A Comparative Evaluation of Protective Gloves for Law Enforcement and Corrections Applications (October 2001)


Title: A Comparative Evaluation of Protective Gloves for Law Enforcement and
Corrections Applications
Series: N/A
Author: National Law Enforcement and Corrections Technology Center
Published: October 2001
Subject: Technology in law enforcement
pages: 14
bytes: 32KB

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National Law Enforcement and Corrections Technology Center
Bulletin
A Program of the National Institute of Justice
October 2001

A Comparative Evaluation of Protective Gloves for Law Enforcement and
Corrections Applications

Protective gloves are an important part of the standard personal protective
equipment law enforcement and corrections officers should wear to avoid risks
from blood-borne pathogens, including hepatitis or human immunodeficiency
virus (HIV); from sharp-edged weapons such as knives or razor blades; and
from pointed weapons such as hypodermic needles. There are a number of
gloves on the market that claim to offer various levels of protection against
some or all of these threats, but until now there has been no objective
evaluation of their protective quality and no way to compare the performance of
one manufacturer's glove against another's. Research on protective gloves has
centered primarily on medical or industrial applications, with little focus on the
particular needs of law enforcement and corrections professionals.

In response to a request from the Law Enforcement and Corrections
Technology Advisory Council (LECTAC) to assist the law enforcement and
corrections community in acquiring better protective gloves, the Office of
Science and Technology of the National Institute of Justice (NIJ) assembled a
team from the National Law Enforcement and Corrections Technology Center
(NLECTC), the Office of Law Enforcement Standards (OLES), and the Office
of Law Enforcement Technology Commercialization to develop a comparative
evaluation protocol and a testing program for protective gloves. More
information on the development of this test protocol can be found at the end of
this bulletin.

NLECTC's advisory board, LECTAC, is composed of nationally recognized
criminal justice practitioners from Federal, State, and local agencies who assess
technological needs and set priorities for research programs and products to be
evaluated and tested. NLECTC, a program of NIJ, supervises national
comparative evaluation and standards-based testing programs that are
conducted by independent laboratories. An important part of NLECTC's
mission is to provide objective, independent testing of products to assist law
enforcement and corrections agencies to procure safe, reliable equipment. 

For most law enforcement and corrections products, there are no independent
evaluation mechanisms or performance standards. OLES works closely with
NLECTC to develop specific test protocols and evaluation methods that are
used to test equipment. The most well known of the standards-based testing
programs is the body armor program, but OLES has developed more than 200
standards for various types of law enforcement and corrections equipment,
including rechargeable batteries, handcuffs, and pistols.

In addition to standards-based testing, NLECTC also manages comparative
evaluation programs. For example, NIJ has a partnership with the Michigan
State Police to test patrol vehicles. NIJ helps to underwrite costs and, in turn,
disseminates testing data. Patrol vehicle tires and brake pads are also tested in
a similar manner. For more information on NLECTC's testing programs, visit
NLECTC's Internet site, JUSTNET, at www.justnet.org, or visit the testing
program information pages at http://testingprogram.nlectc.org.

The Protection Classes

NIJ Test Protocol 99-114 establishes three major rating types for protective
gloves, designated as Type A, pathogenic resistant (against biohazards); Type
B, cut resistant (against blades); and Type C, puncture resistant (against
hypodermic needles). Gloves that are considered to provide multiclass
protection offer any combination of classes A, B, and/or C.

Type A is specifically designed for protection against biological hazards. The
gloves should provide general protection against health hazards in the following
situations: field interrogation, apprehension, transport, and incarceration of
suspects and/or prisoners; crime scene investigation; and evidence gathering.
Type A gloves are tested for pathogenic resistance, dexterity, and tear
resistance. Puncture resistance and cut resistance may also be tested depending
on the manufacturer's claims for a particular glove.


Type B is specially designed to be cut resistant. This type of glove should
provide general protection against health hazards in the following situations: field
interrogation, apprehension, and incarceration of suspects and/or prisoners;
crime scene investigation; and evidence gathering in hostile environments where
sharp objects such as knives and/or razor blades may pose a threat. Type B
gloves are tested for dexterity, tear resistance, and cut resistance. Pathogenic
resistance and puncture resistance may also be tested depending on the
manufacturer's claims for a particular glove.

Type C is specifically designed to be puncture resistant. The gloves should
provide general protection against health hazards in the following situations: field
interrogation, apprehension, transport, and incarceration of suspects and/or
prisoners; crime scene investigation; and evidence gathering in hostile
environments where pointed and/or needle-shaped objects may pose a threat.
These gloves are intended for use while frisking or patting down suspects
and/or prisoners.

Type C gloves are tested for dexterity, tear resistance, and puncture resistance.
Pathogenic resistance and cut resistance may also be tested depending on the
manufacturer's claims for a particular glove. Table 1 shows the classifications of
gloves and how they are rated.

In the spring of 2000, protective glove manufacturers were invited to submit
models of protective gloves for testing in accordance with the requirements of
NIJ Test Protocol 99-114. Nine manufacturers submitted a total of 28 glove
models to be tested. Two laboratories, Touchstone Research Laboratory,
located in Triadelphia, West Virginia, and TRI/Austin, Inc., located in Austin,
Texas, were selected and approved to perform the testing. The gloves were
tested between September 2000 and April 2001 at the approved test
laboratories and the preliminary data were reviewed by NLECTC and OLES
staff. This bulletin provides a summary review of that data and the test
procedures, as well as an overview of some of the issues that a law
enforcement or corrections agency must consider when selecting a particular
type of protective glove. 

How To Use This Bulletin

The NIJ test protocol for protective gloves is a comparative evaluation protocol
that can be used as a procurement aid. Law enforcement and corrections
agencies can use these ratings to evaluate and compare the performance of
particular glove models, focusing on the tests that are applicable to individual
department needs. It is important to note, however, that the rating scales of the
specific test protocols were designed to test a wide range of protective
materials and clothing, including cotton and nylon, for a wide range of industrial
applications. Many of the fibers used in protective gloves are similar to the
fibers used to make ballistic- and stab-resistant protective vests. Because these
fibers have tensile strengths many times higher than steel, the test results are
skewed to the high end of the rating scales, sometimes extending beyond the
parameters of the High rating.

Because performance requirements and needs may vary greatly between
agencies, the information presented in this bulletin makes no attempt to identify
which glove models performed best in either a specific category or as an overall
test result across multiple categories. It is important that your agency place the
appropriate weights on those portions of the test data most representative of
the protection requirements determined to be essential to your agency's needs.
A sample distribution of category weights is shown in table 2.

The test results reported in this bulletin may be used in two ways. First, they
may be used as is to determine the model of protective gloves that best meet
the needs of your agency. In this case, you should emphasize those portions of
the evaluation that best reflect your agency's protection requirements. Second,
the overall test results may be used to adjust the manufacturer's bid price for
these glove models. In each test category, the absolute difference between a
glove model and the best scoring glove model is divided by the best glove
model's score, resulting in a deviation factor. This factor is then multiplied by a
category weight, such as those listed in table 2, to produce a weighted category
score. The total of these weighted scores for a particular glove model is then
used to adjust the glove's bid price.

Testing Procedures and Methods

Pathogenic Resistance

Pathogen-resistant gloves provide protection against common bodily
fluid-borne infectious diseases. Gloves that meet this criterion must provide
protection against microbiological pathogens that are transmitted through
physical contact or contact with bodily fluids, such as blood, saliva, or semen.
The gloves are tested in accordance with NFPA 1999, Sections 6-9 and 6-10,
the Standard of Protective Clothing for Emergency Medical Operations;
ASTM D5151, Standard Test Method for Detection of Holes in Medical
Gloves; and ASTM F1671, Standard Test Method for Resistance of Materials
Used in Protective Clothing to Penetration by Blood-Borne Pathogens Using
Phi-X174 Bacteriophage Penetration as a Test System.



Pathogen-resistant gloves need to have excellent barrier characteristics that will
be maintained under a variety of conditions. The test to detect for holes in
gloves is a pass/fail test in which gloves are filled with water, suspended for 2
minutes, and visually inspected for leaks.

The test method to measure the resistance of a protective material to
penetration by a bodily fluid-borne pathogen is performed by placing a glove
sample, partially filled with a sterile liquid, into a flask that contains a broth that
has been contaminated with a synthetic "Phage," or viral simulant. The cuff of
the glove is rolled over the outer edge of the flask and the glove is filled with
more uncontaminated liquid. The top of the flask is sealed with a paraffin film,
placed on an orbital shaker in a heated incubator, and shaken for 1 hour. At the
end of the hour, the flask is removed from the incubator and the paraffin film is
removed. Several samples of the liquid from inside the glove are placed onto
culture dishes, which are maintained in the incubator for a period of 6 to 18
hours. The cultures are analyzed to determine if any of the viral simulant
penetrated the glove material and contaminated the liquid in the glove. As this
test is a pass/fail criteria, any indication of viral penetration constitutes a failure.
Table 3 shows the results of the pathogen-resistance test.

Dexterity

Dexterity testing is based on the dexterity requirements of the British European
Standard BS EN 420: 1994, Section 5.2, General Requirements for Gloves. In
this test, a subject wearing the test glove attempts to pick up a series of pins
that have similar lengths but different diameters. The dexterity rating, which is
expressed as High, Moderate, or Low, is based on the smallest diameter pin
that can be picked up while wearing the glove. Table 4 shows the results of the
dexterity test.

Cut Resistance

The cut-resistance test measures the protection provided against slashes and/or
cuts by sharp objects such as razor blades or knives. The test is based on
ASTM F1790, Standard Test Method for Measuring Cut Resistance of
Materials Used in Protective Clothing. In this test, the glove material is mounted
on the metal mandrel of a cut tester. A special blade is moved across the
specimen until it cuts through the material. Different weights are used on the arm
holding the blade. The device measures the distance of blade travel before it
cuts through the material, which is determined by when the blade makes contact
with the mandrel. The fabric is rated as having High, Moderate, or Low cut
resistance based on the weight needed to cut through the fabric. Table 5 shows
results of the cut-resistance test.

Tear Resistance

The tear-resistance test is based on the British European Standard BS EN 388:
1994, Section 6.3, Protective Gloves Against Mechanical Risks. For this test, a
computer-controlled tensile tester is used to measure the force necessary to
tear a material specimen that has been taken from the glove. A 4-inch by 2-inch
sample is cut from the glove and a 2-inch incision is made in the longitudinal
(lengthwise) direction of the sample. The sample is mounted in the tensile tester,
which records the force values required to completely tear the sample in two.

The test is performed on four different specimens, each one cut from a different
glove. Two specimens are tested in the direction of the glove from cuff to finger
tips, and two specimens are tested across the palm width. The tear resistance
for each specimen is taken as the highest peak value recorded during the tests,
and the classification is determined by taking the lowest of the four values.
Based on these values, the tear resistance of the glove is rated as either High,
Moderate, or Low. If a glove is made from several different types of materials
that are not completely bonded together (e.g., a leather outershell with a
cut-resistant insert), the test is performed on each layer, and the classification is
based on the material that provides the highest level of cut resistance. Table 6
shows the results of the tear-resistance test.

For gloves that are entirely made of elastomeric materials (e.g., latex or plastic
film) or have a liner of these materials, the test for tear resistance is ASTM
D2582, Standard Test Method for Puncture-Propagation Tear Resistance of
Plastic Film and Thin Sheeting. This test method is designed to simulate material
snagging and subsequent tearing caused by contact with sharp objects, for
example, when a glove comes into contact with a protruding nail or hypodermic
syringe. In this method, a probe is dropped by a carriage onto the surface of
the test material that is held in a specimen holder at an angle to the probe. The
tear resistance is calculated from the weight of the carriage, the height of the
carriage before release, and the length of the resulting tear.

Four, 8-inch-long samples, each cut from a different glove, are individually
mounted in a test fixture and held in place by five clamps. A sharp-edged probe
is mounted onto a weighted drop mass, which falls along guide rails. This mass
is dropped so that the probe comes in contact with the sample, causing it to
tear. The weight of the mass is adjusted until the drops produce a tear that is 40
mm (1.57 inches) in length on the sample. The data is recorded for each
sample, and the results are expressed as the average of the tear resistance for
the direction tested. To determine the best score between gloves, the
combination of the highest drop mass (carriage) weight and the highest
resistance (lbf) determine which glove has the highest puncture-propagation
resistance. Table 7 shows the results of this test.

Puncture Resistance

The puncture-resistance test is based on ASTM F1342, Standard Test Method
for Protective Clothing Material Resistance to Puncture. The test method
determines the puncture resistance of protective clothing by measuring the force
required to cause a sharp-edged puncture probe to penetrate the material.

For this test, four specimens, each 4 inches square, are cut from separate
gloves. Each sample is mounted into a holder that measures 3.5 inches in
diameter, with three holes that are 1-inch apart at 60-degree angles, forming an
equilateral triangle on the sample. The holder is mounted into a
computer-controlled tensile tester and held in place with two bolts. A puncture
probe is mounted in the test machine. The test machine records the force
required to puncture the test sample at each of the three locations on the holder.
All 12 data points are averaged to determine the final score. This score is then
expressed in a rating scale as either High, Moderate, or Low puncture
resistance. Table 8 shows the results of this test.

Summary of Test Results

Under rating type A, or pathogen-resistant protective gloves, 14 models were
tested. All 14 models passed the pathogen-resistance test and all 14 rated High
for dexterity. The tear-resistance (puncture propagation) test results are listed in
table 7.

Ten models of type B, or cut-resistant gloves, were tested. Six models rated
High for dexterity, three rated Moderate, and one rated Low. The test for cut
resistance resulted in two High ratings, five Moderate, and three Low. Under
tear-resistance testing, seven models rated High in both transverse and
longitudinal tear testing, two models rated High in longitudinal testing and
Moderate in the transverse test, and one model rated Low in longitudinal testing
and Moderate in the transverse test.

One model of type C, or puncture-resistant gloves, was tested. It rated
Moderate for dexterity, High for puncture resistance, and High in both
longitudinal and transverse tear testing.

In the multiclass category, three models of gloves that claimed to protect against
type A, B, and C threats were tested. All three failed the test for pathogen
resistance because of infiltration through the stitching holes in the seams of the
gloves. Two models rated High for dexterity and one rated Moderate. For cut
resistance, one model rated High, one rated Moderate, and one rated Low.
Two models rated High for puncture resistance and one model rated Low.

Selecting Protective Gloves

Note: The information contained in this section was developed from various
sources, which are noted accordingly and include the University of Toronto
Protective Glove Standard (http://www.utoronto.ca/safety/glovestd.htm).

In its 1999 standard, the National Fire Protection Association (NFPA)
specified that emergency medical services (EMS) gloves must pass viral
penetration, rubber flexibility, puncture, and dexterity testing. For a glove to be
NFPA approved for EMS use, it must be flexible, fit well, have a degree of
puncture resistance, resist blood-borne pathogens, and allow enough dexterity
for fine manipulations required to perform medical tasks.

Protective gloves are designed to create a barrier against hazards. Using the
correct hand protection can significantly reduce or eliminate potential injuries.
Glove specification should be done after careful evaluation of potential hazards
and glove protection characteristics. Select a glove that is appropriate.
Consider factors associated with actual use that may affect the performance of
the glove. 

Because no single glove material will protect against all threats, it is important to
match the glove to the type of threat. No glove material is totally impermeable.
Glove performance can vary with product and manufacturer. The performance
characteristics of a particular glove and its ability to protect against specific
hazards are based on a number of factors including the glove material, its
design, its construction, and its thickness and size.

Appropriate glove protection must not only protect against the specific threat
likely to be encountered, it should provide a comfortable and secure fit that
does not interfere with the ability to carry out normal duties. Gloves must first
meet the basic criteria of providing good manual dexterity. 

The gloves themselves must not aggravate existing allergies or promote medical
complications such as latex allergy reactions. According to the National Institute
for Occupational Safety and Health (NIOSH), a program of the Centers for
Disease Control and Prevention, the increased use of latex gloves in and out of
the workplace has resulted in an increase in reported irritant and allergic
reactions to this material. According to the Occupational Safety and Health
Administration (OSHA), the Food and Drug Administration (FDA) has
received more than 1,000 reports of allergic reactions resulting from the use of
latex gloves. Reactions are either due to exposure to the natural latex proteins
or to chemicals added during the manufacturing process. As stated in NIOSH
Publication 97-135, Preventing Allergic Reactions to Natural Rubber Latex in
the Workplace (June 1997), studies indicate that 1 to 6 percent of the general
population and 8 to 12 percent of regularly exposed health care workers are
sensitized to latex. Allergic reactions to latex proteins can be a serious health
risk with symptoms ranging from local skin irritation to more serious effects
such as asthma, and, very rarely, anaphylactic shock. For more information on
latex glove allergies and prevention measures, please refer to the following
websites:

NIOSH: http://www.cdc.gov/niosh/latexalt.html
http://www.cdc.gov/niosh/98-113.html

OSHA: http://www.osha-slc.gov/SLTC/latexallergy/index.html

FDA: http://www.fda.gov/medbull/natural.html
http://www.fda.gov/cdrh/glvpwd.html

Protective gloves are a supplementary form of protection and should not be
used as a substitute for good work practices. Understand the limitations of
protective gloves and exercise proper care and maintenance. It is risky to wear
gloves that have not been tested for viral penetration resistance when there is a
chance of contact with blood or other bodily fluids, or materials containing
biological hazards. It is also important to periodically replace unused supplies of
latex gloves, as studies have demonstrated that age degradation increases the
probability that these gloves may fail, as the tensile strength and elongation
properties of these types of gloves decrease from aging. (See Environmental
Degradation of Latex Gloves, The Effects of Elevated Temperatures on Tensile
Strength, DMMS Report #96-05, by D.L. Walsh, D.J. Chwirut, R Kotz, and
J. Dawson, published by the Food and Drug Administration, Rockville,
Maryland.) Gloves made from synthetics, such as nitrile, do not experience the
same degradation over time as latex gloves.

Inspection and care of protective gloves should be conducted routinely. Follow
the manufacturer's instructions for the care and maintenance of protective
gloves. Generally, reusable gloves should be thoroughly washed and rinsed
according to the manufacturer's care instructions and allowed to air dry. Gloves
should be replaced on a regular and frequent basis. Disposable gloves should
be replaced frequently and never reused.



Developing the Test Protocol

As part of the development of the test protocol, NLECTC reviewed the major
requirements for protective gloves and prepared a survey for the law
enforcement and corrections community to help validate and prioritize the
requirements (see sidebar). Based on survey results, protection from
pathogens, cut resistance, puncture resistance, tactility, dexterity, and
affordability emerged as the primary criteria for the evaluation and comparison
of protective gloves. The leading companies in the protective garment materials
industry were also consulted to determine the state of the art in protective glove
technology.

At the same time, OLES reviewed existing industry standards and test methods
that could be adopted for testing protective gloves and that would be applicable
to the needs of the criminal justice community. OLES assembled various
standards, procedures, and test methods from the following sources for the
protective glove protocol: The Code of Federal Regulations, the American
National Standards Institute/American Society for Quality Control, the National
Fire Protection Association, the American Society for Testing and Materials,
and British/European Standards.

Initially, OLES planned to develop an official NIJ protective glove standard
from this compendium of standards, but the standard development team was
concerned that the existing standards for cut and puncture resistance would not
represent the real-world threat facing law enforcement and corrections in a
meaningful manner. The team determined that it would be better to provide a
set of standard test protocols that would enable the user community to compare
the performance of protective gloves based on the test data provided. NIJ Test
Protocol 99-114, Test Protocol for Comparative Evaluation of Protective
Gloves for Law Enforcement and Corrections Applications, published in June
1999, is the first step in an ongoing process by NIJ, OLES, and NLECTC to
evaluate the state of the art in protective glove technology. This bulletin
summarizes the results of the initial round of tests. As more tests are performed
and more data collected, the test protocol will be further refined and become
the basis for an NIJ standard.

Participating Glove Manufacturers

AdTex, AS
(formerly known as International Security Protection, AS)
Schwensens Gate 5

0170 Oslo, NORWAY
Phone: (+47) 90 61 24 14
Fax: (+47) 90 42 26 42

Dakota Corporation
(Damascus Gloves/Slashguard/Dave Larken)
P.O. Box 543
Rutland, VT 05702-0543
Phone: 800-451-4167
Fax: 877-326-2728
http://www.damgloves.com

Gimbel Glove Company, LLC
7720 North 16th Street 
Suite 370
Phoenix, AZ 85020 
Phone: 888-667-8425
Fax: 602-944-7934 
http://www.gimbelglove.com

HIGH FIVE Products, Inc.
319 W. Ontario
Chicago, IL 60610 
Phone: 888-253-9292
Fax: 312-266-9171
http://www.highfivegloves.com

Microflex
P.O. Box 32000
Reno, NV 89533-2000
Phone: 800-876-6866
775-746-6600
Fax: 775-746-6577
http://www.microflex.com

Safeskin Corporation
(Kimberly Clark Scientific & Industrial)
12777 High Bluff Drive
San Diego, CA 92130
Phone: 800-462-9993
http://www.safeskin.com



Samco Co.
122 South Main Street
Gloversville, NY 12078
Phone: 518-725-4705

Speith & Weinsky
(Distributed by Masley Enterprises, Inc.)
222 Waverly Road
Wilmington, DE 19803
Phone/Fax: 302-427-9885

Warwick Mills (Turtleskin Gloves)
P.O. Box 409
301 Turnpike Road
New Ipswich, NJ 03071
Phone: 888-477-4675
http://www.turtleskin.com

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Law Enforcement and Corrections Requirements for Protective Glove Survey

NLECTC developed a survey to rank law enforcement and corrections
communities' top requirements and priorities for protective gloves. Survey
respondents were asked to rate 15 criteria in order of importance.

The criteria included protective qualities, use qualities, and other practical
considerations in choosing protective gloves. Protective criteria considered
were pathogenic protection, chemical protection, electrical insulation, tear
resistance, cut resistance, and puncture resistance. Use criteria included
dexterity or ease in hand and finger manipulation; tactility or the quality of touch
and feel when using a handgun or writing; holding capacity or ease in grasping
objects; and human factors such as comfort, insulation, and moisture vapor
transmission. Other criteria considered were inservice care, durability, test
costs, unit costs, and availability.

The survey also asked respondents to comment on the practicality of carrying
more than one set of gloves, such as disposable gloves for pathogen protection
and a reusable set for cut and/or puncture resistance, given that the
development of protective gloves that protect against all possible threats may
not be practical or cost effective.



The priority, according to 70 percent of the survey responses, was pathogenic
protection, followed by puncture resistance, dexterity, tear resistance, cut
resistance, tactility, and holding capability. The survey respondents came from
law enforcement, corrections, forensics, and other agencies. Responses were
fairly evenly distributed from those who worked in agencies that were small,
under 25; intermediate, 25 to 100; and medium, 101 to 500, with 11 percent of
responses coming from large agencies of 501 or more. The responses came
predominantly from supervisors, followed by line staff, administrators, support
staff, and various other positions.

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The National Law Enforcement and Corrections Technology Center is
supported by Cooperative Agreement #96-MU-MU-K011 awarded by the
U.S. Department of Justice, National Institute of Justice. Analyses of test results
do not represent product approval or endorsement by the National Institute of
Justice, U.S. Department of Justice; or Aspen Systems Corporation 

The National Institute of Justice is a component of the Office of Justice
Programs, which also includes the Bureau of Justice Assistance, Bureau of
Justice Statistics, Office of Juvenile Justice and Delinquency Prevention, and
Office for Victims of Crime.

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New Publications/Videos

The following publications/videos are available from the National Law
Enforcement and Corrections Technology Center-National:

Selection and Application Guide to Personal Body Armor, NIJ Guide 100-01.
This guide responds to questions about the selection and use of body armor for
law enforcement. It responds to commonly expressed concerns and provides
information to help determine the level of protection required by officers. This
guide provides information on the newly released 0101.04 ballistic-resistant
standard and the new stab-resistant standard (NIJ Standard-0115.00).

Surviving a Shooting: Your Guide to Personal Body Armor. This 19-minute
videotape provides a synopsis of the National Institute of Justice (NIJ)
publication titled Selection and Application Guide to Personal Body Armor.
Covered in the videotape are what body armor is, what it can and cannot
protect against, how to select it, and how to wear and care for it. 



National Law Enforcement and Corrections Technology Center Publications
Catalog 2002. This document provides a listing of NLECTC and other
government publications of interest to law enforcement, corrections, and
forensic sciences practitioners. Categories include communications, forensics,
less-than-lethal weapons, protective equipment, and weapons and ammunition.

Michigan State Police Tests 2002 Police Vehicles. This bulletin summarizes test
results from the Michigan State Police's annual evaluation of police-package
and special-service patrol vehicles.

A Comprehensive Evaluation of 2001 Patrol Vehicle Tires. This bulletin
summarizes results of NIJ's latest comprehensive evaluation of patrol vehicle
tires.

A Guide for Applying Information Technology in Law Enforcement. This
publication seeks to help law enforcement professionals choose the information
technologies that best suit their needs and incorporate them into their
day-to-day operations. This guide is intended to help law enforcement
practitioners plan and implement information system upgrades and address
connectivity and data sharing issues.

2001 Mock Prison Riot Videotape. This video features technologies used to
quell a mock prison riot staged by NIJ's Office of Law Enforcement
Technology Commercialization. Emerging technologies were incorporated into
training scenarios to demonstrate the latest technologies.

To obtain any of the above publications or videotapes, write NLECTC, P.O.
Box 1160, Rockville, MD 20849-1160; telephone 800-248-2742.
Publications can also be downloaded from JUSTNET at www.justnet.org.