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An Introduction to Quality Assurance in Analytical Science
Dr Irene Mueller-Harvey Mr Richard Baker Mr Brian Woodget
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Part 4 - Regulation and Accreditation
Contents: Accreditation (slide 3,4) ISO (slides 5-7) Inter-laboratory proficiency testing (slides 8-11) Evaluating analytical quality (slides 12-13) The presentation contains some animation which will be activated automatically (no more than a 2 second delay), by mouse click or by use of the ‘page down’ key on your keyboard.
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Accreditation Accreditation is defined as: Formal recognition that
Certificate Accreditation is defined as: Formal recognition that a testing laboratory is competent to carry out specific tests
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Accreditation – which standard?
A number of universally recognised Accreditation systems ISO 9000 applicable mostly to manufacturing & services - emphasis on records and customer service Good laboratory (GLP) and good manufacturing practice (GMP) recognised for pharmaceutical and clinical measurements - emphasis on records, procedures, reproducibility ISO 17025 used by analytical laboratories for work outside the health sector - emphasis on valid data, traceability, comparisons and data recognition in a court of law
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ISO 17025 Accreditation Main features of accreditation
Guarantee to customers: work to agreed standards Laboratory: independent & stringent assessment Agreed & specified methods used All measurements traceable to national & international standards
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ISO 17025 Accreditation How do you become accredited?
1 Install a quality system in the laboratory that complies with the ISO requirements; 2 Decide on the schedule of tests that are to be accredited 3 Apply to the United Kingdom Accreditation Service (UKAS); 4 Have a ‘Pre-assessment’ visit from the UKAS assessors; 5 Have a formal Assessment visit from UKAS; 6 Clear any non-compliances they find; 7 Become Accredited for the chosen schedule of tests
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ISO 17025 Accreditation How do you remain accredited?
pay an annual subscription perform satisfactorily in inter-laboratory proficiency tests undergo and pass regular horizontal and vertical audits Mostly concerned with the overall quality management system Will trace sample paths from initial acceptance to final report
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Inter-laboratory Proficiency Tests
Many laboratory tests are used for international or national standard and regulations, for example: food labelling, water quality, animal feeds, pesticide residues. The authorised laboratories must show that their results are comparable with others doing the same tests.
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Participation in proficiency testing schemes offer the
Proficiency Schemes (1) Participation in proficiency testing schemes offer the following benefits: Show labs how well they compare with others; Help them to reduce the overall variability in testing; Give the regulatory authorities and consumers confidence that their quality criteria are meaningful
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Organisers of such schemes must
Proficiency testing (2) Organisers of such schemes must ensure that: all participating labs receive identical samples; a ‘true’ value is assigned for the result of a test (for example it may be the mean of all participants’ results); participants do not know the ‘true’ result before they do the test.
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Proficiency testing (3)
From the results submitted by the participating laboratories, the organisers can: rank the laboratory’s performance by calculating its “z-score”; identify the laboratories that can produce acceptable results for the test; show divergent laboratories how they need to improve their performance of the test.
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Calculation of ‘z’ scores A laboratory’s z-score is calculated from:
-10 -8 -6 -4 -2 2 4 6 8 10 1 Laboratory identity number z-score A laboratory’s z-score is calculated from: [(x - X)/SD] x = the lab result X = the true or accepted result SD = target value for the standard deviation The graph above shows the ‘z’ scores obtained by 120 laboratories who participated in a particular proficiency testing scheme The best performing laboratories have ‘z’ values close to zero. The acceptable range is +2 to -2
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Variation of CV with analyte level
We can expect a CV to be: approx. 5% at a 1g/l level and approx. 15% at a 0.001g/l level +60 +50 +40 +30 Coefficient of variation (CV) or relative standard deviation (RSD) [ % ] +20 +10 -10 -20 -30 -40 -50 -60 10% 0.1% 1 ppm 1 ppb 10-1 10-3 10-6 10-9 Concentration
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