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Grape seed extract is a heterogeneous mixture of gallic
acid, monomers, dimers, trimers, tetramers, polymers and other oligomers. The basic
building blocks are molecules of catechin, epicatechin, epicatechin gallate, gallic acid
esters, glycosides and peptides. Due to the high degree of heterogeneity, several
analytical techniques are required to characterize grape seed extract.
TLC (Thin Layer Chromatography)
- What is measured:qualitative separation of phenolics, used to determine if the extract
is grape based
- Type of method:chromatographic, based on size and polarity of phenolics
- Standard:gallic acid, catechin, epicatechin and a commercially available grape seed
extract
- Issues: qualitative only, can not distinguish between grape skin and grape seed
lack of a non-partisan "commercial" grape seed extract standard
- Grape Seed Method Evaluation Committee has adopted this method "industry wide"
to qualitatively assess if an extract is grape based
This procedure was proffered by ESA Laboratories and includes normal phase TLC
separation of preacetylated powder extracts
In 1998 three independent laboratories (Alpha Chemical Laboratory, Industrial
Laboratory, and PhytoChem) validated the TLC method by testing 14 grape seed extracts,
bilberry, green tea, pycnogenol and cranberry extracts as well as 13 finished products.
This is a qualitative test designed to identify grape seed extract and differentiate it
from botanicals that may have similar components.
Procyanidolic Value and Porter Value
The Procyanidolic assay is also referred to as the Bate-Smith assay.
- What is measured:phenolic dimers and larger, qualitative value that indicates relative
presence
- Type of method:spectrophotometric, based on acid hydrolysis and color formation
- Standard:none
- Issues:poor reproducibility (procyanidolic is the least reproducible)
larger molecules give higher values
- Grape Seed Method Evaluation Committee recommends that these methods are not used for
quantification of total phenols or OPC’s in grape seed extracts
The "Procyanidolic Index" (also called the Bates-Smith Assay) involves a
testing method that measures the change in color when the product is mixed with certain
chemicals; the greater the color in change, the higher the OPCs. It must be noted,
however, that the Procyanidolic Index is a relative value that can measure well
over 100. Unfortunately, a Procyanidolic Index of 95 was erroneously taken to mean 95% OPC
by some and began appearing on the labels of finished products. . All current methods of
analysis suggest that the actual OPC content of these products is much lower than 95%.
The Porter and Procyanidolic value assays are colorimetric tests based on acid
hydrolysis. Dimer and larger molecules are converted to anthocyanidins by acid hydrolysis.
A standard curve is not incorporated and thus results can only be reported as values, not
as percentages. Another artifact of these two assays is that on a molar basis the values
increase with molecular size, i.e. if a grape seed extract is comprised primarily of
larger polymers, it will have higher Procyanidolic and Porter values than an extract
comprised of the same molar concentration of dimers.
It is also difficult to obtain reproducible results with the Procyanidolic value assay,
as the results are very dependent on the testing conditions and cyanidin (the
anthocyanidin formed during the acid hydrolysis step) is relatively unstable. Dr. V.L.
Singleton, a world-renowned authority on grape phenols commented on the Procyanidolic
assay "values obtained are necessarily somewhat arbitrary". Three independent
laboratories conducted a study on both the Porter and Procyanidolic value assays in early
1997 (Industrial Laboratories, Alpha Chemical and Biomedical Laboratories and Hauser) and
found large lab-to-lab variation in the Procyanidolic assay. Some companies utilize a
modified Bate-Smith assay to increase the reproducibility of results. The Porter assay
contains ammonium iron (III) sulfate, which stabilizes the reaction better than in the
Procyanidolic assay and renders the results less dependent on conditions.
Procyanidolic assay
proanthocyanidins (dimers & larger) + HCl/isopropanol + heat = cyanidin, Abs 550 nm
Porter assay
proanthocyanidins (dimers & larger) + NH4Fe(SO4)2 · 12 H2O + HCl/n-butanol + heat = cyanidin, Abs 550 nm
The chemical reaction to the right depicts both the Porter value and Procyanidolic
Value assays.
Total phenols (Folin-Ciocalteau)
- What is measured:concentration of total phenols
- Type of method:spectrophotometric, based on a colorimetric oxidation/reduction reaction
- Standard:gallic acid
- Issues:all phenolic groups are quantitated (e.g. quercetin, anthocyanins, green tea
phenolicscan not tell if an extract is adulterated
can not differentiate types of phenol
present (e.g. monomer vs. dimer vs. trimer)
the presence of proteins, nucleic acids and ascorbic acid could alter the response
factor
- Method has been used in the wine industry for over 30 years
- Grape Seed Method Evaluation Committee has agreed to examine this method as possible
"industry wide" method
This is a colorimetric oxidation/reduction assay that measures all phenolic molecules
with no differentiation between gallic acid, monomers, dimers and larger phenolic
compounds. A gallic acid standard curve is used and results are typically expressed as
gallic acid equivalents (GAE). This method has been used in the wine industry for over 30
years. The first paper on this method was published in 1927 and in 1965 Singleton and
Rossi improved the reproducibility of the assay. Swain and Goldstein considered this the
method of choice for estimating total phenol content in complex plant products. This is a
sensitive and quantitative method, independent of the degree of polymerization.
phenolics + alkaline + FC reagent + heat = blue colored product, Abs 755 nm
FC reagent is an oxidizing agent comprised of heteropolyphosphotungstate-molybdate. The
blue colored product is a mixture of the 1-, 2-, 4-, and 6-electron reduction products in
the tungstate series P2W18O62-7 to H4P2W18O62-8
and the 2-, 4-, and 6-electron reduction products in the molybdate series H2P2Mo18O62-6
to H6P2Mo18O62-6.
Some work has been initiated to determine if monomers react differently than larger
molecules in this assay. Preliminary results show that the standard F-C assay may be
biased in favor of grape seed extracts with high monomer contents since monomers and OPCs
in grape seed extracts have different response factors. (See Addendum A: Calculation of
Monomer Bias Correction Factor.) Label claims based on these results will be relative to
the response factor of the compounds being tested. There is no study that we are presently
aware of that has made a definitive 1:1 correlation between the mass of OPCs (monomers,
oligomers or polymers) and an equal quantity of gallic acid. The method can be used for
standardization, but not direct quantitation. Work is continuing in this area.
This method has been cited as being the Association of Official Agricultural
Chemists’ method for determining total polyphenol content in wines.
Vanillin assay,
with methanol as the solvent
- What is measured:flavan-3-ols
- Type of method:spectrophotometric
- Standard:catechin
- Issues:color production is dependent on many factors
kinetics of the reaction are complicated
a pure sample is required
- Grape Seed Method Evaluation Committee has agreed to move away from this method
with glacial acetic acid as the solvent
- What is measured:flavan-3-ols
- Type of method:spectrophotometric, color formation is directly related to the
concentration offlavan-3-ol end groups
- Standard:catechin
- Issues:concentration of phenol affects the degree of polymerization a pure sample is
required
- Grape Seed Method Evaluation Committee has agreed to move away from this method
The vanillin assay has been utilized in the cereal industry since the 1950’s. Dr.
Larry Butler (Purdue University) has done many comparative studies with sorghum. The
kinetics of the reaction are different with the two solvents (methanol and glacial acetic
acid), with methanol yielding the more complicated kinetics. With glacial acetic acid the
reaction kinetics are less complex (i.e. monomers and polymers react similarly), the
reaction only occurs at the end groups, and the colored product which is formed and
measured is more stable. Obtaining reproducible results with the vanillin assay with
methanol may be difficult. The person running the analysis must be well-trained and the
results are dependent on such techniques as the angle the methanol is added to the vial.
The article by Butler et. al contains the statement "for convenience, catechin, a
monomeric flavan-3-ol unit of condensed tannins, is often used to standardize the assay
rather than purified condensed tannin, although this leads to a considerable
overestimation of tannin content". Further in the article it is also stated that
"methanol affects the reaction with flavan-3-ol monomers and their oligomeric and
polymers quite differently, producing complex kinetic patterns that make standardization
of tannin analysis with monomers such as catechin tenuous at best."
Reverse Phase HPLC (High Pressure Liquid Chromatography)
- What is measured:relative % monomers, oligomers and polymers percent of gallic acid,
catechin and epicatechin by weight
Type of method:chromatographic, based on polarity of phenolics
- Standard:monomer standards are readily available - gallic acid, catechin, epicatechin,
epicatechin gallate
- Grape Seed Method Evaluation Committee has agreed to adopt this method "industry
wide" to determine % monomers in grape seed extract
With this method the percent by weight of gallic acid and phenolic monomers such as
catechin, epicatechin and epicatechin gallate can be determined by using readily available
standards from such companies as Sigma/Aldrich. Unfortunately, except for one dimer, no
large molecule phenolics are commercially available.
In past experiences grape seed manufacturers have found that there is no standard
RP-HPLC procedure among independent laboratories and that a simple request for % monomers
will yield different results as well as different compounds. If this analysis is to be
performed by an independent laboratory the monomers of interest (i.e. those typically
found in grape seed extract) must be stated: catechin, epicatechin, and epicatechin
gallate, as well as gallic acid (a phenolic acid). Depending on the solvents used and the
length of the run some of the monomer peaks may co-elute with other phenolics. Care needs
to be given to ensure that peaks of interest are pure peaks (i.e. no co-elution) and that
the larger phenolic molecules are flushed from the column prior to subsequent runs.
GPC (Gel Permeation Chromatography)
- What is measured:concentration of total phenols
- Type of method:chromatographic, based on size of phenolics
- Standard:"a well characterized" reference material, attempts have been made to
test catechin or
epicatechin but these two monomers have different absorptions at 280nm.
- Issues:short life span of column
not everyone has the necessary instrumentation
use of a non-partisan standard
difficult to differentiate types of phenol present (e.g. monomer vs. dimer vs. trimer)
some have noted that larger molecules seem to "stick on the column"
- Grape Seed Method Evaluation Committee has agreed to examine this method as possible
"industry wide" method
The basic principle of gel permeation chromatography is that molecules are separated by
size on a specific column and when they elute the intensity of absorbency is measured at a
specific wavelength, 280nm for phenols. All of the molecules tend to elute in a hump and
the peak area of the hump is directly proportional to the concentration of phenols in the
product, relative to the "reference material". An internal standard is used to
improve the accuracy of the results. Fuzzati et. al. identified three separate regions of
the "hump" as 1) monomers, 2) monomers, dimers and their gallates and 3) trimers
through heptemers and their gallates based on a "well characterized reference
material" and mass spectroscopy.
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