BIOT6002 Lecture 11 Immunoassay QC PDF

Summary

This document provides an overview of immunoassay quality control (IQC) and quality assurance (QA). It covers topics such as learning objectives, precision and accuracy assessments, validation reports, control charts, and the principles of external quality assessment schemes (EQAS).

Full Transcript

Standardisation & Quality Assurance –
Part 2
BIOT6002: Lecture 11
Lecturer: Caroline A Browne, Ph.D.
Learning Objectives
For Validation Reports, describe how to measure
Precision
Accuracy
Define the principles of
Internal Quality Control
External Quality Assessments
Explain how to use Control Charts
Validation Report -Assessment of Precision
Precision
“The closeness of agreement between independent test results obtained
under stipulated conditions”
Measured as repeatability (r), intermediate precision (Rw), and
reproducibility (R).
Precision is hard to quantify so it is the inversely related
imprecision that is commonly reported.
The Coefficient of Variation (%CV) expresses as a % of the mean
%CV = s / mean x 100
Validation Report -Assessment of Precision
Precision data is required when selecting a method or instrument
initially for routine use – Validation
Precision of assay must be determined over time using
standardised procedures – Internal Quality Control
Assessment of Precision
Repeatability (within-run or within-day) - variability observed when
Laboratory, technician, days, instrument, reagent lot, are held constant
Time between the measurements kept to a minimum.
Reproducibility
All factors varied.
Measurements carried out over several days.
Intermediate precision (between-run or between day)
All factors except laboratory are allowed to vary and for clarity the factors
changed should be stated in the validation report.
Example Procedure for Validation
1. Collect samples with known high and low concentrations of the
measurand. Pool samples if necessary.
2. Make 25 aliquots of each sample and store at −80°C pending
analysis.
3. At day 1–5 measure 5 replicates of each sample. Note: the days
need not to be consecutive, only different.
4. Insert data, separate days on different rows of an excel file.
5. Calculate the mean value, SD, %CV to assess repeatability and
intermediate precision.
Evaluation of precision of methods
Measurement of intra-assay precision:
Analyse ~ 20 replicate samples/standards in one batch or run & calculate
the within assay %CV.
This should be repeated with replicate specimens of different
concentrations.
Intra-assay precision: depends on the nature & concentration of samples
and the performance of analysis at the time & cannot be used as a
definitive measure of precision of method.
Measurement of inter-assay/ inter-day precision:
Select 3-5 samples / standards over the analytical range.
One per day should be analysed for 20 consecutive days
The inter-day %CV is calculated from 20 results
Assessment of Accuracy
Accuracy “the closeness of a measured value to a
standard or known value”
Calibration standards: All quantitative
measurements require a standard (calibrant)
A solution containing a known amount of component to be
assayed.
Primary standard: One in which the concentration is
determined by dissolving a weighed amount of
substance in a solvent and making up to a stated
volume or weight
Accuracy depends on the purity of standard material
and quality of preparation
Assessment of Accuracy
Secondary standard: is one in
which the concentration is
determined by an analytical method
of known reliability.
Internal standard: is a substance
not normally present in the sample
& clearly distinguishable from the
test analyte which is added in
known amount to the sample.
Assessment of Accuracy
Analytical methods can be classified
into 3 groups according to their
accuracy:
1. Definitive method: is one with no
known source of inaccuracy
2. Reference method: is one which
after exhaustive comparisons with a
definitive method has been shown
to have negligible inaccuracy
3. Method of known bias: should be
tested against a reference method.
Methods with little or no bias are
referred to as standard methods
Assessment of Accuracy
1. Recovery experiments: depend on the
determination of a substance in a pair of identical
samples to one of which is added a known amount
of the pure substance. The difference in the results is
the amount recovered & is expressed as % of the
amount added (% recovery)
2. Control Materials: Specimens with known values
e.g. commercial control materials (certified
reference materials) can be used for comparison.
3. Statistical Comparison of methods: the best
method of assessing the accuracy of a method is to
compare the results with a method of known
accuracy ( e.g. t-test or ANOVA).
Principles of IQC for immunoassay
1. IQC samples should be of appropriate:
Type – identical to samples used routinely
Concentration – appropriate testing range
Volume & stability – sufficient to cover a reasonable period of time e.g.
6 months
Commercially available IQC material:
Expensive (unassayed material available for precision studies)
Errors in reconstitution
In house preparation of pools:
Can be hazardous depending on source
Addition of exogeneous analyte, or dilution to within range
Principles of IQC for immunoassay
2. IQC procedures should provide reliable estimates of
intra-batch & inter-batch errors.
Precision: is defined as the agreement between replicate
measurements (random error)
Drift: refers to a progressive/non-random change in results due
to e.g. Temperature variations across plate, unmixed reagents
or inadequate incubation times
Basic IQC statistics

IQC statistics How they are measured
Intra-batch precision Intra-sample, intra batch
precision profile

Intra-batch drift i. Mean difference between Repeat
Analytical Controls (RAC) at the
beginning & the end of the batch.
ii. Standard curve, beginning & end
of the batch
Basic IQC statistics

IQC statistics How they are measured
Inter-batch precision i. Standarddeviation of RAC
between batches
ii. Standard deviation of IQC
pools

Inter-batch drift Current mean of results of IQC
pool compared with previous
mean.
Precision Profile Plot
Three important applications:
i. Determination of the working
range of the assay
ii. Rejection of sample outliers
in raw data
iii. Shape of the plot may reveal
unsatisfactory quality of the
batch
Presentation & Interpretation of IQC data
Quality control charts or Shewhart
charts provide:
i. A visual display of information
for day-to-day analysis
ii. A means of forecasting trends
over a longer period of time.
A measured quantity or a statistic
derived from it is plotted versus time
Control Charts
Any of the following statistics can
be used to plot a control chart:
i. The result obtained from a
control sample or the %
difference between the result
and a mean or target value
ii. The mean of duplicate
analyses of a control sample
iii. The standard deviation or %CV
calculated for the batch, day,
week or month.
Control Charts
Control limits are incorporated in the chart set at +/- 2SD and +/- 3SD.
The position of the control limits are set according to the situation & may be more
stringent than these limits
Warning Limits: +/- 2SD: if value is outside these limits, then the method
needs to be investigated for unstable reagents, temperature control etc
Action Limits: +/- 3SD: if value is outside these limits, then all results are
wrong & fault must be investigated, rectified & assay repeated
Charts can be used to indicate precision & accuracy as well as changes in
these.
The most common is a chart of control samples which should show a
sequence of points randomly distributed about the central mean line.
Control Charts
File:Control chart.jpg

Non random patterns may be of several
different types:
1. Extreme variations due to gross errors e.g.
outliers due to mistakes of sample
identification, calculation etc. – can be
ignored and taken as gross errors rather
than random analytical variation.
2. Jumps in control line indicates a sudden
alteration in accuracy due to e.g. a change in
standard or reagent.
3. A sequence of points may lie on one side of
central line but are still within control limits
– indicates inaccuracy.
Control Charts – Common Mistakes
Misinterpreting Random Variation: Treating random variation as a
sign of a problem can lead to unnecessary adjustments.
Ignoring Special Causes: Failing to investigate points outside control
limits can overlook significant issues.
Incorrect Control Limits: Using incorrect calculations for control limits
can lead to misinterpretation.
Overcomplicating the Chart: Adding too much data or unnecessary
details can make the chart difficult to read.
Lack of Training: Inadequate training on how to use and interpret
control charts can lead to misinformed decisions.
Operation of IQC programme
IQC results evaluated by person
other than the analyst
Rejection of batches/results:
Imprecision – technique & precision
of instrumentation
Inaccuracy – preparation & use of
standards
Cumulative IQC data reviewed to
monitor long term trends in
performance
Comparison with External Quality
Assessment Scheme (EQAS)
Review meetings
Principles of EQAS
Scheme Design:
Frequent sample distribution to
provide relevant & statistically
valid data
Rapid return of EQA reports to
participants
Accurate documentation of
methods used
Common units for reporting results
EQA samples assayed by
participants in precisely the same
way as routine specimens
Principles of EQAS
Sample Material:
Should behave identically to real
samples in all assay systems
Analyte concentrations appropriate
to use of test
Stable under conditions of sample
distribution
Present no avoidable infectious
hazard
Principles of EQAS
Definition of target values:
Reference method values provided
where possible
Validate accuracy & stability of
values
Assessment of performance:
Appropriate statistics used
Overall, method group & individual
laboratory performance estimated
Other aspects of performance (e.g.
Test interferences, interpretation),
assessed where appropriate
Other aspects of QA in immunoassays
Methods, protocols & equipment:
Protocol transfer from R&D assay to
routine laboratory
Equipment & laboratory facilities
adequate e.g. Incubators, plate
washers, pH meters, storage facilities
Calibration of instruments: pipettes,
dispensers, microtitre plate readers,
automated plate washers.
Learning Objectives
For Validation Reports, describe how to measure
Precision
Accuracy
Define the principles of
Internal Quality Control
External Quality Assessments
Explain how to use Control Charts