Name: ASTM F3295-18 - Standard Guide for Impingement Testing of Total Disc Prostheses
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Abstract

Standard Guide for Impingement Testing of Total Disc Prostheses

SIGNIFICANCE AND USE
5.1 This guide can be used to develop test parameters for evaluating fatigue and wear behavior of IVD prostheses under impingement loading. It must be recognized, however, that there are likely many possible impingement conditions for a given IVD prosthesis.
5.2 The user should attempt to determine the clinically relevant and geometrically possible impingement conditions and dictated by the design and impingement wear test parameters that may result in wear and fatigue damage for the IVD prosthesis. The user should also attempt to select the device size which will represent a worst case for the impingement conditions and parameters selected.
5.3 The user should reference and utilize existing sources of information to identify the impingement test parameters that produce the clinically relevant impingement wear and damage for their IVD prosthesis. Prior clinical experience with the device design may aid in the development of impingement test parameters through analysis of device retrievals and radiographs. However, prior clinical experience with the IVD being tested should not be considered as a prerequisite for performing impingement testing.
5.4 This guide details a three-step process for assessing device impingement under a selected set of conditions:
5.4.1 The user selects previously identified impingement conditions, one at a time, or clinically observed conditions.
5.4.2 The user selects the worst-case size of device to apply the selected conditions.
5.4.3 Solid modeling and the quasistatic test method should be employed to assess the impingement condition and determine the impingement test parameters – most importantly, the angular displacement limits to be used in the impingement wear test.
5.4.4 The impingement wear test is then conducted using the impingement test parameters.
5.5 This guide serves to evaluate devices with various designs, materials (i.e., metal-on-metal versus polymer-on-polymer), and stiffness in the impingement reg...
SCOPE
1.1 This standard is intended to provide guidance on the evaluation of wear and fatigue characteristics of total disc prostheses under cyclic impingement conditions.
1.2 This guide describes impingement testing of devices with articulating components. The user is cautioned that the methods described herein are intended to produce an impingement condition which may or may not be indicative of clinical performance and which may or may not be consistent with the intended use of the device, and that this should be considered when interpreting the data. Clinically, total disc prostheses should always be implanted per labeling and the manufacturer’s instructions for use.
1.3 Impingement has been observed in retrievals among several total disc prosthesis designs; however, impingement is not necessarily associated with device or clinical failure. It is the intent of this guide to investigate possible impingement-induced wear and mechanical failure modes associated with device design, as well as potential mechanical failure modes associated with clinical events such as subsidence, malpositioning, and improper implant sizing. Note that mechanical failure may or may not be associated with functional failure.
1.4 It is recommended that the user define the bearing and non-bearing features of the intervertebral disc (IVD) prosthesis and evaluate the performance of the IVD prosthesis under Mode 1 wear by using Guide F2423 or ISO 18192-1 prior to use of this guide. This standard is not intended to provide guidance on Mode I testing.
1.5 The goal of this guide is to evaluate impingement in IVD prostheses regardless of the intended region of the spine (cervical or lumbar), material or material combinations (ceramic, metal, polymer), and bearing type (fixed or mobile).
1.6 It is the intent of this guide to enable comparison of IVD prostheses with regard to wear and fatigue characteristics when tested under the specified cond...

General Information

Status

Published

Publication Date

30-Jun-2018

ICS

11.180.10 - Aids and adaptation for moving

Technical Committee

F04 - Medical and Surgical Materials and Devices

Drafting Committee

F04.25 - Spinal Devices

Current Stage

Ref Project

Relations

Refers

ASTM F1877-16 - Standard Practice for Characterization of Particles

Effective Date

01-Oct-2016

Refers

ASTM F1714-96(2018) - Standard Guide for Gravimetric Wear Assessment of Prosthetic Hip Designs in Simulator Devices

Effective Date

01-Apr-2018

Refers

ASTM F561-19 - Standard Practice for Retrieval and Analysis of Medical Devices, and Associated Tissues and Fluids

Effective Date

01-Jan-2019

Refers

ASTM E1402-13(2018) - Standard Guide for Sampling Design

Effective Date

01-Nov-2018

Refers

ASTM E4-14 - Standard Practices for Force Verification of Testing Machines

Effective Date

01-Jun-2014

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ASTM F3295-18 - Standard Guide for Impingement Testing of Total Disc Prostheses

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ASTM F3295-18 - Standard Guide...

This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: F3295 − 18
Standard Guide for
1
Impingement Testing of Total Disc Prostheses
This standard is issued under the ﬁxed designation F3295; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 1.7 The values stated in SI units are to be regarded as the
standard with the exception of angular measurements which
1.1 This standard is intended to provide guidance on the
should be reported in degrees.
evaluation of wear and fatigue characteristics of total disc
1.8 The use of this standard may involve the operation of
prostheses under cyclic impingement conditions.
potentially hazardous equipment. This standard does not pur-
1.2 This guide describes impingement testing of devices
port to address all of the safety concerns, if any, associated
with articulating components. The user is cautioned that the
with its use. It is the responsibility of the user of this standard
methods described herein are intended to produce an impinge-
to establish appropriate safety, health, and environmental
ment condition which may or may not be indicative of clinical
practices and determine the applicability of regulatory limita-
performance and which may or may not be consistent with the
tions prior to use.
intended use of the device, and that this should be considered
1.9 This international standard was developed in accor-
when interpreting the data. Clinically, total disc prostheses
dance with internationally recognized principles on standard-
should always be implanted per labeling and the manufactur-
ization established in the Decision on Principles for the
er’s instructions for use.
Development of International Standards, Guides and Recom-
1.3 Impingement has been observed in retrievals among
mendations issued by the World Trade Organization Technical
several total disc prosthesis designs; however, impingement is
Barriers to Trade (TBT) Committee.
not necessarily associated with device or clinical failure. It is
2. Referenced Documents
the intent of this guide to investigate possible impingement-
2
induced wear and mechanical failure modes associated with
2.1 ASTM Standards:
device design, as well as potential mechanical failure modes
E4Practices for Force Veriﬁcation of Testing Machines
associated with clinical events such as subsidence,
E1402Guide for Sampling Design
malpositioning, and improper implant sizing. Note that me-
E1488GuideforStatisticalProcedurestoUseinDeveloping
chanical failure may or may not be associated with functional
and Applying Test Methods
failure.
F561 Practice for Retrieval and Analysis of Medical
Devices, and Associated Tissues and Fluids
1.4 It is recommended that the user deﬁne the bearing and
F1714GuideforGravimetricWearAssessmentofProsthetic
non-bearingfeaturesoftheintervertebraldisc(IVD)prosthesis
Hip Designs in Simulator Devices
and evaluate the performance of the IVD prosthesis under
F1877Practice for Characterization of Particles
Mode 1 wear by using Guide F2423 or ISO 18192-1 prior to
F2423Guide for Functional, Kinematic, and Wear Assess-
use of this guide. This standard is not intended to provide
ment of Total Disc Prostheses
guidance on Mode I testing.
3
2.2 ISO Standard:
1.5 The goal of this guide is to evaluate impingement in
ISO 18192–1Implants for surgery—Wear of total interver-
IVD prostheses regardless of the intended region of the spine
tebral spinal disc prostheses—Part 1: Loading and dis-
(cervical or lumbar), material or material combinations
placement parameters for wear testing and corresponding
(ceramic, metal, polymer), and bearing type (ﬁxed or mobile).
environmental
1.6 ItistheintentofthisguidetoenablecomparisonofIVD
3. Terminology
prostheseswithregardtowearandfatiguecharacteristicswhen
tested under the speciﬁed conditions.
3.1 Deﬁnitions of Terms Speciﬁc to This Standard:
2
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
1
This guide is under the jurisdiction ofASTM Committee F04 on Medical and contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Surgical Materials and Devices and is the direct responsibility of Subcommittee Standards volume information, refer to the standard’s Document Summary page on
F04.25 on Spinal Devices. the ASTM website.
3
Current edition approved July 1, 2018. Published August 2018. DOI: 10.1520/ Available fromAmerican National Standards Institute (ANSI), 25 W. 43rd St.,
F3295–18. 4th Floor, New York, NY 10036, http://www.ansi.or
...

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5.1 The significance of the information to be recorded in a test report allows for exoskeleton safety and performance to be contextualized with the exoskeleton configuration. Exoskeleton tests can also be replicated across similar or different exoskeletons by using this practice to record the exoskeleton test configuration in a standardized way.
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SCOPE
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SIGNIFICANCE AND USE
5.1 Obstacles can vary greatly in, for example: length, width, height, quantity, geometry, and for a variety of industries. Fig. 2 shows examples of various obstacles.
FIG. 2 Example Obstacles in: (a) Road Construction; (b) Warehouse; (c) Manufacturing: Floor; (d) Manufacturing: Overhead; (e) Military Obstacle Course
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1.1.5 ASTM Subcommittee F48.03 develops and maintains international standards for task performance and environmental considerations that include but are not limited to, standards for safety, quality, and efficiency. This subcommittee aims to develop standards for any exoskeleton application as exemplified as in 1.1.2. The F48.03 test suite consists of a set of test methods ...

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Standard Practice for Recording the Exoskeleton User Information

SIGNIFICANCE AND USE
5.1 The significance of the information to be recorded in a test report allows for exoskeleton safety and performance to be contextualized with the exoskeleton user. Exoskeleton test results can be compared across users to determine exoskeleton usefulness, exoskeleton capability for particular users or groups of users, and standardized reporting of user information allows organizations to better replicate tests.
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5.3.1 2012 Anthropometric Survey (ANSUR II6) of U.S. Army Personnel: Methods and Summary Statistics,
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5.3.5 Tables D7878/D7878M,
5.3.6 Tables D6960/D6960M,
5.3.7 Terminology D5219,
5.3.8 Tables D8241/D8241M,
5.3.9 Practice E3003,
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5.3.11 ISO 7250-1.
SCOPE
1.1 This practice describes a means to record the exoskeleton user information when testing. The practice provides a method for recording exoskeleton user: general information, measurements, activity level, experience with exoskeletons, prior injuries, and other pertinent information that may impact exoskeleton testing.
1.2 This practice is intended to be used with other exoskeleton test methods and practices to provide a clear representation of the exoskeleton user being tested; provides a basis for comparison of the test circumstances across different exoskeletons, users, tests, or all three; and allows a test to be recreated.
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Standard Practice for Recording the Exoskeleton Fit to the User

SIGNIFICANCE AND USE
5.1 The significance of the information to be recorded in a test report allows for exoskeleton safety and performance to be contextualized with the exoskeleton fit to the user. Exoskeleton tests can also be replicated across similar or different exoskeletons by using this practice to record the exoskeleton fit to the user for a test in a standardized way.
5.2 Limitations of the practice are that not all exoskeletons have the same connections to the body and fit to all users, and therefore, fit to the user may change the exoskeleton capabilities. For example, as users vary in size, shape, gender, etc., an exoskeleton that is fit to one user may allow an increase or decrease in torque applied to the arms, legs, etc. as compared to another user, especially users at the upper and lower limits of manufacturer-suggested exoskeleton sizing. Another example is that an exoskeleton that is not fit properly to a user may be uncomfortable, and as a result the user may not perform tasks as long, as fast, as strong/delicately, or many other possible outcomes.
5.3 It is expected that all exoskeleton tests require the exoskeleton to be fit properly to the user according to manufacturer specifications. However, as testing exoskeletons can vary, so can fit to the user, and variations in fit may also be tested. For example, a test may be performed with the exoskeleton not fit properly to the users’ legs (for example, longer fit on shorter legs) to evaluate performance changes when the task requires the user to stand on their toes. Should exoskeleton tests be performed with the exoskeleton not fit properly to the user, the test requestor should verify with the manufacturer that the exoskeleton will not harm the user as a result of a bad fit, and provide this information to the test administrator to record on the test report.
5.4 Additional fit and measurement information may be found in Terminology D5219, Practice E3003, and Practice F1731.
SCOPE
1.1 This practice describes a means to record the exoskeleton fit to the user when testing. The practice provides a method for recording exoskeleton: alignment to the user, component distances from the body, sizing, and subjective comfort using a standard recording method.
1.2 This practice is intended to be used with other exoskeleton test methods and practices to provide a clear representation of the exoskeleton fit to the user measured along body planes; provides a basis for comparison of the test circumstances across different exoskeletons or tests, or both; and allows a test to be recreated.
1.3 The values stated in SI units are to be regarded as the standard. The values given in parentheses are not precise mathematical conversions to imperial units. They are close approximate equivalents for the purpose of specifying exoskeleton characteristics while maintaining repeatability and reproducibility of the test method results. These values given in parentheses are provided for information only and are not considered standard.
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
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SIGNIFICANCE AND USE
5.1 Beams and beams with platforms can vary greatly in, for example: length, width, height, quantity, geometry, surface coatings, and for a variety of industries. Fig. 2 shows examples of various beams and beams with platforms.
FIG. 2 Example Beams: (a) Steel Construction Beams; (b) Steel Construction Beam to a Platform; (c) Log Construction Beam; (d) Playground Log Beam; (e) Log Beam across Water; and (f) Balance Beam used for Gymnastics
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SCOPE
1.1 Purpose:
1.1.1 The purpose of this test method, as a part of a suite of exoskeleton use test methods, is to quantitatively evaluate an exoskeleton’s (see Terminology F3323) safety (see 1.4) or performance, or both, when traversing beams.
1.1.2 Exoskeletons shall possess a certain set of allowable exoskeleton user movement capabilities, including user-motion adaptability, to suit operations such as: industrial/occupational, military, response, medical, or recreational.
1.1.3 Environments in these typical sectors often pose constraints to exoskeleton user movement to various degrees. Being able to traverse beams, as intended by the user or test requestor, while using an exoskeleton, is essential for exoskeleton deployment for a variety of tasks (for example, ascending/descending stairs, ramps, hills). This test method specifies test setup, procedure, and recording to standardize this beams task for testing exoskeleton user movement.
1.1.4 Exoskeletons need to function as intended, regardless of types of tasks and terrain complexities (for example, carpet, metal, masonry, rock, wood). Required movement capabilities may include, for example: walking, running, crawling, climbing, traversing gaps, hurdles, stairs, beams, slopes, various types of floor surfaces or terrains, or confined spaces, or combinations thereof. Standard test methods are required to evaluate whether or not exoskeletons meet these requirements.
1.1.5 ASTM Subcommittee F48.03 develops and maintains international standards for task performance and environmental considerations that include but are not limited to, standards for safety, quality, and efficiency. This subcommittee aims to develop standards for any exoskeleton application as exemplified as in 1.1.2. The F48.03 test suite consists of a set of test methods for evaluating exoskeleton capability requirements. This beams test method is a part of the test suite. The setup, procedure,...

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ASTM

ASTM F3582-22(Test Method)

Standard Test Method for Exoskeleton Use: Gaps

SIGNIFICANCE AND USE
5.1 Exoskeletons are being used in the industrial/occupational, military, response, medical, and recreational sectors to enhance safety and effectiveness of the user to perform tasks. Traversing gaps is a component of many tasks that someone would do with an exoskeleton. For example, an exoskeleton may be used to help a worker in building construction where gaps in ground surfaces are prevalent. In the military, and other similar environments, soldiers using exoskeletons may traverse gaps along paths carrying loads. Fig. 1 shows examples of gaps typically found in various environments in which persons using exoskeletons may be required to step over gaps. The testing results of exoskeletons shall describe, in a statistically significant way, how reliably the exoskeleton is able to support tasks within the specified types of environments, confinements, and terrains, and thus provide sufficiently high levels of confidence to determine the applicability of the exoskeleton to a given task.
5.2 This test method addresses exoskeleton safety and performance requirements expressed by manufacturing, medical, emergency responders, military, or other organizations requesting this test. The safety and performance data captured within this test method are indicative of the test exoskeleton’s and the exoskeleton user’s capabilities. The safety and performance data from these tests are essential to guiding the procurement and deployment decisions of exoskeleton purchasers and users.
5.3 The standard test setup and apparatus (see Section 6) is specified to be easily fabricated. This facilitates evaluation and replication of gap tests by exoskeleton sectors. The standard test setup and apparatus can also be used to support training (see Practice F3444/F3444M) and to establish proficiency of exoskeleton users, as well as provide manufacturers with information about the usefulness of their exoskeleton(s) for tasks.
5.4 Although the test method was developed for the sectors lis...
SCOPE
1.1 Purpose:
1.1.1 The purpose of this test method, as a part of a suite of exoskeleton use test methods, is to quantitatively evaluate an exoskeleton’s (see Terminology F3323) performance or safety, or both, of usage by the exoskeleton user (see 1.4) for gaps.
1.1.2 Exoskeletons shall possess a certain set of allowable exoskeleton user movement capabilities, including user-motion adaptability, to suit operations such as: industrial/occupational, military, response, medical, or recreational. Environments in these typical sectors often pose constraints to exoskeleton user movement to various degrees. Being able to step over gaps, as intended by the user or test requestor, while using an exoskeleton is essential for exoskeleton deployment for a variety of tasks. This test method specifies test setup, procedure, and recording to standardize this gaps task for testing exoskeleton user movement.
1.1.3 Exoskeletons need to function as intended, regardless of types of tasks and terrain complexities (for example, carpet, metal, masonry, rock, wood). Required movement capabilities may include, for example: walking, running, crawling, climbing; traversing gaps, stairs, slopes, various types of floor surfaces or terrains, or confined spaces, or combinations thereof. Standard test methods are required to evaluate whether or not exoskeletons meet these requirements.
1.1.4 ASTM Subcommittee F48.03 develops and maintains international standards for task performance and environmental considerations that include but are not limited to, standards for safety, quality, and efficiency. This subcommittee aims to develop standards for any exoskeleton application as exemplified as in 1.1.2. The F48.03 test suite consists of a set of test methods for evaluating exoskeleton capability requirements. This gaps test method is a part of the test suite. The setup, procedure, and apparatuses associated with the test methods challenge speci...

Standard
17 pages
English language
sale 15% off

14-Nov-2022
11.180.10
25.040.30
F48