ISO 21474-1:2020

INTERNATIONAL ISO
STANDARD 21474-1
First edition
2020-08
In vitro diagnostic medical devices —
Multiplex molecular testing for
nucleic acids —
Part 1:
Terminology and general
requirements for nucleic acid quality
evaluation
Dispositifs médicaux de diagnostic in vitro — Tests moléculaires
multiplex pour les acides nucléiques —
Partie 1: Terminologie et exigences générales pour l’évaluation de la
qualité des acides nucléiques
Reference number
ISO 21474-1:2020(E)
©
ISO 2020

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ISO 21474-1:2020(E)

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ISO 21474-1:2020(E)

Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 General considerations . 8
4.1 General . 8
4.1.1 Pre-analytical phase considerations . 8
4.1.2 Specimen quality considerations . 8
4.1.3 Nucleic acid quality considerations . 9
4.2 Multiplex molecular test quality nucleic acid and evaluation . 9
4.2.1 Evaluation of nucleic acid quality for multiplex molecular tests . 9
4.2.2 Evaluation of nucleic acid quantity .10
5 Procedure for preparation of nucleic acid.10
5.1 General .10
5.2 Preparation of samples .11
5.2.1 General.11
5.2.2 Consideration on tissue preparation .11
5.2.3 Nucleic acid extraction and purification .12
5.2.4 Quality evaluation method .13
Annex A (informative) Evaluation of RNA Integrity .15
Annex B (informative) Evaluation of DNA Integrity .16
Annex C (informative) Use of PCR to assess amplifiable DNA from FFPE samples .17
Annex D (informative) microRNA Sample .19
Bibliography .20
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ISO 21474-1:2020(E)

Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www .iso .org/ directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www .iso .org/ patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to the
World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see www .iso .org/
iso/ foreword .html.
This document was prepared by Technical Committee ISO/TC 212, Clinical laboratory testing and in
vitro diagnostic test systems.
A list of all parts in the ISO 21474 series can be found on the ISO website.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www .iso .org/ members .html.
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ISO 21474-1:2020(E)

Introduction
The first generation of in vitro diagnostics (IVD) medical devices for nucleic acid-based molecular tests
have been focused on detection or quantitation of a single nucleic acid sequence (e.g., viral RNA, mRNA
or genomic DNA) within a clinical specimen. By comparison, a multiplex molecular test simultaneously
measures multiple nucleic acid sequences of interest in a single reaction. The development and clinical
use of multiplex IVD medical devices are rapidly expanding with technological advances and new
elucidation of the clinical significance of many biomarkers.
The measurement of multiple analytes of interest in a clinical specimen is generally performed by the
following successive (or simultaneous) steps. After specimen collection, transport and storage, nucleic
acids are extracted, with or without a subsequent purification procedure. The nucleic acid is then
quantified, and its quality evaluated (if necessary), diluted (if necessary) and subjected to multiplex
molecular test(s). Multiplex molecular tests in current clinical use detect DNA or RNA targets using
various techniques, such as multiplex PCR examinations, microarrays, mass array or massive parallel
sequencing-based methodologies.
Although quality aspects of nucleic acids for single target molecular analysis (such as singleplex PCR)
[1][2]
has been described , this cannot necessarily be applied to multiplex molecular tests. Due to the
inherent competition for more than one nucleic acid target in a multiplex assay, these assays are usually
more sensitive to the isolated nucleic acid quality and quantity than single target assays. The variability
of each specimen in biological, physical and chemical properties can influence the performance of
multiplex assays to a larger degree than single target assays, potentially leading to unreliable results
and hampering patient care. Thus, sample quality evaluation should require additional considerations
for multiplex molecular tests.
The collection, transport and preparation of specimens for medical laboratory use has been addressed
in national and international efforts in general including ISO/TS 20658 “Medical laboratories—
[3]
Requirements for collection, transport, receipt and handling of samples” , “Guideline for the Quality
Management of Specimens for Molecular Methods; The Procurement, Transport, and Preparation of
[4]
Specimens” (Japan, JCCLS) and “Guideline for the Quality Management of Specimens for Molecular
[5]
Methods (Part 2) New Technologies and Sample Quality Control (Japan, JCCLS)” , and more specifically
[6][7][8]
for different biological specimen types in the series of ISO 20166, 20184, and 20186 .
This document describes the terminology and general quality requirements for nucleic acid used in
multiplex molecular tests, in order to ensure reproducible performance of such tests.
NOTE Guidelines, requirements, and performance criteria laid down in this document, are intended to
ensure that comparable, accurate and reproducible results are obtained in different laboratories.
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INTERNATIONAL STANDARD ISO 21474-1:2020(E)
In vitro diagnostic medical devices — Multiplex molecular
testing for nucleic acids —
Part 1:
Terminology and general requirements for nucleic acid
quality evaluation
1 Scope
This document provides the terms and general requirements for the evaluation of the quality of nucleic
acids as the analytes for multiplex molecular tests, which simultaneously identify two or more nucleic
acid target sequences of interest. This document is applicable to all multiplex molecular methods used
for examination using in vitro diagnostic (IVD) medical devices and laboratory developed tests (LDTs).
It provides information for both qualitative and quantitative detection of nucleic acid target sequences.
This document is intended as guidance for multiplex molecular assays that detect and/or quantify human
nucleic acid target sequences or microbial pathogen nucleic acid target sequences from human clinical
specimens. This document is applicable to any molecular in vitro diagnostic examination performed
by medical laboratories. It is also intended to be used by laboratory customers, in vitro diagnostics
developers and manufacturers, biobanks, institutions and commercial organizations performing
biomedical research, and regulatory authorities. This document is not applicable to metagenomics.
NOTE An examination procedure developed for a laboratory’s own use is often referred to as a “laboratory
developed test”, “LDT”, or “in-house test”.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 15189:2012, Medical laboratories — Requirements for quality and competence
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— ISO Online browsing platform: available at http:// www .iso .org/ obp
— I EC E le c t r op e d i a : av a i l able at ht t p:// w w w . ele c t r op e d i a ./ or g
3.1
accuracy
closeness of agreement between a measured quantity value and a true quantity value of a measurand
Note 1 to entry: The term accuracy, when applied to a set of test results, involves a combination of random
components and a common systematic error or bias component (ISO 3534-2:2006, 3.3.1).
[SOURCE: ISO/IEC Guide 99:2007, 2.13, modified — “NOTE 1”, “NOTE 2” and “NOTE 3” have been deleted,
and new “Note 1 to entry” has been added.]
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3.2
algorithm
set of rules or calculations applied to test data that generate an interpretable or reportable result
3.3
allele
any of several forms of a gene that is responsible for hereditary variation
Note 1 to entry: An allele can also be defined as:
1) one of the alternate forms of a polymorphic DNA sequence that is not necessarily contained within a gene;
2) one of the alternative forms of a gene that may occupy a given locus.
3.4
allelic ratio
ratio of a specified allele (3.3) to the total number of alleles (3.3), normally expressed as a fraction
Note 1 to entry: For example, if a specific allele (3.3) represents 40 % of the total alleles (3.3) found at a given
locus, the allelic ratio is 0,4.
Note 2 to entry: Allelic ratio is synonymous with allele frequency.
3.5
analyte
component represented in the name of a measurable quantity
[SOURCE: ISO 17511:2020, 3.1, modified — The example has been deleted.]
3.6
chemical purity
degree of contamination with chemical substances that influences the multiplex analysis
Note 1 to entry: The purity of nucleic acid for PCR is absence of interfering organic and protein components
carried through from the extraction step, as well as contaminating nucleic acids.
3.7
DNA microarray
DNA chip
solid substrate where a collection of probe DNA arranged in a specific design is attached in a high-
density fashion directly or indirectly, that assays large amounts of biological material using high-
throughput screening methods
[SOURCE: ISO 16578: 2013, 3.3]
3.8
documented procedure
specified way to carry out an activity or a process that is documented, implemented and maintained
interlaboratory comparison (3.13)
3.9
evaluation method
method of evaluating the quality specified for nucleic acid
3.10
expiry date
expiration date
upper limit of the time interval during which the performance characteristics of a material stored
under specified conditions can be assured
Note 1 to entry: Expiry dates are assigned to IVD reagents (3.16), calibrators, control materials and other
components by the manufacturer based on experimentally determined stability (3.38) properties.
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ISO 21474-1:2020(E)

[SOURCE: ISO 18113-1:2009, 3.17, modified — “Note 2 to entry” and “Note 3 to entry” have been deleted.]
3.11
external measurement standard
reference standard
material or substrate prepared for testing the compatibility of the methods of multiplex analysis, whose
property value is derived as a consensus value based on collaborative experimental work under the
auspices of a scientific or engineering group
Note 1 to entry: This is commonly targeted at the multiplex molecular analysis.
Note 2 to entry: Reference material can be used as an alternative of external measurement standard.
[SOURCE: ISO 16578:2013, 3.9, modified — “Note 1 to entry” and “Note 2 to entry” have been added.]
3.12
intended use
intended purpose
objective intent of an IVD manufacturer regarding the use of a product, process or service as reflected
in the specifications, instructions and information supplied by the IVD manufacturer
[SOURCE: ISO 18113-1:2009, 3.31, modified — “Note 1 to entry” and “Note 2 to entry” have been
deleted.]
3.13
interlaboratory comparison
organization, performance and evaluation of measurements or tests on the same or similar items by
two or more laboratories in accordance with predetermined conditions
[SOURCE: ISO/IEC 17043:2010, 3.4]
3.14
in vitro diagnostic instrument
IVD instrument
equipment or apparatus intended by a manufacturer to be used as an IVD medical device (3.15)
[SOURCE: ISO 18113-1:2009, 3.26, modified — “Note 1 to entry” has been deleted.]
3.15
in vitro diagnostic product
in vitro diagnostic medical device
IVD medical device
reagents, instruments, and systems intended for use in the diagnosis of disease or other conditions,
including a determination of the state of health, in order to cure, mitigate, treat, or prevent disease or
its sequelae
[SOURCE: 21CFR809.3 of the US Federal Food, Drug and Cosmetic Act]
3.16
in vitro diagnostic reagent
IVD reagent
chemical, biological, or immunological components, solutions or preparations intended by the
manufacturer to be used with an IVD medical device (3.15)
[SOURCE: ISO 18113-1:2009, 3.28, modified — “Note 1 to entry” has been deleted.]
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3.17
laboratory developed tests
LDTs
type of in vitro diagnostic devices that are intended for clinical use and are designed, manufactured
and used within a single laboratory
Note 1 to entry: It is often referred to as a “in-house test”.
[SOURCE: CLSI QSRLDT]
3.18
limit of detection
LOD
measured quantity value, obtained by a given measurement procedure, for which the probability of
falsely claiming the absence of a component in a material is β, given a probability α of falsely claiming
its presence
Note 1 to entry: IUPAC recommends default values for α and β equal to 0,05.
Note 2 to entry: This is for LODs when the tests are evaluating the presence or absence of multiple analytes (3.5)
rather than a multivariable molecular test (3.26).
Note 3 to entry: Limit of detection, LOD, is alternatively defined as 1) the lowest quantity of a nucleic acid that
can be sequenced reliably and distinguished from its absence typically within a stated confidence limit; 2) the
minimum detectable allelic fraction in a given sample.
[SOURCE: CLSI MM09 2014]
3.19
limit of detection for microarray platform
limit of detection for multiplex molecular test platform
LODP
lowest relative quantity of the external measurement standard (3.11) (or reference material) that
can be consistently detected experimentally at a 95 % confidence level, given a known (determined/
estimated) number of copies and/or concentration of the external measurement standard (3.11) (or
reference material)
Note 1 to entry: This is commonly targeted at the multiplex molecular analysis.
Note 2 to entry: LODP can be used as a performance indicator replaced by limit of detection (3.18) for multiplex
analysis.
[SOURCE: ISO 16578:2013, 3.1, modified — “Note 1 to entry” and “Note 2 to entry” have been added.]
3.20
massive parallel sequencing
methodology that enables high-throughput DNA sequencing using the concept of processing a very
large number of molecules in parallel
Note 1 to entry: For example but not limited to the technologies with miniaturized and parallelized platforms
for sequencing of thousands to millions of short reads (≈50 to 400 bases), or polymerase-based real-time DNA
sequencing platform enabling long read (mean length ≈10,000–15,000 bases).
3.21
microRNA
17 to 25 nucleotide-long single strand RNA relating to post transcriptional expression regulation
3.22
multiple sequences of analyte(s)
constituent of a sample with multiple sequences of nucleic acid measured simultaneously
Note 1 to entry: This includes extracted nucleic acid and that before and/or after amplification in case of nucleic
acid amplification-based assay.
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3.23
multiplex molecular test
in vitro diagnostic test that simultaneously evaluates sequence identity and/or amounts of multiple,
namely two or more nucleic acid targets of interest in a single run of the assay, such as multiplex PCR
(3.25), multiple hybridization detection, microarray and massive parallel sequencing (3.20) based
methodologies
Note 1 to entry: “Multiplex” is defined as “those in which two or more targets are simultaneously detected
through a common process of sample preparation, target or signal amplification, allele (3.3) discrimination, and
[24]
collective interpretation. (CLSI/MM17-A ).
Note 2 to entry: Targets of interest is defined as detection targets of interest and exclude the control material
from being a target.
3.24
multiplex molecular test quality nucleic acid
nucleic acid template with appropriate property that ensures the measurement by a multiplex molecular
test (3.23) such as that of sufficient length, quantity, chemical purity (3.6), structural integrity (3.40),
and presence of nucleic acid sequence of interest
3.25
multiplex PCR
PCR technique that employs multiple pairs of primers combined within a single reaction mixture to
produce multiple amplicons simultaneously
[SOURCE: ISO 16577:2016, 3.117]
3.26
multivariable molecular test
molecular test that combines the values of multiple variables using an interpretation function to yield a
single, patient-specific result including “classification,” “score” and/or “index”
Note 1 to entry: This is usually based on a platform of multiplex molecular tests.
Note 2 to entry: This is intended for use in the diagnosis of disease or other conditions, or in the cure, mitigation,
treatment or prevention of disease.
Note 3 to entry: The term “multivariable” as used in statistics implies the evaluation of multiple outcomes rather
than using multiple variables to evaluate a single outcome.
3.27
pathogen
infectious agent that causes diseases in its host
Note 1 to entry: Pathogen includes some virus, viroid, prion, bacterium, fungus, or parasite.
[SOURCE: ISO 15714:2019, 3.1.2, modified.]
3.28
PCR quality DNA
DNA template of sufficient length, quantity, chemical purity (3.6), and structural integrity (3.40) to be
amplified by PCR
[SOURCE: ISO 24276:2006, 3.2.3, modified — “quantity” is added.]
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3.29
preanalytical phase
pre-examination processes
processes that start, in chronological order, from the clinician’s request and include the examination
request, preparation and identification of the patient, collection of the primary sample(s), and
transportation to and within the laboratory, isolation of analytes, and end when the analytical
examination begins
[SOURCE: ISO 15189:2012, 3.15, modified — The words "isolation of analytes" have been added.]
3.30
primary sample
specimen
discrete portion of a body fluid or tissue taken for examination, study or analysis of one or more
quantities or properties assumed to apply for the whole
Note 1 to entry: Global Harmonisation Task Force (GHTF) uses the term specimen in its harmonized guidance
documents to mean a sample of biological origin intended for examination by a medical laboratory.
Note 2 to entry: In some ISO and CEN documents, a specimen is defined as “a biological sample derived from the
human body".
Note 3 to entry: In some countries, the term “specimen” is used instead of primary sample (or a subsample
of it), which is the sample prepared for sending to, or as received by, the laboratory and which is intended for
examination.
[SOURCE: ISO 15189:2012, 3.16]
3.31
range of reliable signal
ability (within a given range) to provide results that are directly proportional to the concentration and/
or copy number of the external measurement standard (3.11) (or reference material)
Note 1 to entry: This is used mostly for quantitative but not qualitative tests.
Note 2 to entry: Linear range or analytical measurable range is also used.
[SOURCE: ISO 16578:2013, 3.2, modified — "Note 1 to entry” and “Note 2 to entry” have been added.]
3.32
reportable range
region of the genome in which sequence of an acceptable quality can be covered by the laboratory test
Note 1 to entry: The reportable range is also defined as “the range of test values over which the relationship
between the instrument, kit, or system's measurement response is shown to be valid” (US CFR 493).
3.33
reference range
reportable sequence variations the assay can detect that are expected to occur in an unaffected
population
Note 1 to entry: A reference range is also defined as a set of values that include upper and lower limits of a
laboratory test based on a group of otherwise healthy people.
3.34
RT
reverse transcription
synthesis of DNA from an RNA template using a reverse transcriptase enzyme combined with an RT-
primer in the presence of deoxyribonucleoside triphosphate
[SOURCE: ISO 22174:2005, 3.3.1]
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3.35
RT-PCR
method consisting of two reactions, a reverse transcription (3.34) of RNA to DNA and a subsequent PCR
[SOURCE: ISO 22174:2005, 3.4.2]
3.36
RT-PCR quality RNA
RNA template of sufficient length, quantity, chemical purity and structural integrity suitable for reverse
transcription (3.34) and PCR
[SOURCE: ISO 22174:2005, 3.2.4, modified.]
3.37
sample
one or more parts taken from a primary sample
[SOURCE: ISO 15189:2012, 3.24, modified — The example has been deleted.]
3.38
stability
ability of an IVD medical device (3.15) to maintain its performance characteristics within the limits
specified by the manufacturer
Note 1 to entry: Stability applies to:
— IVD reagents (3.16), calibrators and controls, when stored, transported and used in the conditions specified
by the manufacturer;
— Reconstituted lyophilized materials, working solutions and materials removed from sealed containers
(when prepared, used and stored according to the manufacturer’s instructions for use).
Note 2 to entry: Stability of an IVD reagent (3.16) or measuring system is normally quantified with respect to time:
— in terms of the duration of a time interval over which a metrological property changes by a stated amount;
— in terms of the change of a property over a stated time interval.
[SOURCE: ISO 18113-1:2009, 3.68, modified — “Measuring instruments or measuring systems after
calibration “in the “Note 1 to entry” and “Note 3 to entry” have been deleted.]
3.39
specimen stability
resistance of a specimen to quality change during long-term storage
[SOURCE: ISO 23833: 2013, 5.5.10, modified — The text “changes in chemical composition during
electron bombardment, i.e. the resistance to change of the intensity of the relevant characteristic X
rays observed during the time the specimen is exposed to the electron beam” has been replaced with
“quality change during long-term storage”.]
3.40
structural integrity
degree of preservation of nucleic acid reflecting the original state
3.41
validation
confirmation, through the provision of objective evidence, that the requirements for a specific intended
use (3.12) or application have been fulfilled
Note 1 to entry: The word “validated” is used to designate the corresponding status.
[SOURCE: ISO 9000:2015, 3.8.13, modified — “Note 1 to entry” and “Note 3 to entry” have been deleted.]
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3.42
verification
confirmation, through provision of objective evidence, that specified requirements have been fulfilled
Note 1 to entry: The word “verified” is used to designate the corresponding status.
Note 2 to entry: Confirmation can comprise activities such as
— performing alternative calculations,
— comparing a new design specification with a similar proven design specification,
— undertaking tests and demonstrations, and
— reviewing documents prior to issue.
[SOURCE: ISO 9000:2015, 3.8.12, modified — “Note 1 to entry” and “Note 2 to entry” have been
reworded.]
4 General considerations
4.1 General
4.1.1 Pre-analytical phase considerations
For general statements on quality management s
...