Reporting%20Results%20and%20Reliability%20of%20Analyses

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Reporting%20Results%20and%20Reliability%20of%20Analyses

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Title: Reporting%20Results%20and%20Reliability%20of%20Analyses

1
Reporting Results and Reliability of Analyses
1
introduce
2
Reporting Results
3
Reliability of Analyses
2
Reporting Results and Reliability of Analyses

The basic purpose of an analytical assay
is to determine the mass (weight) of a component
in a sample. The numerical result of the assay is
expressed as a weight percentage or in other
units that are equivalent to the mass/mass ratio.
The mass (weight) of a component in a food sample
is calculated from a determination of a parameter
whose magnitude is a function of the mass of the
specific component in the sample.
Some properties are basically mass
dependent. Absorption of light or other forms of
radiant energy is a function of the number of
molecules, atoms, or ions in the absorbing
species. Although certain properties, such as
specific gravity and refractive index, are not
mass dependent, they can be used indirectly for
mass determination. Thus, one can determine the
concentration of ethanol in aqueous solutions by
a density determination. Refractive index is used
routinely to determine soluble solids (mainly
sugars) in syrups and jams. Some mass-dependent
properties may be characteristic of several or
even of a single component and may be used for
selective and specific assays. Examples are light
absorption, polarization, or radioactivity. Some
properties have both a

magnitude and a specificity parameter
(nuclear magnetic resonance and infrared
spectroscopy). Such properties are of great
analytical value because they provide selective
determinations of a relatively large number of
substances.
In this chapter, we describe conventional
ways of expressing analytical results and discuss
the significance of specificity, accuracy,
precision, and sensitivity in assessing the
reliability of analyses.
In recent years the metric SI system of
units has gained worldwide acceptance. It has
been recommended or required by International
Union of Pure and Applied Chemistry (IUPAC), and
the International Union of Pure and Applied
Physics (IUPAP), as well as by an increasing
number of scientific and professional
organizations in the United States and by the
industry and the trade. The SI system contains
seven base units, two supplementary units, 15
derived units having special names, and 14
prefixes for multiple and submultiple units. All
physical properties can be quantified by 38 names.

4
Reporting Results

In reporting analytical results, both the
reference basis and the units used to express the
results must be considered. For example, analyses
can be performed and the results reported on the
edible portion only or on the whole food as
purchased. Results can be reported on an as-is
basis, on an air-dry basis, on a dry matter
basis, or on an arbitrarily selected moisture
basis (e.g., 14 in cereals).
To convert contents () of component Y from
oven-dried (OD) to an as-received (AR) basis, or
vice versa, the following formulas are used

To convert contents from an as-received
basis to an arbitrary moisture basis, the
following formula is used

To weight out a sample on an arbitrary
moisture (AM) basis, use the following

To obtain dry matter, subtract
percentage of moisture from 100. If the moisture
has been determined in two stages, air drying
followed by oven drying, compute total moisture
contents of sample as follows
Where TM is the total moisture, A the
moisture loss in air drying, and B the moisture
of air-dried sample as determined by oven drying.

Tables, nomograms, and calculators are
available to simplify calculations in expressing
results on a given basis, or for weighing samples
on a fixed moisture basis (e.g., 20 in dried
fruit). In view of the very wide range in
moisture contents in various foods, analytical
results are often meaningless unless the basis of
expressing the results is known.
Expressing analytical results on an as-is
basis is wrought with many difficulties. It is
practically impossible to eliminate considerable
desiccation of fresh plant material. In some
instances, even if great pains are taken to
reduce such losses, the results may still vary
widely. For example, the moisture contents of
leafy foods may vary by as much as 10 depending
on the time of harvest (from early morning to
late afternoon). Similarly, the moisture contents
of bread crust and crumb change from the moment
bread is removed from the oven as a result of
moisture migration and evaporation. Absorption of
water in baked or roasted low-moisture foods
(crackers, coffee) is quite substantial. In most
cases, storing air-dried foods in hermetically
closed containers is least

troublesome. Once the moisture contents of
such foods are determined, samples can be used
for analyses over a reasonable period.
The concentrations of major components are
generally expressed on a percentage by weight or
percentage by volume basis. For liquids and
beverages, g per 100mL is often reported. Minor
components are calculated as mg (or mcg) per kg
or L vitamins in mcg or international units per
100g or 100mL.Amuunts of spray residues are often
reported in ppm (parts per million).
In calculating the protein contents of a
food, it is generally assumed the protein
contains 16 nitrogen. To convert from organic
nitrogen (generally determined by the Kjeldahl
method see Chapter 37) to protein, the factor of
6.25100/16 is used. In specific foods known to
contain different concentrations of nitrogen in
the protein, other conversion factors are used
(5.7 in cereals, 6.38 in milk). Heidelbaugh et
al. (1975) compared three methods for calculating
the protein content of 68 foods (1)
multiplication of Kjeldahl nitrogen by 6.25 (2)
multiplication of Kjeldahl nitrogen by factors
ranging

from 5.30 to 6.38 depending on the type of
food and (3) calculation on the basis of amino
acid composition, determined by chemical
analyses. Up to 40 differences in protein
content were found depending on the calculation
method. There were, however, only small
differences in mixed diets representing typical
menus.
If a food contains a mixture of
carbohydrates, the sugars and starch are often
expressed as dextrose. In lipid analyses (free
fatty acids or total lipid contents) calculations
are based on the assumption that oleic acid is
the predominant component. Organic acids are
calculated as citric, malic, lactic, or acetic
acid depending on the main acid in the fruit or
vegetable.
Mineral components can be expressed on an
as-is basis or as of total ash. In either case
the results can be calculated as elements or as
the highest valency oxide of the element.
Amino acid composition can be expressed in
several ways g amino acid per 100 g of sample,
or per 100 g of protein, or per 100 g of amino
acids. For the determination of molar
distribution of amino acids in protein, g-mol of
amino acid residue per 100 g-mol of amino

acid are computed.
In trade and industry, empirical tests
are often used. For example, fat acidity of
cereal grains is often expressed as mg KOH
required to neutralize the fatty acids in 100 g
of food. Acidity is often expressed for
simplicity in milliliters of N/10 or N NaOH. The
acidity of acid phosphates in baking powders is
reported in industry as the number of parts of
sodium bicarbonate that are required to
neutralize 100 parts of the sample.

BACK
12
Reliability of Analyses

The reliability of an analytical method
depends on its (1) specificity, (2) accuracy, (3)
precision, and (4) sensitivity (Anastassiadis and
Common 1968).
Specificity is affected primarily by the
presence of interfering substances that yield a
measurement of the same kind as the substance
being determined. In many cases, the effects of
the interfering substances can be accounted for.
In calculating or measuring the contribution of
several interfering substances, it is important
to establish whether their effects are additive.
Accuracy of an analytical method is
defined as the degree to which a mean estimate
approaches a true estimate of an analyzed
substance, after the effects of other substances
have been allowed for by actual determination or
calculation. In determining the accuracy of a
method, we are basically or calculation. In
determining the accuracy of a method, we are
basically interested in establishing the
deviation of an analytical method from an ideal
one. That deviation may be due to an inaccuracy
inherent in the procedure the effects of
substances other than the analyzed one in the food

sample and alterations in the analyzed
substance during the course of the analysis.
The accuracy of an analytical assay
procedure can be determined in two ways. In the
absolute method, a sample containing known
amounts of the analyzed components is used. In
the comparative method, results are compared with
those obtained by other methods that have been
established to gibe accurate and meaningful
results.
The absolute method is often difficult or
practically impossible to apply, especially for
naturally occurring foods. In some cases, foods
can be prepared by processing mixtures of pure
compounds. If the mixtures are truly comparable
in composition to natural foods, meaningful
information is obtained.
Several indirect methods are available to
determine the accuracy of analyses. Although
these methods are useful in revealing the
presence of errors they cannot prove the absence
of errors. When a complete analysis of a sample
is made and each component is determined
directly, a certain degree of accuracy is
indicated if the

sum of the components is close to 100. On
the other hand, an apparently good summation can
result from compensation of unrelated errors in
the determination of individual components. A
more serious error can result from compensation
of errors that are related in such a way that a
negative error in one component will cancel a
positive error in another component. This may be
particularly important in incomplete
fractionations. For example, the sum of proteins
separated according to differences in solubility
may be close to 100, yet the separation of
individual components may be incomplete or of
limited accuracy.
In the recovery method, known amounts of a
pure substance are added to a series of samples
of the material to be analyzed and the assay
procedure is applied to those samples. The
recoveries of the added amounts are then
calculated. A satisfactory recovery is most
useful in demonstrating absence of negative
errors.

If the accuracy of an analytical method is
affected by interference from substances that
cannot be practically eliminated, a suitable
correction can sometimes be applied. Such a
correction is often quite complicated because the
results may be affected by concentration of the
interfering or assayed substance, or by their
interaction in food processing or during the
analyses.
Precision of a method is defined as the
degree to which a determination of a substance
yields an analytically true measurement of that
substance. It is important to distinguish clearly
between precision and accuracy. In industrial
quality control, it often is unimportant whether
analysis of numerous similar samples yields
exactly accurate (i.e., true) information
regarding the composition of the sample. The
information may be useful provided the difference
between the precise and accurate determination is
consistent. The analysis that gives the actual
composition (or in practice the most probable
composition) is said to be the most accurate. For
instance, direct and accurate determination of
the bran content can be estimated directly from
the amount of crude fiber in a flour. This

estimation is based on the fairly constant
ratio between crude fiber (determined by a
precise, but not accurate, empirical method) and
actual bran contents. Still simpler is the
estimation of bran content from total mineral
content or reflectance color assay of a flour.
To determine the precision of an
analytical procedure and the confidence that can
be placed on the results obtained by that
procedure, statistical methods are used. The most
basic concept in statistical evaluation is that
any quantity calculated from a set of data is an
estimate of an unknown parameter and that the
estimate is sufficiently reliable. It is common
to use English letters for estimates and Greek
letters for true parameters.
If n determinations x1,x2,.xn
are made on a sample, the average is
an estimate of the unknown true value . The
precision of the assay is given by the standard
deviation

If the number of replicate determinations
is small (lt10), an estimate of the standard
deviation ( s ) is given by
The divisor n-1 used to estimate s is
termed the degrees of freedom and indicates that
there are only n-1 independent deviations from
the mean. The standard deviation is the most
useful parameter for measuring the variability of
an analytical procedure.
If s is independent of x for a given
concentration range, s can be computed from
results of replicate analyses on several samples
of similar materials. In that case, the sums of
the squares of the deviations of the replicates
of each material are added, and the resultant
total is divided by the number of degrees of
freedom (the sum of the total number of
determinations, n, minus the number of series of
replicate determinations).

A complicating factor in determining the
precision arises when the standard deviation
varies with the concentration of the element
present. Sometimes the range of concentration can
be divided into intervals and the standard
deviation given for each interval. If the
standard deviation is approximately proportional
to the amount present, precision can be expressed
as a percentage by using the coefficient of
variation (CV).
If the data show a varying standard
deviation, transformation of the data into other
units in which the standard deviation is constant
is often useful. Two widely used transformations
are square roots and logarithms.
Chemical analyses are made for various
purposes and the precision required may vary over
a wide range. In the determination

of atomic weights, an effort is made to keep
the error below 1 part in 104-105. in most
analytical work, the allowable error lies in the
range 1-10 parts per 1000 for components
comprising more than 1 of the sample. As a rule,
analyses should not be made with a precision
greater than required. Up to a point, precision
is a function of time, labor, and overall cost
(Youden 1959).
The precision of an analytical result
depends on the least exact method used in
obtaining the result. In expressing the result,
the number of figures given should be such that
the next to the last figure is certain and the
last figure is highly probable yet not certain.
Thus 10 and 10.00 denote widely varying
precision (Paech 1956). The following is an
example of how an average result computed from
several determinations should be expressed.
Assume the moisture content of sugar is
determined in triplicate, and the following
results are obtained 1.032, 1.046, and 1.036.
The average is 1.038. However, because the
difference between 1.032 and 1.046 is larger than
0.010, the results should not be expressed with
more than two figures after the decimal point.
Thus, the average result should be reported as
1.04 (not 1.038), indicating that the first
figure after the decimal point is certain, and
the second one is probable but uncertain.

The results of weighing, buret reading,
and instrumental (including automatic) reading
have limitations. Replication of analyses
eliminates some the errors resulting from
sampling, from heterogeneity of sampled material,
and from indeterminateaccidental or
randomerrors in the assay. Although repetition
of an assay generally increases the precision of
the analysis, it cannot improve its specificity
and accuracy. If, however, reasonable specificity
and accuracy have been established, the precision
of the assay is an important criterion of its
reliability.
Sensitivity can be increased in tow ways
(1) by increasing the response per unit of
analyzed substance (e.g., in colorimetric assays
by the use of color reagents that have a high
specific absorbance in gravimetric
determinations by the use of organic reagents
with a high molecular weight) and (2) by
improving the discriminatory power of the
instrument or operator (e.g., in gravimetry by
using a microbalance in spectrophotometry by
using a photomultiplier with a

high magnifying power) (Anastassiadis and
Common 1968).
According to Horwitz (1982, 1983), the
important components of reliability, which are
listed in their order of importance for most
purposes in food analyses, are as follows
1.Reproducibilitytotal between
laboratory precision
2.Repeatabilitywithin-laboratory
precision
3.Systematic error or biasdeviation from
the true value
4.Specificityability to measure what is
intended to be measured
5.Limit of reliable measurementthe
smallest increment that can
bemeasured with a statistical degree of
confidence
Typical analytical systematic errors
(biases) are plotted in Fig.4.2.Detection and
determination of errors were described and
discussed in detail by Cardone. Tolerances and
errors are depicted
in Fig.4.3, in which the tolerance limits
for the measured property are given by Lp and Cm
indicates the uncertainty in the

measurement. The values of Lp and Cm include
estimates of the bounds for systematic errors or
biases (B) and estimates of random errors (s, the
estimate of standard deviation). Cm should be
less than Lp. The confidence limits for , the
mean of replicate measurements, are
where is the so-called Student factor.
For regulatory purposes, reliability is
paramount and reproducibility is the critical
component (Horwitz 1982).The between-laboratory
coefficient of variation CV is represented by

Where C is the concentration expressed
as powers of 10(e.g., 1ppm, or 10-6, C-6).The
value of CV doubles for each decrease in
concentration of two orders of magnitude. The
between-laboratory coefficient of variation at 1
ppm is 16(24).The within-laboratory CV should be
one-half to two-thirds of the between-laboratory
CV. The interlaboratory coefficient of variation
as a function of concentration is illustrated in
Table 4.5 and Fig.4.4.the largest contributors to
experimental errors in instrumental methods are
systematic errors(Horwitz 1984),which are
difficult to measure without interlaboratory
comparisons. They can be reduced by incorporating
reference physical constants and certified
standards.
The precision characteristics of 18
analytical methods for trace elements subjected
to inter laboratory collaborative studies over
the last 10 years by the Association of Official
Analytical Chemists were examined by Boyer etal.
(1985).Removal of outliers and statistical
calculations were standardized by the use of a
computer program.

Most of the studies, which represented a
variety of analytes matrices and measurement
techniques over a range of concentrations of
100g/kg to 10µg/kg, were distributed about a
curve defined by the equation.
where RSDx is the among-laboratory
standard deviation and C the concentration
expressed as a decimal fraction (e.g., 1 ppm
10-6), irrespective of analyte, matrix, or
measurement technique. The within-laboratory
relative standard deviation RSD0 was usually
one-half to one-third RSDx. Positive deviations
from this curve with decreasing concentration
could be explained by heterogeneity of the
material, free choice of analytical method, or
concentrations below the limit of determination.
The presence of more than 20 outlying laboratory
results or RSDx degenerating faster than the
moral rate

with decreasing concentration was taken by
the authors to indicate that a particular method
is inapplicable at or below the level generating
the imprecise data.
Optimizing chemical laboratory performance
was the subject of a symposium organized by the
Association of Official Analytical Chemists
(Garfield et al.1980).The symposium covered a
wide range of topics including design, criteria,
and maintenance of quality assurance programs
reference standards maintenance of records and
government regulations as they relate to good
manufacturing practices and good laboratory
practices(Piggott,1986Hubbard 1990).Reliability
measures in collaborative tests was discussed by
Karpinski (1989).The author presented procedures
for calculating confidence intervals and
operating characteristic curves for acceptance
criteria based on repeatability and
reproducibility estimates. Comparisons of the
reliability of estimates were provided for
various numbers of collaborators. With a small
number of collaborators, the estimates of
reproducibility are not reliable and decisions
regarding acceptability of a method are heavily
based on the methods repeatability rather than
the property of most interest, namely, the
reproducibility of the method. Wagstaffe (1989)

discussed errors in analytical methods and
the use of intercomparisons to locate sources of
error and how to improve accuracy in food
analyses. According to the author, although most
analytical chemists achieve a good level of
precision, relatively few evaluate maximum
possible errors in their results. This is evident
from the wide range of values often seen in
interlaboratory trials. This problem arises
largely because, unlike precision, accuracy is
difficult to achieve and, within an isolated
laboratory, often impossible to demonstrate.
Certified Reference Materials (CRMs) provide an
effective and economic means of investigating and
controlling accuracy. Reference values
(certification) are generally assigned to CRMs on
the basis of agreement of independent methods.
For many difficult analyses, certification cannot
be achieved until the major sources of error have
been identified and reduced. A systematic
approach has been developed, which involves a
series of preliminary studies, each designed to
investigate specific steps in the analysis (e.g.,
calibration, extraction, clean-up, and end
method). This procedure often leads to

considerable improvements in the application
of established methods and even to the
development of new ones. The approach was
illustrated with reference to recent studies in
CRMs development for aflatoxin M1 in milk powder,
aflatoxin B1 in peanut meal, deoxynivalenol in
corn and wheat, and polycyclic aromatic
hydrocarbons in kale and coconut oil.
The significance of reference material for
improving the quality of nutritional composition
data for foods was presented in a lecture by
Southgate (1987). The main features of a quality
assurance program must include adequate training
supervision and motivation of staff proper
organization of record keeping adequate sampling
to ensure that the samples are representative
preservation of composition during storage and
exclusion of contamination selection reliable
analytical methods and judicious evaluation of
results. Major factor in selection of reference
materials are variety of food matrices, from and
distribution of nutrients in foods, species of
nutrients (types and range of separation), and
means of protecting labile nutrients. The
reference materials should include major
components (proximate constituents-water,
protein, fat, and carbohydrates), inorganic
constituents (major Na, K, Ca, Mg, P, and Cl
minor Cu, Mn,

Cr, I, F, and Co and Co and boundary Fe
and Zn), and vitamins. Peeler et al. (1989)
examined the available collaborative studies for
standard methods of analysis for various
constituents of milk and milk products in an
attempt to assign specific repeatability and
reproducibility precision parameters to these
methods. The collaborative assays for the primary
constituents (moisture/solids, fat, protein), the
nutritionally important elements (calcium,
sodium, potassium, phosphorus), and miscellaneous
analytes/physical constants (ash, lactose, salt,
freezing point) produced different estimates of
the precision estimates from collaborative
studies was given by the reproducibility relative
standard deviation, RSDR, which is relatively
constant within a product and permits comparisons
across products. Horwitz et al. (1990) studied
the precision parameters of methods of analysis
required for nutrition labeling, with regard to
major nutrients. The precision data are best
summarized as a median or average parameter and
the interval containing the centermost 90 of
reported values. The precision of methods of
analysis can be expressed as a function of
concentration

only, independent of analyte, matrix, and
method. The average RSDR value from each
collaborative data set can be used as the
numerator in a ratio containing, as the numerator
in a ratio containing, as the denominator, the
value calculated from the Horwitz equation
where C is the concentration as a
decimal fraction. A series of ratios consistently
above 1, and especially above 2, probably
indicates that a method is unacceptable with
respect to precision.
By this criterion, only the protein
(Kjeldahl) determination is acceptable with a 90
interval for RSDR of 1-3 at C values above about
0.01(1g/100g). Fat, moisture/solids, and ash are
acceptable down to limiting concentrations in the
region of 1-5g/100g, if a test portion large
enough to provide at least 50mg of weighable

residue or volatiles is specified.
Measurements of individual carbohydrates and
fiber-related analytes have unexpectedly poor
precisions among laboratories. The variability,
although high, may still be suitable for
nutrition labeling.

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