SIST EN ISO 5840-1:2015

SLOVENSKI STANDARD
oSIST prEN ISO 5840-1:2014
01-julij-2014
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Cardiovascular implants - Cardiac valve prostheses - Part 1: General requirements
(ISO/DIS 5840-1:2014)
Herz- und Gefäßimplantate - Herzklappenprothesen - Teil 1: Grundlegende
Anforderungen
Implants cardiovasculaires - Prothèses valvulaires - Partie 1: Exigences générales
(ISO/DIS 5840-1:2014)
Ta slovenski standard je istoveten z: prEN ISO 5840-1
ICS:
11.040.40 Implantanti za kirurgijo, Implants for surgery,
protetiko in ortetiko prosthetics and orthotics
oSIST prEN ISO 5840-1:2014 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN ISO 5840-1:2014

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oSIST prEN ISO 5840-1:2014
DRAFT INTERNATIONAL STANDARD
ISO/DIS 5840-1
ISO/TC 150/SC 2 Secretariat: ANSI
Voting begins on: Voting terminates on:
2014-04-10 2014-07-10
Cardiovascular implants — Cardiac valve prostheses —
Part 1:
General requirements
Implants cardiovasculaires — Prothèses valvulaires —
Partie 1: Exigences générales
ICS: 11.040.40
ISO/CEN PARALLEL PROCESSING
This draft has been developed within the International Organization for
Standardization (ISO), and processed under the ISO lead mode of collaboration
as defined in the Vienna Agreement.
This draft is hereby submitted to the ISO member bodies and to the CEN member
bodies for a parallel five month enquiry.
Should this draft be accepted, a final draft, established on the basis of comments
received, will be submitted to a parallel two-month approval vote in ISO and
THIS DOCUMENT IS A DRAFT CIRCULATED
formal vote in CEN.
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
To expedite distribution, this document is circulated as received from the
IN ADDITION TO THEIR EVALUATION AS
committee secretariat. ISO Central Secretariat work of editing and text
BEING ACCEPTABLE FOR INDUSTRIAL,
composition will be undertaken at publication stage.
TECHNOLOGICAL, COMMERCIAL AND
USER PURPOSES, DRAFT INTERNATIONAL
STANDARDS MAY ON OCCASION HAVE TO
BE CONSIDERED IN THE LIGHT OF THEIR
POTENTIAL TO BECOME STANDARDS TO
WHICH REFERENCE MAY BE MADE IN
Reference number
NATIONAL REGULATIONS.
ISO/DIS 5840-1:2014(E)
RECIPIENTS OF THIS DRAFT ARE INVITED
TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
©
PROVIDE SUPPORTING DOCUMENTATION. ISO 2014

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oSIST prEN ISO 5840-1:2014
ISO/DIS 5840-1:2014(E)

Copyright notice
This ISO document is a Draft International Standard and is copyright-protected by ISO. Except as
permitted under the applicable laws of the user’s country, neither this ISO draft nor any extract
from it may be reproduced, stored in a retrieval system or transmitted in any form or by any means,
electronic, photocopying, recording or otherwise, without prior written permission being secured.
Requests for permission to reproduce should be addressed to either ISO at the address below or ISO’s
member body in the country of the requester.
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Fax + 41 22 749 09 47
E-mail copyright@iso.org
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Reproduction may be subject to royalty payments or a licensing agreement.
Violators may be prosecuted.
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oSIST prEN ISO 5840-1:2014

Contents
Foreword . v

Introduction . vi
1  Scope . 1
2  Normative references . 1
3  Terms and definitions . 2
4  Abbreviations . 11
5   Fundamental requirements . 12
6   Device description . 12
6.1   Intended use . 12
6.2  Design inputs . 12
6.2.1  Operational specifications . 12
6.2.2  Performance specifications . 142
6.2.3  Implant procedure . 12
6.2.4  Packaging, labeling, and sterilization . 13
6.3  Design outputs . 13
6.4  Design transfer (manufacturing verification/validation) . 14
6.5  Risk management . 15
7  Design verification testing and analysis / Design validation . 15
7.1  General requirements . 15
7.2  In vitro assessment . 15
7.3  Preclinical in vivo evaluation . 15
7.4  Clinical investigations . 15
Annex A (informative) Rationale for the provisions of this International Standard . 16
Annex B (normative)  Packaging . 19
Annex C (normative)  Product labels, instructions for use, and training . 20
Annex D (normative)  Sterilization . 23
Annex E (informative) In vitro test guidelines for paediatric devices . 24
Annex F (informative)  Statistical procedures when using in vitro performance
criteria . 29
Annex G (informative)  Examples and definitions of some physical and material
properties of heart valve systems . 30
Annex H (informative)  Examples of standards applicable to testing of materials
and components of heart valve systems . 40
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oSIST prEN ISO 5840-1:2014

Annex I (informative)  Raw and post-conditioning mechanical properties for
support structure materials . 45
Annex J (informative) Corrosion assessment . 47
Annex K (informative)Echocardiographic protocol . 50
Bibliography . 53


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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.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives,
Part 2.
The main task of technical committees is to prepare International Standards. Draft International
Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies
casting a vote.
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.
ISO 5840-1 was prepared by Technical Committee ISO/TC 150, Implants for surgery, Subcommittee
SC 2, Cardiovascular implants and extracorporeal systems.

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oSIST prEN ISO 5840-1:2014

Introduction
There is, as yet, no heart valve substitute which can be regarded as ideal.
This International Standard has been prepared by a group well aware of the issues associated with heart valve
substitutes and their development. In several areas, the provisions of this International Standard deliberately
have not been specified to encourage development and innovation. It does specify types of tests, test methods,
and/or requirements for test apparatus, and requires documentation of test methods and results. The areas with
which this International Standard are concerned are those which will ensure that associated risks to the patient
and other users of the device have been adequately mitigated, facilitate quality assurance, aid the clinician in
choosing a heart valve substitute, and ensure that the device will be presented at the operating table in
convenient form. Emphasis has been placed on specifying types of in vitro testing, on preclinical in vivo and
clinical evaluations, on reporting of all in vitro, preclinical in vivo, and clinical evaluations and on the labelling and
packaging of the device. Such a process involving in vitro, preclinical in vivo, and clinical evaluations is intended
to clarify the required procedures prior to market release and to enable prompt identification and management of
any subsequent problems.
With regard to in vitro testing and reporting, apart from basic material testing for mechanical, physical, chemical,
and biocompatibility characteristics, this International Standard also covers important hydrodynamic and
durability characteristics of heart valve substitutes.
The Standard does not specify exact test methods for hydrodynamic and durability testing but it offers guidelines
for the test apparatus.
This International Standard is incomplete in several areas. It is intended to be revised, updated, and/or amended,
as knowledge and techniques in heart valve substitute technology improve.




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oSIST prEN ISO 5840-1:2014
© ISO 2014 – All rights reserved
DRAFT INTERNATIONAL STANDARD  ISO/DIS 5840-1:201x
Cardiovascular implants—Cardiac valve prostheses—
Part 1: General requirements
1 Scope
1.1 This International Standard is applicable to heart valve substitutes intended for human implantation
and provides general requirements. Subsequent parts of this International Standard provide specific
requirements.
1.2 This International Standard is applicable to both newly developed and modified heart valve
substitutes and to the accessories, packaging, and labelling required for their implantation and for
determining the appropriate size of the heart valve substitute to be implanted.
1.3 This International Standard outlines an approach for qualifying the design and manufacture of a heart
valve substitute through risk management. The selection of appropriate qualification tests and methods
are derived from the risk assessment. The tests may include those to assess the physical, chemical,
biological, and mechanical properties of heart valve substitutes and of their materials and components.
The tests may also include those for pre-clinical in vivo evaluation and clinical evaluation of the finished
heart valve substitute.
1.4 This International Standard defines operational conditions for heart valve substitutes.
1.7 This International Standard excludes homografts.
NOTE—A rationale for the provisions of this International Standard is given in Annex A.
2 Normative references
The following referenced documents are indispensable for the application 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 11135-1:2007, Sterilization of health care products -- Ethylene oxide -- Part 1: Requirements for
development, validation and routine control of a sterilization process for medical devices

ISO 11135-2: Sterilization of health care products -- Ethylene oxide -- Part 2: Guidance on the application
of ISO 11135-1

ISO 11137-1, Sterilization of health care products — Radiation -- Part 1: Requirements for development,
validation and routine control of a sterilization process for medical devices
ISO 11137-2, Sterilization of health care products — Radiation — Part 2: Establishing the sterilization
dose
ISO 11137-3, Sterilization of health care products — Radiation — Part 3: Guidance on dosimetric aspects
ISO 11607-1, Packaging for terminally sterilized medical devices -- Part 1: Requirements for materials,
sterile barrier systems and packaging systems
ISO 11607-2, Packaging for terminally sterilized medical devices — Part 2: Validation requirements for
forming, sealing and assembly processes
ISO 14155:2011, Clinical investigation of medical devices for human subjects—Part 1: General
requirements

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oSIST prEN ISO 5840-1:2014

ISO 14160, Sterilization of single-use medical devices incorporating materials of animal origin—Validation
and routine control of sterilization by liquid chemical sterilants

ISO 14630:2012, Non-active surgical implants—General requirements

ISO 14937:2000, Sterilization of health care products—General requirements for characterization of a
sterilizing agent and the development, validation and routine control of a sterilization process for medical
devices

ISO 14971:2007, Medical devices—Application of risk management to medical devices
ISO 17665-1, Sterilization of health care products -- Moist heat -- Part 1: Requirements for the
development, validation and routine control of a sterilization process for medical devices

3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.


3.1
accessories
device-specific tools that are required to assist in the implantation of the heart valve substitute

3.2
adverse event
AE
untoward medical occurrence in a study subject which does not necessarily have to have a causal
relationship with study treatment

NOTE 1 to entry: An AE can be an unfavorable and unintended sign (including an abnormal laboratory finding),
symptom, or disease, temporary or permanent, whether or not related to the prosthetic valve implantation or procedure.
3.3
actuarial methods
statistical technique for calculating event rates over time

NOTE 1 to entry: Standard actuarial methods calculate the probability of freedom from events within pre-specified
intervals of time. When the intervals approach zero width, the methods are called Kaplan-Meier methods.

3.4
arterial end diastolic pressure
minimum value of the arterial pressure during diastole

3.5
arterial peak systolic pressure
maximum value of the arterial pressure during systole

3.6
back pressure
differential pressure applied across the valve during the closed phase

3.7
body surface area
BSA
2
total surface area (m ) of the human body

NOTE 1 to entry: This can be calculated (Mosteller's formula) as the square root of the product of the weight in kg
times the height in cm divided by 3600. See Mosteller, RD.
3.8
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cardiac index
2 2
cardiac output (CO, lL/min) divided by the body surface area (BSA, m ), with units Ll/min/m

3.9 cardiac output
stroke volume times heart rate

3.10
closing volume
portion of the regurgitant volume that is associated with the dynamics of valve closure during a single
cycle

NOTE 1 to entry: See Figure 1.
3.11
coating
thin-film material that is applied to an element of a heart valve system to modify its physical or chemical
properties

3.12
compliance
relationship between change in diameter and change in pressure of a deformable tubular structure (e.g.,
valve annulus, aorta, conduit), defined in this document as:

(r r )100
2 1
C 100%
r (p  p )
1 2 1

where

C is the compliance in units of %radial change/100 mmHg
p is the diastolic pressure, in mmHg;
1
p is the systolic pressure, in mmHg;
2
 r is the inner radius at p , in millimeters;
1 1
r is the inner radius at p , in millimeters;
2 2

NOTE Reference ISO 25539-1.


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Figure 1 — Schematic representation of flow waveform and regurgitant volumes for one cycle
3.13
component-joining material
material, such as a suture, adhesive or welding compound, used to assemble the components of a heart
valve system

3.14
cumulative incidence
statistical technique where events other than death can be described by the occurrence of the event over
time without including death of the subjects

NOTE 1 to entry: Cumulative incidence is also known as “actual” analysis.

3.15
cycle
one complete sequence in the action of a heart valve substitute under pulsatile-flow conditions

3.16
cycle rate
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number of complete cycles per unit of time, usually expressed as cycles per minute (cycles/min)

3.17
design verification
establishment by objective evidence that the design output meets the design input requirements

3.18
design validation
establishment by objective evidence that device specifications conform with user needs and intended
use(s)

3.19
device failure
inability of a device to perform its intended function sufficient to cause a hazard

3.20
device migration
detectable movement or displacement of the heart valve substitute from its original position within the
implant position, without device embolization

3.21
effective orifice area
EOA
orifice area that has been derived from flow and pressure or velocity data

For in-vitro testing, EOA is defined as:
q
v
RMS
EOA =
p
51,6 *

where
2
EOA is the Effective Orifice Area (cm );
q is the root mean square forward flow (ml/s) during the positive differential pressure period;
v
RMS
p is the mean pressure difference (measured during the positive differential pressure period) (mmHg);
3
  is the density of the test fluid (g/cm ).

3.22
prosthetic valve endocarditis
any infection involving a valve in which an operation has been performed, based on reoperation, autopsy
or the Duke Criteria for Endocarditis

NOTE 1 to entry: See Li et al (2000).

3.23
failure mode
mechanism of device failure

NOTE 1 to entry: Support structure fracture, calcification, and prolapse are examples of failure modes.

3.24
flexible surgical heart valve substitute
surgical heart valve substitute wherein the occluder is flexible under physiological conditions
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NOTE 1 to entry: The orifice ring may or may not be flexible.

3.25
follow-up
continued assessment of patients who have received the heart valve substitute

3.26
forward flow volume
volume of flow ejected through the heart valve substitute in the forward direction during one cycle

3.27
fracture
disruption, under the action of applied stress or strain, of any part of the heart valve substitute that was
previously intact

3.28
heart valve substitute
device used to replace the function of a natural valve of the heart

3.29
implant site/implant position
intended location of heart valve substitute implantation or deployment

3.30
intended use
use of a product or process in accordance with the specifications, instructions, and information provided
by the manufacturer

3.31
leakage volume
portion of the regurgitant volume which is associated with leakage during the closed phase of a valve in a
single cycle and is the sum of the transvalvular leakage volume and paravalvular leakage volume

NOTE 1 to entry: The point of separation between the closing and leakage volumes is obtained according to a defined
and stated criterion (the linear extrapolation shown in Figure 1 is just an example).

3.32
linearized rate
total number of events divided by the total time under evaluation

NOTE 1 to entry: Generally, the rate is expressed in terms of percent per patient year.

3.33
major bleeding
any episode of major internal or external bleeding that causes death, hospitalization, or permanent injury
(e.g. vision loss) or necessitates transfusion

3.34
mean arterial pressure
time-averaged arithmetic mean value of the arterial pressure during one cycle

3.35
mean pressure difference / mean pressure gradient
time-averaged arithmetic mean value of the pressure difference across a heart valve substitute during the
forward-flow phase of the cycle

3.36
nonstructural valve dysfunction
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abnormality extrinsic to the heart valve substitute that results in stenosis, regurgitation and/or haemolytic
anemia

3.37
occluder/leaflet
component that inhibits backflow

3.38
outflow tract profile height
maximum distance that the heart valve substitute extends axially into the outflow tract in the open or
closed position, whichever is greater, measured from the valve structure intended to mate with the top
(atrial or aortic/pulmonic side) of the patient's annulus

3.39
pannus
ingrowth of tissue onto the heart valve substitute which may interfere with normal functioning

3.40
paravalvular leakage volume
portion of the leakage volume that is associated with leakage around the closed heart valve substitute
during a single cycle

3.41
profile height
maximal axial dimension of a heart valve substitute in the open or closed position, whichever is greater

3.42
reference valve
heart valve substitute with a known clinical experience used for comparative preclinical and clinical
evaluations

NOTE 1 to entry: The reference valve should be legally marketed and approximate the test heart valve substitute in
type, configuration, and tissue annulus diameter; it may be an earlier model of the same valve, if it fulfils the necessary
conditions. The characteristics of the reference valve should be well documented with clinical data.

3.43
regurgitant fraction
regurgitant volume expressed as a percentage of the forward flow volume

3.44
regurgitant volume
volume of fluid that flows through a heart valve substitute in the reverse direction during one cycle and is
the sum of the closing volume and the leakage volume

NOTE 1 to entry: See Figure 1.

3.45
rigid surgical heart valve substitute
surgical heart valve substitute wherein the occluder(s) and orifice ring are non-flexible under physiological
conditions

3.46
risk
combination of the probability of occurrence of harm and the severity of that harm

NOTE 1 to entry: Adapted from ISO 14971

3.47
risk analysis
systematic use of available information to identify hazards and to estimate the associated risks
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NOTE 1 to entry: Adapted from ISO 14971.

3.48
risk assessment
overall process comprising a risk analysis and a risk evaluation

NOTE 1 to entry: Adapted from ISO 14971.

3.49
root mean square forward flow
RMS forward flow
square root of the integral of the volume flow rate waveform squared during the positive differential
pressure interval of the forward flow phase used to calculate EOA

NOTE 1 to entry: Defining the time interval for flow and pressure measurement as the positive pressure period of the
forward flow interval for EOA computation provides repeatable and consistent results for comparison to the Table 2
reference values.

NOTE 2 to entry:  This is calculated using the following equation:

t
2
2
q (t) dt
V

t
1

q 
V
RMS
t t
2 1


where

q
 is root mean square forward flow during the positive differential pressure period;
V
RMS
q (t) is instantaneous flow at time t;

V
t is time at start of positive differential pressure period;
1
t is time at end of positive differential pressure period.
2

q
NOTE 3 to entry: The rationale for use of is that the instantaneous pressure difference is proportional to the
V
RMS
square of instantaneous flow rate, and it is the mean pressure difference that is required.

NOTE 4 to entry: See Figure 2.
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Figure 2 — Schematic representation of the positive pressure period of an aortic forward flow
interval
3.50
safety
freedom from unacceptable risk

NOTE 1 to entry: Adapted from ISO 14971.

3.51
severity
measure of the possible consequences of a hazard

NOTE 1 to entry: Adapted from ISO 14971.

3.52
sterility assurance level
SAL
probability of a single viable microorganism occurring on an item after sterilization
6 3
NOTE 1 to entry: The term SAL takes a quantitative value, generally 10 or 10 . When applying this quantitative
6
value to assurance of sterility, an SAL of 10 has a lower value but provides a greater assurance of sterility than an
3
SAL of 10 .
NOTE 1 to entry: From ISO/TS 11139, definition 2.46.

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3.53
sterilization
validated process used to render a product free from viable microorganisms
NOTE 1 to entry: In a sterilization process, the rate of microbial inactivation is exponential and thus the survival of
a microorganism on an individual item can be expressed in terms of probability. While this probability can be reduced to
a very low number, it can never be reduced to zero.
NOTE 2 to entry: See 3.52.
NOTE 3 to entry: From ISO/TS 11139:2006.
3.54
structural valve deterioration
change in the function of a heart valve substitute resulting from an intrinsic abnormality that causes
stenosis or regurgitation

NOTE 1 to entry: This definition excludes infection, or thrombosis of the heart valve substitute. It includes intrinsic
changes such as wear, fatigue failure, stress fracture, occluder escape, suture line disruption of components of the
prosthesis, calcification, cavitation erosion, leaflet tear and stent creep.

3.55
support structure
component of a heart valve substitute that houses the occluder(s) (e.g. stent, frame, housing)

3.56
surgical heart valve substitute
heart valve substitute generally requiring direct visualization and cardiopulmonary bypass for implantation

3.57
systolic duration
systole
portion of cardiac cycle time corresponding to ventricular contraction

NOTE 1 to entry: See Figure 3.

3.58
tissue annulus diameter (TAD)
diameter in millimeters of the smallest flow area within the patient’s valve annulus

3.59
thromboembolism
any embolic event that occurs in the absence of infection after the immediate perioperative period.
Thromboembolism may be manifested by a neurological event or a noncerebral embolic event

3.60
transcatheter heart valve substitute
heart valve substitute implanted in a manner generally
...