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POLYDEXTROSES

Prepared at the 44th JECFA (1995), published in FNP 52 Add 3 (1995) superseding specifications prepared at the 25th JECFA (1981), published in FNP 19 (1981)

SYNONYMS

Modified polydextroses; INS No. 1200

DEFINITION

Randomly bonded condensation polymers of glucose with some sorbitol end-groups, and with citric acid residues attached to the polymers by mono or diester bonds. They are obtained by melting and condensation of the ingredients and consist of approximately 90 parts D-glucose, 10 parts sorbitol and 1 part citric acid. The 1,6-glucosidic linkage predominates in the polymers but other linkages are present. The products contain small quantities of free glucose, sorbitol, levoglucosan (1,6-anhydro-D-glucose) and citric acid and may be neutralized with potassium hydroxide and/or decolourized. The products may also be partially hydrogenated with Raney nickel catalyst to reduce residual glucose. Polydextrose-N is neutralized Polydextrose.

C.A.S. number

68424-04-4

Assay

Not less than 90.0% of polymer on the ash-free and water-free bases

DESCRIPTION

White to light tan-coloured solid. Polydextroses dissolve in water to give clear, colourless to straw-coloured solutions

FUNCTIONAL USES

Bulking agent, formulation aid, humectant, stabilizer, texturizer, thickening agent

CHARACTERISTICS

IDENTIFICATION

Solubility

Very soluble in water

Test for sugar

To 1 drop of 1 in 10 solution of the sample, add 4 drops of 5% phenol solution, then rapidly add 15 drops of sulfuric acid TS. A deep yellow to orange colour is produced.

Solubility in acetone

With vigorous swirling add 1 ml of acetone to 1 ml of a 1 in 10 solution of the sample. The solution remains clear. With vigorous swirling add 2 ml of acetone to the solution. A heavy, milky turbidity develops immediately.

Test for reducing sugar

To 1 ml of a 1 in 50 solution of the sample, add 4 ml of alkaline cupric citrate TS. Boil vigorously 2-4 min. Remove from heat and let precipitate (if any) settle. The supernatant is blue or blue-green.

PURITY

Water

Not more than 4.0% (Karl Fischer Method)

pH

Not less than 2.5 (for Polydextrose) (1 in 10 soln)

5.0 - 6.0 (for Polydextrose-N) (1 in 10 soln)

Sulfated ash

Not more than 0.3% (for Polydextrose)

Not more than 3.0% (for Polydextrose-N)

Nickel

Not more than 2 mg/kg

Use method Nickel for polyols

1,6-Anhydro-D-glucose

Not more than 4.0% on the ash-free and the dried bases

See description under TESTS

Glucose and sorbitol

Not more than 6.0% combined on the ash-free and the dried bases, glucose and sorbitol are determined separately

See description under TESTS

Molecular weight limit

Negative to test for polymer of molecular weight greater than 22,000

See description under TESTS

5-Hydroxymethylfurfural

Not more than 0.1% in Polydextrose

Not more than 0.05% in Polydextrose-N

See description under TESTS

Arsenic

Not more than 1 mg/kg (Method II)

Test 3 g of the sample

Lead

Not more than 0.5 mg/kg

See description under TESTS

Heavy metals

Not more than 5 mg/kg

Test 4 g of the sample as directed in the Limit Test (Method II)

TESTS

PURITY TESTS

Lead
Apparatus:
Use a suitable atomic absorption spectrophotometer (Perkin-Elmer Model 6000, or equivalent), a graphite furnace containing a L'vov platform (Perkin-Elmer Model HGA-500, or equivalent), and an autosampler (Perkin-Elmer Model AS-40, or equivalent).

Use a lead hollow cathode lamp (lamp current of 10 mA), a slit width of 0.7 mm (set low), the wavelength set at 283.3 nm, and a deuterium arc lamp for background correction. Use argon as the carrier gas. (Note: For this test use reagent-grade chemicals with as low a lead content as practicable, as well as high-purity water and gases. Before use, rinse all glassware and plasticware twice with 10% nitric acid and twice with 10% hydrochloric acid, and then rinse thoroughly with high-purity water.)

Lead Nitrate Stock Solution:
Dissolve 159.8 mg of reagent-grade lead nitrate in 1000.0 ml of water. Prepare and store this solution in glass containers that are free from lead salts. Each ml of this solution contains the equivalent of 100 µg of lead ion.

Standard Lead Solution:
On the day of use, dilute 10.0 ml of Lead Nitrate Stock Solution with water to 100.0 ml, and mix. Each ml of Standard Lead Solution contains the equivalent of 10 µg of lead ion.

Standard Solutions:
Prepare a series of lead standard solutions serially diluted from the Standard Lead Solution. Into separate 100 ml volumetric flasks, pipet 0.2, 0.5, 1, 2 ml, and 5 ml, respectively, of Standard Lead Solution, dilute to volume with water, and mix. The Standard Solutions contain, respectively, 0.02, 0.05, 0.1, 0.2, and 0.5 µg of lead per ml.

Matrix Modifier:
Transfer 100.0 mg of ammonium phosphate, dibasic ((NH4)2HPO4) to a 10 ml volumetric flask, dilute to volume with water, and mix.

Sample Solution: Transfer about 1 g of the sample, accurately weighed, to a 10 ml volumetric flask, add 5 ml of water, and mix. Dilute to volume with water, and mix.

Spiked (fortified) Sample Solution:
Prepare a solution as directed under Sample Solution, but add 100 µl of the Standard Lead Solution, dilute to volume with water, and mix. This solution contains 0.1 µg/ml of added lead.

Procedure:
With the use of an autosampler, atomize 10-µl aliquots of the five Standard Solutions, using the following sequence of conditions: step (1) dry at 130o with a 20-S ramp period, a 40-S hold time, and a 300 ml/min argon flow rate; step (2) char at 800o with a 20-S ramp period, a 40-S hold time, and a 300 ml/min argon flow rate; step (3) atomize at 2400o for 6 S with a 50 ml/min argon flow rate, and read; step (4) clean at 2600o with a 1-S ramp period, a 5-S hold time, and a 300 ml/min argon flow rate; and step (5) recharge at 20o with a 2-S ramp period, a 20-S hold time, and a 300 ml/min argon flow rate. Atomize 10 µl of the Matrix Modifier in combination with 10 µl of the Sample Solution under identical conditions used for the Standard Solutions. Repeat with 10 µl of the Matrix Modifier in combination with 10 µl of the Spiked Sample Solution.

Plot a standard curve using the concentration, in µg/ml, of each Standard Solution versus its maximum absorbance value compensated for background correction, and draw the best straight line. From the Standard Curve, determine the concentrations CS and CA in µg/ml, of the Sample Solution and the Spiked Sample Solution, respectively. Calculate the quantity, in mg/kg, of lead in the sample by the formula:

where

W = the weight, in g, of the sample taken.

Calculate the recovery by the formula:

where

0.1 = the amount of lead, in µg/ml, added to the Spiked Sample Solution.

1,6-Anhydro-D-glucose, glucose and sorbitol
Gas chromatography

- Octadecane Solution: Accurately weigh 50 mg of n-octadecane into a 100-ml volumetric flask and make up to volume with pyridine.

- Monomer Standard Solution: Weigh accurately 50 mg reagent grade I-D-glucose, 40 mg anhydrous D-sorbitol (min. 97% purity), and 35 mg of reagent grade (1,6-anhydro-D-glucose), into a 100-ml volumetric flask and make up to volume with pyridine.

Silylation of monomer standard solution

Transfer 1.0 ml of Monomer Standard Solution to a screw-cap vial and add 1 ml of Octadecane Solution and 0.5 ml of N-trimethylsilylimidazole. Cap the vial and immerse in an ultrasonic bath at 70o for 60 min.

Gas Chromatograph conditions

Glass column, 2.44 m by 2 mm i.d. packed with 3% OV-1 on Gas Chrom Q 100/120 mesh. Flame ionization detector. Temperatures: column 175o; injection port 210o; detector 230o. Retention times (min): 1,6-anhydro-D-glucose, pyranose form 3.7; 1,6-anhydro-D-glucose furanose form (not present in standard) 4.3; n-octadecane 5.1; I-D-glucose 8.7; D-sorbitol 11.3; ß-D-glucose 13.3.

Procedure

Accurately weigh 20 mg of the sample into a screw-cap vial and add 1.0 ml of Octadecane Solution, 1 ml of pyridine, and 0.5 ml of N-trimethylsilylimidazole. Cap the vial and immerse in an ultrasonic bath at 70o for 60 min. Prior to sample analysis, inject 3 µl of the silylated Monomer Standard Solution into the gas chromatograph. Repeat two times, then inject 3 µl of the sample solution. Calculate the percentage of each monomer by the formula:

where

W = the weight of the sample in mg, adjusted for ash and moisture

WS = the weight in mg of the monomer in the Monomer Standard Solution

R = the ratio of the area of the monomer peak to the area of the octadecane peak in the sample injection

RS = the mean ratio of the area of the monomer peak to the area of the octadecane peak in the standard injections.

In the case of glucose, the peak areas for the I and ß epimers and in the case of 1,6-anhydro-D-glucose the peak areas for the pyranose form and furanose form are combined.

Molecular weight limit
Apparatus

Use a suitable high-pressure liquid chromatograph (HPLC) equipped with a differential refractometer, either a loop injector or suitable autosampler, a column heating block or oven and a computing integrator, or computer data handling system with molecular weight determination capabilities. Use a Waters Ultrahydrogel 250 A size exclusion column, or equivalent. The column is maintained at 45o, and the HPLC pump supplies eluent to it at 0.8 ml/min reproducible to 0.5%. The differential refractometer should be set at a sensitivity of 4 x 10-6 refractive index units full scale, and the plotter of the integrator should be set to 64 millivolts full scale. Maintain the detector cell at 35±0.1o. Noise attributable to the detector and electronics should be less than 0.1% full scale.

Eluent

The eluent is 0.1 N sodium nitrate containing 0.025% sodium azide. Dissolve 35.0 g of sodium nitrate and 1.0 g of sodium azide in 100 ml of HPLC-grade water. Filter through a 0.45-µm filter into a 4-l flask. Dilute to volume with HPLC-grade water. De-gas by applying an aspirator vacuum for 30 min.

Standard Solution

Transfer 20 mg each of dextrose, stachyose, 5800, 23,700, and 100,000 MW pullulan standards into a 10 ml volumetric flask. Dissolve in and dilute to volume with Eluent. Filter through a 0.45 µm syringe filter into a suitable autosampler vial, and seal (All components of the Standard Solution are available from Polymer Laboratories, Inc., Technical Center, Amherst Fields Research Park, 160 Old Farm Road, Amherst, MA 01002, USA).

Column Equilibration

After installation of a new column in the HPLC, pump Eluent through it overnight at 0.3 ml/min. Before calibration or analysis, increase the flow slowly to 0.8 ml/min over a 1-min period, then pump at 0.8 ml/min for at least 1 h before the first injection. Check the flow gravimetrically, and adjust it if necessary. Reduce the flow to 0.1 ml/min when the system is not in use.

Data System Setup

Set the integrator or computerized data handling system as their respective manuals instruct for normal gel permeation chromatographic determinations. Set the integration time to 15 min.

Column Standardization

After the HPLC system has been equilibrated at a flow rate of 0.8 ml/min for at least 1 h, inject 50 µl of the Standard Solution five times, allowing 15 min between injections. Record the retention times of the various components in the Standard Solution. Retention times for each component should agree within ± 2 s. Insert the average retention time along with the molecular weight of each component into the calibration table of the molecular weight distribution software.

System Suitability

Check the regression results for a cubic fit of the calibration points. They should have an R2 value of 0.9999+. Dextrose and stachyose should be baseline-resolved from one another and from the 5800 MW pullulan standard. Elevated valleys are usually observed between the 5800, 23,700 and 100,000 MW pullulan standards.

Sample Preparation

Transfer 50 mg of sample, accurately weighed, into a 10 ml volumetric flask. Dissolve in and dilute to volume with Eluent. Filter through a 0.45 µm syringe filter into a suitable autosampler vial.

Procedure

Inject 50 µl of the Sample Preparation, following the same conditions and procedure as described under Column Standardization. Using the Formula weight Distribution software of the data reduction system, generate a molecular weight distribution curve of the sample. There is no measurable peak above a molecular weight of 22,000.

5-Hydroxymethylfurfural (HMF)
Principle

HMF solutions absorb light in the ultraviolet region. The maximum absorption occurs at 283 nm and the molar extinction coefficient is 16,830 at that wavelength. The HMF concentration in polydextrose solutions is determined from the optical density at 283 nm and the application of the Beer-Lambert law.

Apparatus

- Standard laboratory equipment

- Ultraviolet spectrophotometer

- Spectrophotometer cells (quartz), 1.00 cm path length

Procedure

Accurately weigh 1.00±0.01 g of the sample into a 100-ml volumetric flask and make up to volume with distilled water (for polydextrose-N 70% solution use 1.43 ± 0.01 g sample). Read the optical density of this solution against a water blank at 283 nm in a 1.00 cm quartz cell in the spectrophotometer according to the directions supplied with the instrument. Under these conditions, the % HMF in the original sample is 0.0749 x optical density, on the dried basis.

Calculation

where

C = % HMF in the original polydextrose sample

M = HMF molecular weight

D = optical density of the solution

L = the path length of the spectrophotometer cell

E = the molar extinction coefficient for HMF

The numbers 100 and 10 are factors to convert solution concentration in mg/l to % HMF in the original sample, on the dried basis.

METHOD OF ASSAY
Phenol Solution

Add 20 ml of water to 80 g of phenol.

Glucose Standard Solutions

Weigh accurately 100 mg of I-D-glucose (minimum 97% purity) into a 500-ml volumetric flask and make up to volume with distilled water. Dilute five aliquots of the solution with distilled water to obtain the following concentrations of standard: 50, 40, 20, 10 and 5 µg/ml.

Standard Curve

Run each analysis in triplicate. On a daily basis, pipet 2.0 ml of each of the Glucose Standard Solutions into 4-dram acetone-free screw-cap vials. Add 0.12 ml of the phenol solution and mix gently. Uncap vials and add rapidly 5 ml of sulfuric acid TS. Immediately recap the vials and shake vigorously.

CAUTION: Rubber gloves and safety shield should be used in the sulfuric acid addition step.

Let the vials stand at room temperature for 45 min. Determine absorbances at 490 nm in a suitable spectrophotometer, using a Phenol Solution-sulfuric acid mixture as a blank in the reference cell. Plot mean absorbances versus concentrations in µg/ml.

Procedure

In triplicate, weigh accurately about 250 mg of the sample into a 250-ml volumetric flask and make up to volume with distilled water. Transfer a 10 ml aliquot to a 250-ml volumetric flask and make up to volume with distilled water. Proceed as in Standard Curve. Calculate the percentage of polymer by the formula:

where

A = the sample absorbance

S = the slope of absorbance versus glucose concentration in µg/ml obtained from the Standard Curve

C = the concentration of the sample solution in µg/ml (adjusted for ash and moisture)

PG and P1 = the percentages of glucose and 1,6-anhydro-D-glucose, respectively, determined by the tests for monomers (see Purity tests for 1,6-Anhydro-D-glucose, glucose and sorbitol as described above).

Source: Joint FAO/WHO Expert Committee on Food Additives (JECFA)

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