Laboratory Quality PDF

Summary

This document presents an overview of laboratory quality management. It covers topics such as quality definitions, indicators, and implementation steps for various laboratory settings. The document also includes considerations for achieving excellent lab performance, including essential elements of the implementation process.

Full Transcript

LABORATORY QUALITY

Prof Dr AFAF DESOKY

(2024)

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 Laboratory Quality Management

What is Quality?
―Quality is defined as
conformance to requirements, not as 'goodness' or 'elegance'.‖

Quality Indicators Definition
Established measures used to determine how well an organization meets
needs and operational and performance expectations.

Eight Steps to Developing Successful Indicators
1. objective
2. methodology
3. limits
4. interpretation
5. limitations
6. presentation
7. action plan
8. exit plan
Essentials for Implementation
Commitment
Planning
Structure
Leadership
Participation and Engagement
leads to Continual Improvement

How do we achieve excellent performance in the laboratory?

Laboratory tests are influenced by
laboratory environment
knowledgeable staff
competent staff
reagents and equipment
quality control
communications
process management
occurrence management
record keeping

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Laboratory errors cost in
time
personnel effort
patient outcomes

The entire process of managing a sample must be considered:

between.

Twelve Quality System Essentials
set of coordinated activities that function as building blocks for quality
management
Organization Personnel Equipment
Organization 11—
g1Personnel
human resources
job qualifications
job descriptions
orientation
training
competency assessment
professional development
continuing education

Equipment
acquisition
installation
validation
maintenance
calibration
trouble shooting
service and repair
records

Purchasing and Inventory

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 vendor qualifications
supplies and reagents
critical services
contract review
inventory management

Process Control
quality control
sample management
method validation
method verification

Information Management
confidentiality
requisitions
logs and records
reports
computerized laboratory information systems

Documents
creation
revisions and review
control and distribution

Records

Collection
review
storage
retention

Occurrence Management
complaints
mistakes and problems
documentation
root cause analysis
immediate actions
corrective actions
preventive actions

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Laboratory Assessment

External
Proficiency
testing (EQA)
Inspections
Accreditations

Process Improvement
opportunities for improvement (OFIs)
stakeholder feedback
problem resolution
risk assessment
preventive actions
corrective actions
Customer Service
customer group identification
customer needs
customer feedback

Facilities and Safety
safe working environment
transport management
security
containment
waste management
laboratory safety
ergonomics

A Brief History of Quality Management
Innovator Date Cycle
Walter A.Shewhart 1920s Statistical Process Control
W. Edwards Deming 1940s Continual Improvement
Joseph M. Juran 1950s Quality Toolbox
Philip B. Crosby 1970s Quality by Requirement
Robert W. Galvin 1980s Micro Scale Error Reduction

In summary
Quality management is not new.
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 Quality management grew from the
good works of innovators who defined
quality over a span of 80 years.
Quality management is as applicable
for the medical laboratory as it is for
manufacturing and industry

Facilities and Safety
Secondary effects of a laboratory
accident
loss of staff confidence
loss of reputation
loss of customers
increased costs litigation, insurance
Negligence
of laboratory safety is costly!

N.B

All diagnostic and health care laboratoriesmust be designed
and organized forBiosafety level 2 or above

Laboratory design
Path followed by the sample
reception and registration of patients
sampling rooms dispatch between different laboratories
analysis of samples
Report delivery, filing
Service rooms

Safety during Service
no unauthorized persons
no friends
no children
no animals
PleaseCLOSE the DOOR
Sample collection room
Stock room
Doors and large equipment
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Waste
Premises
high ceiling with good ventilation
walls and ceiling
use washable, glossy paint
easy to clean and disinfect
floor
easy to clean and disinfect
Benchtops
non-porous covering, easy to clean,resistant to chemicals and disinfectants
no wood, no steel

Scheduled Cleaning
daily
bench tops
floors
weekly
ceiling and walls
other
refrigerators
freezers
storage areas
record date and cleaning staff

Laboratory Hazards
physical
chemical
biological

Physical Hazards
Needles, Broken Glass, and Sharps
do not recap needles
always use puncture-resistant, leak proof, sharps containers
always use specific waste disposal containers
never directly handle broken glass

Chemical Hazards
Biosafety Level 1 and 2 laboratories
Separate cabinets for storage:
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 spill containment cabinet
hazardous waste storage
flammable liquids storage

Biological Hazards
Aerosols and droplets are the main
sources of contamination

Contamination Routes
Ocular invasion
Inhalation
Ingestion
Skin penetration
Personal Protective Equipment
laboratory coat
gloves
goggles or face shield
masks
hearing protection

Chemical Spills
anything beyond a minor
spill and requiring help from
outside of the laboratory group
constitutes a major spill

Biological Spills
Facilities and Safety –
Learn how to operate a portable
fire extinguisher
Laboratory Fire Safety

Summary
When designing a laboratory or
organizing workflow, ensure that
patients and patient samples do not
have common pathways

Summary
Safety is dependent on:
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 a responsible supervisor
a safety manual and SOPs
trained personnel
assessment of risks
laboratory design

Key Message
Neglecting laboratory safety is costly.
It jeopardizes the lives and health of
employees and patients, and jeopardizes
laboratory reputation, equipment, and
facilities

Selecting and Acquiring Equipment

performance characteristics
cost
reagents

Selecting and Acquiring Equipment
easy to use
safety
will it fit?
warranty
language

Negotiating Equipment Acquisition
wiring diagrams
software information
parts list
operator manual
installation by manufacturer
trial period

Equipment Calibration
perform initialcalibration
use calibrators orstandards
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 follow manufacturer’sinstructions
determine frequency of routine calibrations

Function Checks
Monitor instrument parameters:
periodically, daily, weekly, monthly
after major instrument repairExamples:
incubator temperatures
wavelength calibration
autoclave temperature chart

Create an Equipment Inventory Log
Record:
instrument type, model number,serial number
location in laboratory
date purchased
manufacturer andvendor contact information
warranty, note expiration date
spare parts

Troubleshooting:
What is the source of the problem?
Sample?
Reagent?
Water,Electricity?
Equipment

N.B
Do NOT use equipment that does
not function properly

Service and Repair
manufacturers
laboratory must schedule routine manufacturer’s maintenance
warranty may require repair handled by manufacturer
in-house biomedical service technicians

Documents
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Develop written procedures for:
routine maintenance
function checks
calibration
troubleshooting
manufacturer’s Service

Dedicated Log Book
Routine maintenance:
calibration
service repair by manufacturer
all problems
Function checks

Recording Problems
date problem occurred, equipment removed from service
reason for breakdown or failure
corrective actions taken
date returned to use
change in maintenance or in function checks

Summary
An equipment management program will address:
equipment selection
preventive maintenance
procedures for troubleshooting and repair
Documents and records will include:
inventory of all laboratory equipment
Information provided by the manufacturer on operation, maintenance,
and troubleshooting
records of all preventive maintenance and repair activities

Equipment - Microbiology
Monitor temperatures of:
incubators
refrigerators
freezers
Perform function checks for:
pipettes
autoclaves
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 pH meter
weights and measures
Maintain records

Analyze Needs
Conduct analysis of supply and reagent needs by:
listing all tests in laboratory
identifying all supplies needed for each test
using available information to estimate usage

Shelf Organization
avoids ―losing‖ a product
saves time
systemizes storage space Number cold room or refrigerators and freezers
and label shelves

Definition
Quality Control (QC) is part of quality
management focused on fulfilling quality
requirements

QC is examining ―control‖ materials of
known substances along with patient
samples to monitor the accuracy and
precision of the complete examination
(analytic) process.

Purpose
The goal of QC is to detect
errors and correct them before
patients’ results are reported
Quantitative Examinations
Measure the quantity of a
particular substance in a sample
Measurements should be both
accurate and precise
Qualitative Examination Methods
Examinations that do not have
numerical results:
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 growth or no growth
positive or negative
reactive or non-reactive
color change
QC Summary
important part of quality managementsystem
goal is to identify errors and eliminate them before reporting patientresults
different methods applied for quantitative, qualitative
, and semi-quantitative results

Definitions
Accuracy The closeness of measurements to the true value
Precisio The amount of variation in the measurements
Bias The difference between the expectation of a test result
and an accepted reference value
Quality Control:
Diagnostics Quality Control:
Molecular Diagnostics

Overview
Sample Collection, Transport, and Processing
maintain Nucleic acid integrity through these processes
Contamination Control
establish a unidirectional work flow from a DNA-free area for reagent
preparation, to a sample processing area, to area where
amplification and detection occur
Positive and Negative Controls
Reference: CLSI MM3-A (Molecular Diagnostic
Methods for Infectious Diseases

Continuous monitoring is the key element to success in the
Quality System

Summary
Assessment is important in monitoring the effectiveness of the laboratory
quality management system.
Both external and internal audits yield useful information.
An outcome of assessment is finding root causes of problems and taking
corrective actions

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Laboratory Staff
laboratory’s greatest asset
critical to quality
partners in public health
qualified professionals

Summary
Personnel management is critical to
success of a quality management system.
Job descriptions should accurately describe tasks and authorities.
Competency must be assessed.
Training will help to assure competentstaff.
Methods for attracting and retaining personnel must be addressed

Actions to meet patient requirements
provide collection information
provide collection facilities
trained and knowledgeable personnel
confidentiality of records
maintenance of records

Provide information for patients
laboratory address and location –directions
hours of operation
bilingual/ multilingual staff

Collection Requirements
patient identification
patient preparation
type of sample required
type of container needed
labeling
special handling
safety precautions

Good customer service provides:
valuable information for best patient care
valuable information to improvesurveillance
professional image of laboratory

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Summary
Customer service is an integral part of a quality management system. It is
important for the laboratory to:
have commitment to process
conduct planning and monitoring
know and understand clients and theirneeds
provide resources for program

Meeting customer needs is a primary goal of the laboratory
An active quality management system ensures laboratories meet all
clientrequirements
Everyone in the laboratory is responsible for quality, and therefore
for customer service

Good Documents are:
clear
concise
user-friendly
explicit
accurate
up-to-date

Oveveiw
Laboratory quality control (QC) and assurance are critical, particularly
in highly regulated industries such as food, cosmetics, and pharmaceuticals.
There are many definitions of quality, but in a laboratory setting, it generally
refers to the accuracy and reliability of results. While inaccuracy is accepted
to an extent, a strong quality management system will keep that level to a
minimum. Quality and compliance go hand in hand and can form the
backbone of an organization's viability. Lack of QC and assessment can lead
to dire consequences for organizations and their customers. Lab staff strive
to meet quality and compliance standards to ensure outputs are reliable and
conform to regulations.

Quality improvement in clinical laboratories is crucial to ensure
accurate and reliable test results. With increasing awareness of the potential
adverse effects of errors in laboratory practice on patient outcomes, the need

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for continual improvement of laboratory services cannot be overemphasized.

The robustness of the healthcare system relies upon the clinical
laboratory because all the clinical decisions taken on patients by physicians
mainly depend upon the clinical lab reports. About 70–75% of medical
diagnoses are obtained via clinical laboratory reports, making laboratory
service quality directly impact healthcare quality. Laboratory findings
should be precise as possible, also at the same instance; all laboratory
operations must be reliable with timely reporting resulting in a beneficial
clinical setting. Negligence during laboratory operations, including
processing, assessing, and reporting, can cause severe consequences,
including complications, lack of adequate treatment, and delay in correct and
timely diagnosis, leading to unnecessary treatment and diagnostic testing. A
clinical laboratory is a complex set of cultures that include several activity
steps, and many people make it unique and saucerful. The comprehensive set
of these complex operations occurring during a testing process is called the
path of the workflow. The workflow path in a clinical laboratory initializes
with the patient and finishes with reporting and comprehending the results.
In any clinical lab setting, it is presumed that mistakes will be made in this
process due to the high volume of samples, the limited number of staff, and
the different steps implicated in the testing process. Errors at any stage of the
total testing process (TTP) can result in inaccurate laboratory outcomes. To
guarantee the quality of the results, a reliable method for determining errors
within the TTP is required.

Laboratories are one of the most important places to provide services to
patients within the health institution, which must be ensure the patient safety
and care quality.

Laboratory quality (LQ) is often outlined as precision, responsibility and
time achieving of reportable check outcomes. lab outcomes should be
correct, all aspects of lab. operations should be trusted, and time saving
coverage for helpful during a clinical or public health setting. If unreliable
outcomes submitted, the implications are often terribly vital, including:
Unnecessary treatment or generally operations Treatment complications
Medications side effects Missing necessary diagnoses Failure to produce the
right treatment Increased price of aid. These consequences end in inflated
cost, time and employees’ endeavors, and sometimes in poor patient
outcomes. Minimizing lab mistakes to realize the very best level of precision

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and responsibility, it's necessary for whole processes and procedures within
lab. To be done at absolute excellent approach. The lab. is a complicated
system, including several steps of activity and plenty of folks. The (QS)
needs a lot of processes to be done. So, Quality System Management (QSM)
model, that appear at the whole system, is extremely necessary to achieve
smart lab. functioning.

Laboratory quality control is designed to detect, reduce, and correct
deficiencies in a laboratory's internal analytical process prior to the release
of patient results, in order to improve the quality of the results reported by
the laboratory. Quality control (QC) is a measure of precision, or how well
the measurement system reproduces the same result over time and under
varying operating conditions. Laboratory quality control material is usually
run at the beginning of each shift, after an instrument is serviced,
when reagent lots are changed, after equipment calibration, and whenever
patient results seem inappropriate. Quality control material should
approximate the same matrix as patient specimens, taking into account
properties such as viscosity, turbidity, composition, and color. It should be
simple to use, with minimal vial-to-vial variability, because variability could
be misinterpreted as systematic error in the method or instrument. It should
be stable for long periods of time, and available in large enough quantities
for a single batch to last at least one year. Liquid controls are more
convenient than lyophilized (freeze-dried) controls because they do not have
to be reconstituted, minimizing pipetting error. Dried Tube Specimen (DTS)
is slightly cumbersome as a QC material but it is very low-cost, stable over
long periods and efficient, especially useful for resource-restricted settings

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in under-developed and developing countries. DTS can be manufactured in-
house by a laboratory or Blood Bank for its use. [5,6]

Quality Control (QC)
The principles of quality assurance, quality control, and quality
management are bases for good laboratory results and workings.
Every test in the laboratory gives a result. To be sure about the accuracy
of the result is not possible until it is verified by some means. It is the quality
control that will give confidence about the result.
This is the duty of the technicians to be sure about the accuracy of the
test result.
Analytical sensitivity
It is defined as the smallest amount of substance in a sample that can
accurately be measured by an assay (synonymously to detection limit).

Analytical specificity
It is defined as the ability of an assay to measure one particular organism
or substance, rather than others.

Quality assurance:
It consists of plans, policies, and procedures that provide an
administrative structure for a laboratory’s efforts to achieve quality goals.

 It has three components:

1. Assessment and monitoring.
2. Development of the program.
3. Quality improvement (quality control).

 Quality assurance is vital to the patients, and this will need:
1. Quality can be assessed and monitored.
2. Quality program development.
3. Quality control improvement.

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  Quality control is one of the components of quality assurance. Quality
assurance will check the entire testing process and will check quality
regularly.
 Quality can be assessed, monitored, and it can be improved.
 Quality control will ensure the accuracy and reproducibility of the
lab’s various tests.

 QC checks the particular source of errors, estimates the magnitude of
the errors, and alerts the laboratory personnel that quality has
deteriorated.
 Quality control results will be acceptable when these are in the
acceptable range of the error limits.
 Quality control (QC) results are unacceptable when these results show
excessive errors and are out of the range.

Ideal properties of QC materials are:
 QC material should resemble human serum, plasma, blood, urine,
and cerebrospinal fluid.
 QC material should be stable for prolonged periods without any
interfering preservatives.

 QC material should be free of communicable diseases like bacteria,
viruses, and fungi.
 QC material should have a known concentration of the analytes.
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  QC material should be easy to store and dispense.
 QC material needs to be affordable and not too costly.

Quality control objectives are:
 QC provides continuous accuracy of the results.
 QC gives an early warning about the accuracy of the test so that
early remedies may be taken to avoid great mistakes.
 QC compares the tests at a different time from the same control
sera.

Many tools are used for quality control like:
 Procedure manuals.
 Maintenance schedules.
 Calibrations.
 Quality assurance program.
 Training.

Quality control will be different for the different disciplines of pathology:

 Quality assurance for the blood transfusion.
 Quality assurance for microbiology.
 Quality assurance for biochemistry.
 Quality assurance for surgical pathology.
 Quality control for hematology.

Quality control depends on:
 The time between the collection and the performance of the test ex.
Leukocytes and RBCs utilize glucose and cause a steady decrease in
glucose concentration.
 Specimen storage also causes an error in the result.
 Evaporation of the sample may cause the wrong result, like
electrolytes.
 Exposure to light affects the Bilirubin level.
 Refrigeration will affect lactate dehydrogenase (LDH).
 The clerical mistake may occur at any stage.

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Quality control purposes:
 To maintain a continuous record of the precision of the tests.
 It gives an early warning of the control trends, and early action will
be taken before a great mistake occurs.
 It provides valid judgment on the accuracy of results by comparison
with the known sera.
 This is very important for automated analyzers to check their
performance.
 Monitor the analytic process and help to find which method is more
accurate.
 This also helps to evaluate the technologist’s skills.
 Determine analytical errors during analysis.
 Prevent incorrect patient values.
 The monitoring of the analytic values is compared with known
standards and compared with their expected values.

Quality control of various terms used are:
 Accuracy means the true value of the analyte. This isn’t easy to
define the true value of a substance. The value, in comparison to the
known control, has some advantages.
 Precision is the measure of reproducibility for that particular test. A
method may give excellent precision but poor accuracy.
 Mean is a basic statistical work, where this is the mean of the sum
of data divided by the number of items.
 The mode is the value that occurs most frequently in a list of data
items. It is not affected by extreme values.
 Standard deviation is a mathematical concept. This is very
important because they are not acceptable if the mean values are
outside of a standard deviation of >2.
 Median when the data is arranged in ascending or descending
manner, the number that occupies the central position is median.
 Centile is the percentile; the value is greater than a specified
percentage of the list of values.

Analytic factors can be minimized, which depends upon
instrumentation and reagents.

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  A schedule of daily and monthly preventive maintenance is needed
for each instrument.
 Keep a check on water quality, power supply, calibration of
electrical balance, and calibration of glassware and pipettes.
 Reagents and kits should be dated when received and when opened.
 Run new lots of the reagents with the old lot in parallel before being
used for analysis.
 The primary standard is the most highly purified substance.
 The secondary standard is one whose concentration is determined by
analysis and compared with the primary standard.
 Post-analytic errors are due to the recording and reporting of the
results.

Quality control material should be:

 Available in sufficient quantity.
 It should be stable for a period of a minimum of one year.
 Keep in small volumes.
 Its concentration should vary minimally.
 Their composition should not vary from vial to vial.
 Control material should be tested like the test sample.

External quality assessment:
This is the program in which the specimens are subjected to other
laboratories for analysis, and the individual laboratory results are
compared.

This comparison can be made to the performance of a peer group of
laboratories or to the performance of a reference laboratory. The term
External quality assessment is sometimes used interchangeably with
proficiency testing; however, External quality assessment can also be
carried out using other processes.

External quality assessment is here defined as a system for
objectively checking the laboratory’s performance using an external
agency or facility.

Total quality management focuses on the following:
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  Customer. The users are doctors and nurses, while the customers are
patients.
 Management commitment.
 Training of the workers.
 Measurement through quality-improved tools.
 Quality improvement occurs when the problems are permanently
eliminated. Issues arise from imperfect procedures, of which 85 %.
The remaining 15% of cases need action and performance
improvements of individual employees. So the main problems are
management problems, and management has the power to change
the work process.

Control of the preanalytical mistakes:
 Patient identification and labeling are critical. Barcode technology
has reduced these mistakes, which are common in handwritten
labels.
 Keep a record of the sample received and when the report is ready.
 Check the request form, the test tube name, and the requested tests.
 Check the adequate amount of the sample.
 Observe if there is hemolysis or lipemic serum.
 Take the history of food intake, alcohol, drugs, smoking, stress,
sleep, and posture because these factors may influence the result.
 Explain all instructions to the patient for the collection of the
sample.
 Incorrect containers and incorrect preservatives will affect the result.
 Transport of the sample is very important and may be critical to
some of the tests.
 Processing the sample as a separation of the serum, where centrifuge
speed, temperature, and the person are important.

Analytic errors in quality control:
Quality control errors in the laboratory are classified into:

I. Random errors affect precision and are the basis for varying
differences between repeated measurements.
1. These mistakes will increase the standard deviation.

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 2. These are present in pipettes and volumetric glassware with
manufacturing defects.
3. There may be a defect in the instruments and
spectrophotometer.
4. There may be a defect in the cuvet temperature.
5. There may be an effect of light, temperature, and evaporation
on the serum or the plasma.
6. There may be interference from other substances in the
analyzed sample.
7. Clerical errors are unavoidable and should not be accepted.
a) Labeling the wrong name of the patients.
b) Delay in the transport of the sample.
c) Incorrect calculations.
8. These can be avoided by:
a) Well-trained staff.
b) By good working organization.
c) Well-designed worksheets.
d) Thorough checking of the results.
II. Systemic errors indicate a constant difference, either increased or
decreased. This may be caused by:
1. These errors will displace the mean value in one direction,
which may go up and down.
2. There may be instability of the reagents.
3. There may be an inaccuracy in the standards.
4. If the method is nonspecific for the analysis.
5. Analysis of analytes by the kinetic method at 340 nm is critical.
III. Some errors encounter both systemic and random errors.

Laboratory Quality Management System
A Laboratory Quality Management System (LQMS) is a comprehensive
framework of processes, procedures, and practices implemented within a
laboratory to ensure overall quality.
It involves systematic planning, control, and monitoring of all activities
within the laboratory to comply with regulatory requirements, maintain
reliable results, and enhance customer satisfaction.
Laboratory processes that require quality practices include:
 Sample handling and management
 Equipment calibration and maintenance

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  Method validation and verification
 Quality control and quality assurance
 Training and competency assessment
 Document control and recordkeeping
 Customer communication and satisfaction

It is important to distinguish between the Quality Management System
(QMS) in the medical laboratory and an Electronic Quality Management
System (eQMS).
The laboratory QMS primarily concentrates on overseeing and ensuring
quality within the laboratory’s operations. It encompasses processes,
procedures, and protocols designed to maintain uniform and high quality and
accuracy in testing, analysis, and reporting.
On the other hand, an eQMS offers a digital solution for effectively
implementing and managing QMS principles and processes in an electronic
format. It serves as a specialized software designed to align with regulatory
requirements and streamline the implementation of QMS principles.

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 In a medical laboratory, an eQMS supports the laboratory quality
management system processes such as document management, change
control, CAPA management, employee training, and more.
Simpler QMS provides a comprehensive eQMS solution that
encompasses all of the features and modules designed to streamline the
efficiency of laboratory operations. These modules integrate seamlessly with
the overall QMS framework, improving operational efficiency and
supporting compliance with regulatory requirements. (1)

Applicable Laboratory QMS Requirements
models:

Various applicable standards and regulations govern laboratory quality
management. These ensure that laboratories adhere to specific requirements
and maintain a high and uniform level of quality in their processes.

 ISO 9001:2015

The ISO 9001:2015 standard is a general requirement for a quality
management system.
Although not tailored specifically for medical and clinical laboratories, ISO
9001:2015 requirements can still be followed by these laboratories to
consistently deliver products and services that meet customers’ expectations
and comply with regulatory requirements.

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  ISO/IEC 17025:2017

The ISO 17025:2017 standard establishes the requirements for testing
and calibration laboratories to demonstrate their competency in testing and
equipment calibration.
Compliance with this standard indicates that a laboratory possesses the
necessary knowledge, skills, and resources to produce reliable and valid
results.
It ensures that testing and calibration activities are conducted with
impartiality, competence, and consistent operational practices. This way,
laboratories can enhance their credibility, inspire confidence in their clients,
and demonstrate their commitment to quality and accuracy.

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  ISO 15189:2022

The ISO 15189:2012 provides laboratories with a framework to
develop robust lab quality management systems and assess their own
competence.
This standard aims to promote the welfare of patients and the satisfaction of
laboratory users through confidence in the quality and competence of
medical laboratories.
ISO 15189:2012 covers a wide range of requirements, including but not
limited to:
 Quality Manual
 Personnel training
 Equipment calibration
 Nonconformances
 Complaints
 Data retrieval and storage
 Environmental conditions

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  Examination processes
 Risk management
 Control of records
 Management reviews

 ISO/IEC 17043:2010

The ISO 17043:2010 standard focuses on proficiency testing and sets
forth the requirements for laboratories to participate in interlaboratory
comparisons.
Laboratories can test identical or similar samples under predetermined
conditions, allowing them to evaluate their performance, identify areas for
improvement, and demonstrate their competence in delivering accurate and
reliable results.

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  CLSI HS01-A2

The Clinical and Laboratory Standards Institute (CLSI) HS01-
A2 guideline specifies the requirements for a QMS model for healthcare
organizations.
It offers essential background information and infrastructure to
establish a quality management system aligned with healthcare quality
objectives.
Implementing this guideline, along with other relevant CLSI
documents, allows Life Science companies to apply the model to their
unique processes.

 CLSI GP26-A3

The CLSI GP26-A3 guideline outlines the requirements for applying
a QMS model for laboratory services.
It is a useful resource for improving clinical laboratory processes,
workflow, and operations, meeting government and accreditation
requirements.
Combined with the CLSI HS01-A2, it provides a comprehensive
framework for laboratories to implement a complete quality management
system.

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  FDA 21 CFR Part 58

The 21 CFR Part 58 establishes Good Laboratory Practices (GLP) for
nonclinical laboratories involved in research related to food and color
additives, animal food additives, human and animal drugs, human medical
devices, biological products, and electronic products.
Compliance with this part is intended to assure the quality and
integrity of the products and substances’ safety data.

 Clinical Laboratory Improvement Amendments
(CLIA)

The CLIA refers to a series of adjustments made to the Public Health
Services Act by the US Congress over time.
These amendments have been implemented to safeguard the accuracy
and reliability of testing conducted in laboratories that perform testing on
humans.

 FDA 42 CFR Part 493

The 42 CFR Part 493 is designed to ensure that medical and clinical
laboratories that perform testing on humans operate safely and efficiently
and produce accurate and reliable results.
It requires laboratories to have a comprehensive quality management
system that includes policies and procedures for all aspects of laboratory
operations.
Among the requirements outlined in this part of the regulation are:
 Sample control procedures
 Complaint investigations
 Quality control and quality assurance
 Proficiency testing
 Personnel competency
 Equipment calibration
 Corrective and preventive actions
 Test reporting

31
12 Elements of Laboratory Quality Management System
(QMS)
The 12 elements of a laboratory quality management system are the
building blocks for a QMS framework in medical and clinical laboratories.
Developed by the Clinical and Laboratory Standards Institute (CLSI),
these quality elements are integral to laboratory QMS effectiveness.
Neglecting any of these elements can compromise the success of the
LQMS. Possibly leading to potential failures in achieving accurate and
reliable laboratory results, maintaining regulatory compliance, and meeting
customer expectations.
The quality system essentials are illustrated in the diagram below.

The following are the 12 essential elements of a laboratory quality
management system, along with examples of how an eQMS, like
SimplerQMS, streamlines these processes.
Organization
The organization refers to the laboratory’s management and the
supporting organizational structure that facilitates the implementation of
quality management practices.

Management must actively support the laboratory QMS and
emphasize its significance to the personnel. The management must also

32
ensure the laboratory possesses legal approval from regulatory authorities
for its design and operations.
The key organizational requirements for a successful quality system are
listed below:
 Leadership: Lab leaders must demonstrate commitment, vision, team-
building skills, effective communication, and responsible resource
management.
 Organizational structure: The organizational structure should be
well-defined, with a clear organizational chart and assigned
responsibilities.
 Planning process: Lab managers should have skills for effective
planning, including defining timeframes, allocating responsibilities,
managing resources, and financial planning.

33
  Implementation: Management personnel should address project
management, resource allocation, adherence to timelines, and goal
achievement.
 Monitoring:
There should be processes for monitoring the quality management
system, ensuring compliance with benchmarks and standards, and
continuous improvement is important.

Personnel
Personnel is the most valuable resource in the laboratory. Their
integrity, understanding of the importance of their work, and active
participation in continuous improvement are essential for successfully
implementing the quality management system.
 Management is responsible for defining suitable qualifications for
personnel in every laboratory position. Additionally, they must ensure
that personnel receive proper training to meet education, skills,
knowledge, and experience requirements.
 Employees must undergo a performance evaluation to assess their
competency, including policy adherence, safety compliance,
communication skills, punctuality, and behavior.
 The laboratory should maintain confidential employee records related
to their work. In contrast, non-essential records may be stored with
centralized departments like Human Resources.
 Simpler QMS provides robust training management capabilities. The
system automates training activities and securely stores employee
records while ensuring GDPR compliance.
 It streamlines the entire training process, from creating training plans
and learning rules to tracking training deadlines and completion
status.
 Automated notifications for new training materials simplify staying up
to date. Upon completion, personalized quizzes can be used to
evaluate the effectiveness of the training.

Equipment
Effective equipment management is essential to a laboratory QMS,
ensuring the laboratory’s ability to conduct accurate, reliable, and timely
testing.

34
By implementing proper equipment maintenance, calibration, and
documentation protocols, laboratories can ensure the integrity of their testing
processes and the optimal performance of their equipment.

When it comes to equipment management, careful planning is essential.
Several key elements should be considered in the equipment management
process:
 Selection and purchasing: Laboratories should establish criteria to
select equipment according to the applicable requirements.
 Installation: Requirements for installing new equipment should be
followed, and specific personnel should handle the installation.
 Calibration and performance evaluation: Laboratories should
perform equipment calibration and validation in new and existing
instruments.
 Maintenance: Laboratories should implement maintenance plans
following manufacturer guidance.
 Troubleshooting: A clear procedure should be in place for
troubleshooting equipment issues.
 Service and repair: The laboratory should assess the costs involved
in obtaining service and repair for its equipment. Furthermore, it
should assess the availability of such facilities in its area.
 Retiring and disposing of equipment: Laboratories should have
procedures for replacing old equipment and ensuring proper disposal.
A technical operator is responsible for overseeing equipment in the
laboratory, ensuring proper troubleshooting and maintenance.
The laboratory must maintain a logbook with essential details about
equipment, including tests performed and personnel involved.
Using Simpler QMS software, medical and clinical laboratories can
streamline calibration and maintenance activities and ensure compliance
with regulatory requirements.
The software streamlines equipment management tasks, such as
equipment registration and qualification, making it easier for laboratories to
maintain accurate information on their equipment.

35
 It keeps track of calibration data and automatically sends notifications
and reminders before calibration becomes due.
Furthermore, it allows assigning the responsibility of calibration and
maintenance to appropriate personnel.

Purchasing and Inventory
Constant availability of reagents, supplies, and services is crucial for
efficient and cost-effective laboratory operations. Any interruption in
testing, even for a short period, can severely impact clinical care, prevention
activities, and public health programs.

Establishing policies and procedures for managing critical materials
and services is essential for successful purchasing and inventory
management.
Some of the key components to address are:
 Supplier qualifications
 Purchase agreements
 Receiving, testing, storing, and handling materials
 Tracking materials to individual patients
 Assessing and maintaining inventory
 Controlling expiration periods
 Dispatching supplies to satellite laboratories
 And others
A successful purchasing and inventory management system in a
laboratory quality management system can be achieved through the
following actions:
 Assigning responsibility
 Evaluating laboratory needs
 Establishing minimum stock requirements
 Implementing electronic forms and logs
 Adopting a digital system for receiving, inspecting, and storing
materials
 Maintaining an inventory system across all storage areas

36
 For example, licensed drug manufacturers and laboratories must justify
their stock levels of restricted chemicals to local drug regulatory authorities.
Maintaining logs and forms ensures compliance and prevents penalties from
regulatory bodies.
With Simpler QMS, laboratories can effectively manage their supplier
selection process by evaluating and qualifying suppliers based on relevant
performance criteria. It facilitates the maintenance of an approved supplier
list (ASL) and offers templates for contracts, surveys, and supplier
evaluations.
Additionally, the software sends automatic notifications and reminders
for upcoming supplier certificate renewals.
Simpler QMS streamlines the entire supplier qualification process,
allowing laboratories to categorize suppliers, perform qualification tasks,
and conduct reviews seamlessly.

Process Control
The key factor that determines the success and performance of a
laboratory is its ability to manage and control all of its processes effectively.
Sample management is essential to process control within a quality
management system in laboratories.
Effective sample management is crucial for accurate and reliable testing,
leading to confident laboratory diagnosis. Precise laboratory results are
essential for making informed therapeutic decisions and ensuring optimal
patient care and outcomes.
The sample collected must be standardized and represent the actual
condition. The sample must be stored in recommended storage conditions to
prevent damage as soon as it is collected.
Sample management policies must include the following:
 Information on the sample collection
 How to handle urgent requests
 Sample collection, labeling, preservation, and transport procedures
 Safety practices in case of accidents
 Methods for evaluating, processing, and tracking samples
 Storage, retention, and disposal procedures
 Among others
It is essential to manage sample documents effectively to avoid any mix-
ups or discrepancies that could lead to incorrect testing outcomes. Important
37
information such as sample identification, collection data, time, and required
tests should be documented accurately.
To facilitate efficient sample management and document control,
Simpler QMS has robust document management capabilities.
These features help streamline quality processes, ensuring all necessary
information is recorded and accessible. By using Simpler QMS, laboratories
can improve their document management practices and reduce the risk of
errors or misinterpretations during testing.

Information Management
Information management is a comprehensive system encompassing all
the necessary processes for efficiently managing patient data, including
incoming and outgoing information.
Test results and data are the final product of laboratory operations. To
ensure accessibility, accuracy, timeliness, security, confidentiality, and
privacy of patient information, laboratories must establish an efficient
information management system.
When developing an information management system, it is important to
consider the following key elements:
 Unique identifiers for patients and samples: The same identifier
should be used every time a patient utilizes the service. Similarly, a
unique identifier should be generated for every sample collected.
 Standardized test request forms: Consistent forms must be used to
request specific tests, ensuring clarity and accuracy in the information
provided.
 Logs and worksheets: Detailed records should be maintained to track
the flow of samples, test results, and any relevant observations or
actions taken during the process.
 Checking processes to ensure data recording and transmission
accuracy: Procedures should be in place to verify the correctness of
recorded data and its proper transmission within the information
management system.

38
  Protection against data loss: Measures such as regular backups and
data recovery mechanisms must be implemented to safeguard data
from loss.
 Protection of patient confidentiality and privacy: Strict protocols
should be followed to maintain the confidentiality and privacy of
patient information per applicable regulations and ethical
considerations.
 Effective reporting systems: Systems must be established to
generate comprehensive and meaningful reports based on the
collected data, facilitating analysis, decision-making, and
communication of results.
 Effective and timely communication: Efficient communication
channels should be established to ensure a timely exchange of
information among relevant laboratory personnel and patients.
Simpler QMS offers a form and template management capability that
can help improve the efficiency of laboratory information management
processes.
With pre-defined forms for patient information, logs, and results,
laboratories can streamline data collection.
The system offers a search function to retrieve relevant documents by
searching keywords in the document title and content, such as name or
patient number.
Documents and Records
Document and record management is an essential component of the
quality system, encompassing the utilization and maintenance.
The primary objective of maintaining QMS documentation is to ensure
immediate access to information whenever required.
Documents need to be regularly updated, and an effective document
control system ensures that the latest versions are accessible and in use.
Some examples of documents and reports include:
 Quality manuals
 Standard operating procedures (SOP)
 Work instructions

39
  Reference materials
 Sample logbook
 Patient test reports
 Incident reports
 Instrument printouts
An automated document control software solution helps ensure precise
data collection by providing a streamlined and efficient process.
Simpler QMS offers Life Science eQMS with robust document control
capabilities, for clinical and medical laboratories, enabling them to maintain
audit-ready documents while accurately managing large volumes of data.
By utilizing the eQMS, laboratories can enhance data accuracy and
reliability, improving decision-making and operational excellence.
The system facilitates easy retrieval of documents and ensures proper
archiving when documents are updated.
Explore our article on laboratory document control to learn more about
the importance of proper document management in ensuring accurate and
reliable results.

Occurrence Management
Occurrence management is essential for maintaining quality laboratory
service by effectively addressing and learning from errors. It is integral to
continual improvement, focusing on identifying and managing errors or near
misses.
An occurrence management program aims to correct errors in testing or
communication that result from an issue and prevent their reoccurrence by
improving the processes involved.

The laboratory should establish a proper system for timely investigation
of all laboratory issues and errors and occurrence management, including the
following:
 Establish a systematic process to detect all problems using available
tools.
 Maintain a comprehensive log of problem events, documenting errors,
investigation activities, and actions taken.
 Investigate and analyze the cause of identified problems, utilizing
available information.

40
  Implement necessary corrective actions, including preventive
measures, if the problem is identified before the error occurs.
 Detect and monitor any reoccurrence of the initial problem,
considering potential systemic issues.
 Communicate relevant information to all stakeholders, including those
affected by the error.
Occurrence management, also called incident management, is essential
to every laboratory as it affects the quality of laboratory testing and results.
Simpler QMS automates the recording and tracking of
nonconformances, ensuring efficient handling of identified issues.
The system also automates the notifications and reminders, ensuring
that the relevant personnel is promptly informed when nonconformance
tasks are assigned. This promotes accountability and facilitates timely action
on identified issues.
Moreover, Simpler QMS allows you to seamlessly link
nonconformances to Corrective and Preventive Action (CAPA) processes.
This integration allows for the systematic resolution of issues and the
implementation of preventive measures to avoid their recurrence in the
future.
The software allows for comprehensive monitoring of nonconformances by
product, process, customer, equipment, or supplier. Customizable views
provide flexibility in analyzing and tracking nonconformances, facilitating
data-driven decision-making and continuous improvement efforts.
Assessment
Assessment evaluates the effectiveness of a laboratory’s quality
management system through internal and external audits and performance
evaluation in external quality assessment programs.

There are two types of audits: internal and external.
Internal audits are conducted by personnel within the laboratory itself.
Individuals from one department assess the operations of another
department. The main objective of these internal audits is to identify and
address any potential weaknesses or areas of improvement.
In contrast, external professionals and experts who specialize in their
respective fields conduct external audits. These audits have many purposes,
such as accreditation, certification, and licensing.

41
 The involvement of external auditors ensures impartiality and brings an
objective perspective to assess the laboratory’s compliance with standards
and regulations.
With Simpler QMS, laboratories can streamline the audit process,
saving valuable time and effort in achieving successful audit outcomes.
The software simplifies creating audit plans, scheduling audits, assigning
dedicated Issue Handlers, and attaching relevant evidence to audit findings.
It provides a closed-loop workflow by directly escalating audit findings to
Corrective and Preventive Actions (CAPAs), ensuring that issues are
promptly addressed and resolved.

Process Improvement
Process improvement is a vital component of a quality management
system, as it establishes a structured program to drive continuous
improvement in laboratory quality over time.

The Plan-Do-Check-Act (PDCA) cycle is a valuable tool for achieving
continuous improvement in any process within quality improvement efforts.
The cycle consists of four key steps:
 Plan: Identify problems and potential weaknesses and gather relevant
information to develop an improvement plan.
 Do: Implement the developed plan and put it into action.
 Check: Monitor and assess the effectiveness of the actions taken,
utilizing review and audit processes. Revise the plan if necessary.
 Act: Take any required corrective actions based on the evaluation and
recheck the results to ensure the effectiveness of the solution. This
cycle is a continuous process, initiating further planning for ongoing
improvements in the laboratory.
The ISO 15189:2022 in section 4.12 specifies a comparable set of activities
for achieving continuous improvement within the laboratory. These are
outlined as follows:
 Identify potential sources of system weaknesses or errors
 Develop improvement plans
 Implement the plan
 Review the effectiveness of actions through focused review and audit

42
  Adjust the action plan and modify the system based on review and
audit results.
Processes like internal and external audits, external quality
assessments, and management reviews are used to identify opportunities for
improvement and can serve as the basis for Corrective and Preventive
Action (CAPA).
CAPA offers a systematic approach to tracking corrective actions and
their effectiveness. However, manually handling CAPA processes can lead
to delays and incomplete actions. Implementing an automated CAPA system
can significantly improve this process.
SimplerQMS offers a comprehensive CAPA management software
solution that simplifies and automates the corrective and preventive action
process. Laboratories can streamline CAPA activities such as data
collection, routing, notifications, approvals, and follow-up, ensuring
efficient and effective management of quality issues.
The software provides a centralized platform to track CAPAs, monitor
progress, and generate insightful reports, helping laboratories drive
continuous improvement and achieve regulatory compliance.

Customer Service
Customer satisfaction is a major aspect of a quality management
system. The primary objective of a medical laboratory is to provide quality
test results to its customers, making it essential to ensure their satisfaction.
To achieve this, the laboratory should clearly understand its clients,
including patients, physicians, public health agencies, and the community.
Additionally, the laboratory should remain attentive to customers’ needs and
requirements.

The laboratory quality manager is accountable for measuring customer
satisfaction through surveys, indicators, and audits. They are also
responsible for taking proactive measures to prevent and correct any issues
identified during the assessment process.
Implementing customer feedback systems enables the collection of real-time
data on customer satisfaction levels.
Customer complaints are a common form of customer feedback.
With SimplerQMS’s complaint management solution, laboratories can
efficiently track, manage, analyze, and resolve complaints within a single
system.

43
It offers the convenience of storing all related documents in a cloud-based
platform, enabling seamless access from anywhere.
The software automatically sends notifications to the appropriate personnel,
ensuring prompt attention to customer feedback. It provides valuable
insights into feedback data, enabling effective utilization for product
improvement and increasing customer satisfaction.

Facilities and Safety
The laboratory workspace and facilities should be designed to
accommodate the workload while ensuring the quality of work and the
safety of laboratory personnel.

Neglecting laboratory safety can result in significant costs and adverse
consequences, such as:
 Loss of reputation
 Loss of customers
 Low staff retention
 Increased costs related to human resources.
The laboratory manager is responsible for both safety and quality in the
laboratory. This includes actively participating in lab design, assessing
potential risks, and providing valuable feedback to ensure the development
of a safe laboratory environment.
Risk assessment is essential for the laboratory to manage and minimize
risks to employees effectively. Developing clear safety procedures for
handling accidents, injuries, and contamination is vital.
SimplerQMS can help laboratories identify and assess potential risks
associated with processes, equipment, personnel, and patient safety.
SimplerQMS Risk Management module allows laboratories to develop
risk mitigation plans by defining appropriate control measures,
implementing preventive actions, and establishing contingency plans.
The software enables documenting risk mitigation strategies and
assigning responsibilities to ensure effective implementation.

Role of Laboratory Quality Management Software
The purpose of laboratory quality management software is to streamline
and improve quality processes within laboratories. This specialized software
is a comprehensive solution that allows companies to manage and streamline

44
laboratory operations, ensuring compliance with regulatory standards and
industry best practices.
The software supports the 12 essential elements of the quality
management system in medical laboratories by providing a unified platform
for efficiently managing documents, equipment, personnel, processes,
testing activities, and other processes.
While eQMS for laboratories offers significant advantages, it is
important to consider that a manual and hybrid approach may still be
suitable for some companies, especially those with limited resources or
specific operational requirements.
The decision to adopt QMS software should consider the laboratory’s
specific needs, resources, and regulatory requirements.
SimplerQMS is specifically designed for Life Sciences, including medical
and clinical laboratories. It provides robust support for compliance with
several Life Science requirements.
With its interconnected QMS modules, SimplerQMS offers key
functionalities that align with the 12 essential elements of a laboratory
quality management system. These modules include document management,
employee training, nonconformance management, CAPA management, audit
management, risk management, and more.
SimplerQMS is a fully validated solution, validated according to ISPE
GAMP5 guidelines.
This means that all software validation processes are handled by
SimplerQMS, eliminating the need for customers to allocate additional
resources, time, or costs for software validation.
Additionally, SimplerQMS provides pre-configured workflows,
templates, and ongoing support to facilitate a smooth implementation and
utilization of the software. This helps laboratories manage their quality
management system efficiently, achieve compliance, and drive continuous
improvement.
To better understand the benefits of implementing an eQMS solution,
we suggest downloading our eQMS Business Case template.
This valuable tool provides a structured approach for assessing the value of
an eQMS tailored to your company’s needs, facilitating effective
communication of your findings to management.
Using a business case analysis, you can uncover potential ROI, cost
savings, efficiency increase, and compliance improvements, including
compliance with standards and regulations.

45
Interpretation of lab. quality
Interpretation of quality control data involves both graphical and
statistical methods. Quality control data is most easily visualized using
a Levey–Jennings chart. The dates of analyses are plotted along the x-axis
and control values are plotted along the y-axis. The pattern of plotted points
provides a simple way to detect increased random error and shifts or trends
in calibration.

Statistical quality control statistics
Statistical quality control, the use of statistical methods in the
monitoring and maintaining of the quality of products and services. One
method, referred to as acceptance sampling, can be used when a decision
must be made to accept or reject a group of parts or items based on the
quality found in a sample. A second method, referred to as statistical process
control, uses graphical displays known as control charts to determine
whether a process should be continued or should be adjusted to achieve the
desired quality.

Acceptance sampling
Acceptance sampling refers to the application of specific sampling
plans to a designated lot or sequence of lots. Acceptance sampling
procedures can, however, be used in a program of acceptance control to
achieve better quality at lower cost, improved control, and increased
productivity. This involves the selection of sampling procedures to
continually match operating conditions in terms of quality history and
sampling results. In this way the plans and procedures of acceptance
sampling can be used in an evolutionary manner to supplement each other in
a continuing program of acceptance control for quality improvement with
reduced inspection.

Assume that a consumer receives a shipment of parts, called a lot, from a
producer. A sample of parts will be taken and the number of defective items
counted. If the number of defective items is low, the entire lot will be
accepted. If the number of defective items is high, the entire lot will be
rejected. Correct decisions correspond to accepting a good-quality lot and
rejecting a poor-quality lot. Because sampling is being used, the
probabilities of erroneous decisions need to be considered. The error of

46
rejecting a good-quality lot creates a problem for the producer; the
probability of this error is called the producer’s risk. On the other hand, the
error of accepting a poor-quality lot creates a problem for the purchaser or
consumer; the probability of this error is called the consumer’s risk.

The design of an acceptance sampling plan consists of determining a
sample size n and an acceptance criterion c, where c is the maximum
number of defective items that can be found in the sample and the lot still be
accepted. The key to understanding both the producer’s risk and the
consumer’s risk is to assume that a lot has some known percentage of
defective items and compute the probability of accepting the lot for a given
sampling plan. By varying the assumed percentage of defective items in a
lot, several different sampling plans can be evaluated and a sampling plan
selected such that both the producer’s and consumer’s risks are reasonably
low..

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