ISO/PRF TR 22293

TECHNICAL ISO/TR
REPORT 22293
First edition
Evaluation of methods for assessing
the release of nanomaterials from
commercial, nanomaterial-containing
polymer composites
Évaluation des méthodes de détermination d'émission de
nanomatériaux par des polymères composites commerciaux,
contenant des nanomatériaux
PROOF/ÉPREUVE
Reference number
ISO/TR 22293:2021(E)
ISO 2021
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ISO/TR 22293:2021(E)
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© ISO 2021

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Foreword ..........................................................................................................................................................................................................................................v

Introduction ................................................................................................................................................................................................................................vi

1 Scope ................................................................................................................................................................................................................................. 1

2 Normative references ...................................................................................................................................................................................... 1

3 Terms and definitions ..................................................................................................................................................................................... 1

4 Abbreviations........................................................................................................................................................................................................... 3

5 Understanding the nano-enabled products ............................................................................................................................. 4

5.1 Pathway analysis for the supply chain ................................................................................................................................ 4

5.2 Matrix and MNM characteristics affecting rate and form of release......................................................... 8

5.2.1 General...................................................................................................................................................................................... 8

5.2.2 Consideration of the polymer used in the composite ...................................................................... 9

5.2.3 Polymer degradation .................................................................................................................................................10

5.2.4 Consideration of MNM used in the composite ....................................................................................10

5.2.5 Polymer nanocomposites ......................................................................................................................................11

5.2.6 Application areas and use phase (or lifecycle) processes .........................................................12

6 Factors affecting release measurement method selection ....................................................................................15

6.1 General ........................................................................................................................................................................................................15

6.2 Forms of release ..................................................................................................................................................................................16

consideration with examples ...................................................................................................................................................21

added manufactured nanomaterials ............................................................................................................................................23

7.1 General ........................................................................................................................................................................................................23

7.2 Methods for sampling released material .......................................................................................................................23

7.2.1 General...................................................................................................................................................................................23

7.2.2 Sampling material released into air .............................................................................................................24

7.2.3 Sampling material released into water, solids, and biological fluids ...............................25

7.3 Methods for preparing samples of released material for subsequent analysis ...........................26

7.3.1 General...................................................................................................................................................................................26

7.3.2 Preparation and analysis of air samples ...................................................................................................26

7.3.3 Preparation and analysis of waters, solids and biological fluid samples .....................27

7.4 Measurement challenges .............................................................................................................................................................28

7.4.1 General...................................................................................................................................................................................28

7.4.2 Surface functionalization and transformations..................................................................................28

7.4.3 Sample collection artefacts ..................................................................................................................................29

7.4.4 Applicability of a measurement method for a given release media ..................................29

7.4.5 Sample preparation artefacts.............................................................................................................................29

7.4.6 Capability of a measurement method .........................................................................................................29

7.4.7 Representativeness of measurements .......................................................................................................30

7.4.8 Composition measurements ...............................................................................................................................30

7.4.9 Polymer stability ...........................................................................................................................................................30

7.4.10 Commercial practices ...............................................................................................................................................30

7.5 Considerations for detection, quantification, and determination of properties of

released materials .............................................................................................................................................................................31

7.6 Applicable measurement methods .....................................................................................................................................32

frameworks, and research .......................................................................................................................................................................32

8.1 General ........................................................................................................................................................................................................32

8.2 Potential improved/new methods ......................................................................................................................................32

8.3 Inter-laboratory studies ...............................................................................................................................................................33

8.4 Protocols and assays .......................................................................................................................................................................34

8.5 Opportunities for standardization of methods ........................................................................................................34

8.6 Decision frameworks ......................................................................................................................................................................35

Annex A (informative) Example case studies............................................................................................................................................38

Bibliography .............................................................................................................................................................................................................................57

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Any feedback or questions on this document should be directed to the user’s national standards body. A

The use of manufactured nanomaterials (MNM) in consumer products and applications is growing as

manufacturers exploit the unique properties of nanomaterials. MNMs are an increasingly common

feature of a growing variety of commercial applications and consumer products — from computer chips

to golf clubs. So too are concerns over what is or can be released from products containing MNMs, and

the risk and potential impacts of exposure to such releases. These unique properties offer significant

commercial value, enabling the manufacture of products that that offer novel characteristics. The MNM

might be embedded in solids, might be suspended in fluid, or might be bound to the surface of solid

products. An understanding of what is released from products containing MNMs is critical to planning

This document aims to contribute to that understanding by providing a guide to the information to

be taken into account in determining the methods for identifying and evaluating releases of MNMs

from matrices; providing a framework for understanding how these methods and the information they

produce can support decision-making; and identifying opportunities for developing standards in this

This document provides practical support for decisions related to product development and use through

early consideration of the potential for release of MNM and through focus on realistic use scenarios

— those planning to develop or adapt technical specifications for MNM use in commercial products;

— risk managers, product developers, exposure measurement practitioners or other stakeholders

seeking guidance on the availability and utility of methods to measure releases that could occur

— methods and instrumentation developers seeking to identify needs of the risk management

— those planning basic and applied research programs for measurement and modelling to support

The structured review of the information regarding the selection of MNM measurement methods

provided in this document is needed because technologies to produce MNMs, their uses, and MNM

measurement methods are often developing at the same time, and the development of measurement

methods can in some cases lag behind product development needs. Furthermore, the need to measure

particular characteristics of the released MNM might also evolve as greater understanding of what

might cause toxicity for a particular kind of MNM is gained. This relationship between emerging

measurement methods and emerging information about toxicity makes a structured approach to review

of measurement needs even more important, so that data are assembled to support decisions using the

most up-to-date and fit-to-purpose measurement methods. Finally, the selection process for choosing

a particular MNM-composite for a product should include the consideration of whether the available

measurement methods are feasible for the evaluating the conditions of use of that MNM-composite.

This consideration is needed because many methods available for research or for controlled conditions

in industrial hygiene settings are not useful for realistic measurement needs where consumers might

be exposed. In some cases, those methods are too difficult to conduct outside of the laboratory, and in

other cases the methods are too labour-intensive to be feasible for routine decision support.

The development of the decision-making framework presented in this document is based in large part

on initial analyses that focused on releases from polyamide or epoxy polymers to which multi-wall

carbon nanotubes (MWCNT) have been added. Nonetheless, the framework can be used to inform the

selection of methods for identifying and evaluating the releases for a wide range of MNMs and types of

matrices, as illustrated by the case studies in Annex A. The case studies have been chosen because of

the availability of information and methods relevant for actual MNM-polymer composite uses.

Release from polymer nanocomposites can occur through processes such as physical, chemical, or

thermal degradation of a polymer matrix, resulting in particles that might include a mixture of free

MNM, free polymer, and matrix-bound MNM. This document focuses on the first release to human

exposure or to an effluent pathway. While acknowledging that subsequent MNM fate and transport

could follow from this initial release, the primary concern of this document is whether and where

release of MNMs can occur in the context of consumer or commercial use, and the need to monitor

likelihood of human exposure potential. Although other stages of the lifecycle of products containing

MNMs are discussed briefly to provide context, subsequent fate and transport events are not addressed

The ultimate goal is to use the report structure of this document as a foundation for addressing releases

In developing the decision-making framework set out in this document two key concepts that have

proven useful in addressing the relevant risk management issues in support of decision-making have

been applied. The first is “problem formulation” . This describes the purpose and context of the

analysis, and the nature of the decision that the analysis aims to support. By making it clear the analysis

is being conducted to support a specific decision, this approach helps to ensure the analysis remains

focused on methods that have practical application in making that decision. The second key concept

is “fit for purpose.” In other words, the nature of the analytical approach used should be sufficient for

and appropriate to addressing the specific risk management decision. This includes assuring that the

depth of analysis - including consideration of the sources and potential magnitude of uncertainty – is

consistent with the information needed to support the decision. In the context of this document, this

means that feasibility is an important consideration in the choice of analytical methods.

In applying these concepts to the selection of methods for identifying and evaluating releases of

MNMs from matrices, the problem formulation would include an evaluation of the potential for human

exposure to the component of the nano-enabled product (NEP) that contains the MNM and the potential

To evaluate the potential for human exposure, an understanding of the product design and the potential

use scenarios is required. If, for example, the component containing the MNM is fully encased within a

consumer product, or is part of a machine where it is accessible only during maintenance, there are

limited opportunities for human exposure as part of the release event. Description of potential use

scenarios is also critical for understanding the potential nature of human exposure (e.g. direct dermal

contact vs. inhalation of released MNM), as well as relevant conditions of potential wear and aging (e.g.

potential and nature of abrasion, temperature, presence or absence of water and UV light).

Together, these elements of the problem formulation can aid in determining which potential release

scenarios need to be tested, as well as the nature of the analytical methods needed and, thus, aid in

determining whether it is feasible to evaluate the risk of a given choice of product composition without

In some situations, a tiered approach — such as those described in Clause 8 — can be useful. For

example, if release outside of a confined structure is not expected (e.g. if the MNM is contained within

a phone, and release would not result in consumer exposure), an analytical method that simply detects

the MNM could be sufficient. In other cases, a qualitative description might be useful to predict the

potential for further interactions with other materials, and ultimately the fate and transport of the

MNM. Such information could be used, for example, in deciding between alternative designs or products

Finally, in some cases it could be necessary to quantitatively evaluate the MNM release in order to feed

into a quantitative risk assessment. In such cases, it is important to ensure that exposure measurements

are made in a way that facilitates integration with hazard data to evaluate risk. Such integration

includes evaluating the MNM characteristics with regard to key determinants of toxicity (e.g. degree of

aggregation and functionalization), and reporting exposure in relevant dose units. Currently completing

an evaluation of this kind presents a significant challenge, as the key determinants of toxicity and

As described in this document, key data needs to support a decision related to product development

— a description of common use scenarios, including frequency of use and relevant populations;

— a description of potential degradation mechanisms that can lead to release under the use scenario(s)

— a description of the composite matrix and its resistance to degradation under the use scenario(s) of

Based on this information, the assessor can determine the potential for release (including the release

rate) and the likely media into which the release might occur. These parameters in turn inform the

After a brief discussion of how the topic of this document relates to Lifecycle analysis, the document

addresses the structure of the polymer and the embedded MNM, and how those structures inform

measurement methods needs through their effect on the release rate and the form of the release

(Clause 5). Clause 6 describes how the relative resilience of the polymer matrix and the embedded MNM

inform measurement methods needs through their effect on the nature of the resulting release and

proposes a tiered (stepwise) decision framework for deciding if or which transformations at the release

point need to be considered. Worked examples applying the decision framework outlined in 6.3 are

presented in Annex A. Clause 7 addresses methods for measuring and describing the characteristics of

the released material, including sampling methods in various media, methods for sample preparation

and analysis, and measurement challenges. Clause 8 addresses remaining gaps and data needs, and

briefly reviews several available decision frameworks to support risk managers in determining the

information and sampling methods needed to support product design and development decisions.

It is anticipated that the information presented in this document will find application in assisting

manufacturers and regulatory agencies to more clearly identify products and scenarios with low

consumer exposure potential (e.g. where the MNM is part of a component that is fully encased) and

those products and scenarios with higher exposure potential (e.g. the MNM is in continuous contact

with human skin or is used under conditions subject to severe weathering). This document is also

intended to aid in evaluating — at the product design stage — how variation in adducts, coatings, or

This document reviews and evaluates the utility of available methods to assess material released from

commercial polymer composites in support of product use and safety decisions, and describes what

revised or additional methods are needed. The document is not focused on describing methods per

se; rather the goal is to describe information that is appropriate for consideration in the selection of

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.

For the purposes of this document, the terms and definitions given in ISO/TS 80004 (all parts) and the

ISO and IEC maintain terminological databases for use in standardization at the following addresses:

solid comprising a mixture of two or more phase-separated materials, one or more being nanophase

Note 1 to entry: Gaseous nanophases are excluded [they are covered by nanoporous material].

Note 2 to entry: Materials with nanoscale phases formed by precipitation alone are not considered to be

Note 1 to entry: Carbon nanotubes usually consist of curved graphene layers, including single-wall carbon

carbon nanotube composed of nested, concentric or near-concentric graphene sheets with interlayer

Note 1 to entry: The structure is normally considered to be many single-wall carbon nanotubes nesting each

other, and would be cylindrical for small diameters but tends to have a polygonal cross-section as the diameter

consecutive and interlinked stages of a product system, from raw material acquisition or generation

[SOURCE: ISO 14044:2006, 3.1, modified — the term has been modified from "life cycle" to "lifecycle".]

Note 1 to entry: The structure can be visualized as a graphene sheet rolled into a cylindrical honeycomb

Note 1 to entry: Properties that are not extrapolations from larger sizes are predominantly exhibited in this

collection of weakly or medium strongly bound particles where the resulting external surface area is

Note 1 to entry: The forces holding an agglomerate together are weak forces, for example van der Waals forces or

Note 2 to entry: Agglomerates are also termed secondary particles and the original source particles are termed

chemically modified graphene prepared by the oxidation of graphite causing extensive oxidative

[SOURCE: ISO/TS 80004-13:2017, 3.1.2.13, modified — "and exfoliation" has been deleted.]