1.96 mg/l), nitrate (2.21 mg/l), malic acid (5.35 mg/l), tartaric acid (5.08 mg/l), sulphate (2.8 mg/l), O.phosphate (3.9 mg/l), citric acid (3.24 mg/l), isocitric acid (1.6 mg/l), given as an example.
DIONEX apparatus used: Pump, PED Detecteur, AMMSII suppressor with AUTOREGEN, AS11 column and AG11 precolumn.
Rate 2ml/mn -
Mobile phase 1: Water-NaOH 0.5mM/l, methanol (80/20)
Mobile phase 2: Water-NaOH 100mM/l, methanol (80/20)
Gradient elution: 100% Mobile phase 1 to 65% mobile phase 1 in 25 min.
Annex (b)
Chromatogramme of a rosé wine diluted 200 times: given as an example
DIONEX apparatus used: Pump, PED Detecteur, AMMSII suppressor with AUTOREGEN, AS11 column and AG11 precolumn.
Rate 2ml/mn -
Mobile phase 1: Water-NaOH 0.5mM/l, methanol (80/20)
Mobile phase 2: Water-NaOH 100mM/l, methanol (80/20)
Gradient elution: time zero 100% Mobile phase 1 to time 25 min 65% mobile phase 1.