On their own, leather gloves can offer up to ANSI level 3 puncture resistance. To achieve higher level of puncture resistance, puncture-resistant liners made with densely knit high-strength fibers like HPPE or para-aramids are sewn to increase puncture resistance to ANSI Level 4 or 5.

Mechanics gloves are different layers of materials (natural or synthetic) sewn together to manufacture gloves. And as with leather gloves, a puncture-resistant liner is sewn into the mechanics gloves to achieve higher levels of puncture protection.

Primary materials used to manufacture puncture-resistant gloves include high HPPE and Para-aramids. Glove gauge and palm coatings also significantly impact puncture protection.

Glove gauge: Higher-gauge (thinner) gloves offer better puncture protection as the yarn is knit tighter together with smaller gaps for pointy objects to penetrate through. Lower-gauge (thicker) gloves are unable to suitably protect from puncture hazards as pointy objects can easily find their way into the larger gaps between the fibers and penetrate the gloves.

Palm coating: In string knit gloves, a very thin layer of palm coating is applied. This coating acts as an additional layer of protection that holds the yarn together to prevent the fibers from moving apart and adds puncture resistance to areas where there are gaps between the yarn.

To learn more about the differences between glove gauges, as it relates to glove performance and comfort, check out our Glove 101 guide that discusses the topic in detail.

Chemical gloves offer only mid-range puncture resistance (ANSI Level 2 – 3) and are usually accompanied by other liners and inserts to achieve higher protection levels (Note: due to manufacturing constraints, adding liners to chemical gloves is quite uncommon).

Latex and silicone offer the best puncture resistance as these materials have a slight stretch to them. When it comes to the rest, there is no one strong performer than the other.

For more information on the features and limitations of each type of glove coating material and the work conditions they’re best suited for, check out our Glove 101 section on palm coating.

An emerging technology is densely knit, puncture-resistant metal mesh gloves. Metal mesh gloves a quite ergonomic as they can move independently and bend easily. However, the challenge with these gloves is that unless they are of a higher gauge (21-gauge), pointy objects can easily find their way through the gaps in the mesh to cause puncture injuries.

Industry standards were established that refer to specific test methods to assign protection levels for safety gloves, including standard puncture testing (classified as blunt puncture testing in the industry testing standard guide). These standards were introduced to create a common language for safety managers, distributors, and manufacturers to define protection levels and be held accountable for their claims.

The EN388 standard testing method for puncture resistance is the only testing procedure that is used and recognized by both EN388 and ANSI/ISEA 105 standards. The test measures the amount of force required for a blunt object to break through the glove material.

Note: The industry testing standards require only the palm side to be tested for puncture resistance.

Testing Method: The testing material is held firmly between two plates and a blunt object (roughly the size of a ballpoint pen, ~ 4.5mm in diameter) is pressed into the material. The object penetrates the test fabric at a 90° angle at 100mm/min. Increasing weights are then added to determine the puncture level of the glove material. For ANSI/ISEA testing, this test is usually performed a total of 12 times on the material, and the average is recorded to determine the final rating.

• The ANSI standard identifies puncture levels on a scale of 0-5 (where 0 is the lowest and 5 is the highest level of puncture resistance)

The EN388:2016 standard identifies puncture levels on a scale of 0-4 (where 1 is the lowest and 4 is the highest level of puncture resistance)

When looking for the protection level on gloves, the ANSI puncture level for standard puncture protection is displayed inside a badge resembling a shield.

And the EN388 puncture level is displayed under the EN388 shield.

There is no such thing as 100% puncture-proof gloves—as it is true of all safety gloves that offer any mechanical protection. This is why safety gloves are called “resistant” and not “proof.”

Puncture-resistant gloves are designed to reduce the likelihood of getting puncture injuries, though injuries can still occur even when wearing gloves if enough force is applied. In such cases, the severity of the injury can be drastically reduced by wearing these gloves.

Most puncture-resistant gloves only offer protection on the palm side of the gloves, and industry standards dictate that only the palms need to be tested for puncture resistance. This is because the palms are the most commonly injured part of the hand by puncture wounds. However, many assume that if the palms are protected, so is the back of the hand. While at Superior Glove we do offer gloves with full 360° hand coverage for cut resistance that can offer a degree of puncture protection, it does not automatically mean the gloves are rated at the same level for puncture resistance. However, zoned protection for puncture resistance in other parts of the gloves can also be added and should be made clear by the manufacturer.

Most puncture-resistant gloves incorporate cut-resistant material but cut-resistant material in gloves may not guarantee sufficient protection from puncture hazards. Always determine the type of puncture protection your workers need (standard or hypodermic) and then review the hazard protection ratings for the gloves you are considering.

Look for these rating icons when your workers need protection from standard punctures like nails, thick cable, wood splinters, and wires, etc.

No matter how light and supple, hypodermic puncture-resistant inserts reduce glove dexterity. This is experienced differently for each type of material. In sting knit gloves, this reduced dexterity is felt more than in leather or mechanics style gloves. This is mostly due to the relative expectation the wearer has from string knit gloves in terms of better dexterity.

Industry standards were established that refer to specific test methods to assign protection levels for safety gloves, including hypodermic puncture testing (classified as needlestick puncture testing in the industry testing standard guide). These standards were introduced to create a common language for safety managers, distributors, and manufacturers to define protection levels and be held accountable for their claims.

Note: The industry testing standards require only the palm side to be tested for puncture resistance.

The ASTM F2878 needle puncture testing modifies the standard puncture test by swapping out the blunt object to a 25-gauge hypodermic needle and the speed at which it travels. During testing, the needle penetrates the test fabric at a velocity of 500mm/min, five times faster than in the standard testing method, and is usually performed a total of 12 times on the material to determine the final rating. The ANSI standard identifies needlestick puncture resistance on a scale of 0-5, based on the newtons of force required to fully penetrate the material.

When looking for the hypodermic protection level on gloves, the ANSI level is displayed inside a badge resembling a shield.

There is no such thing as 100% puncture-proof gloves—as it is true of all safety gloves that offer any mechanical protection. This is why safety gloves are called “resistant” and not “proof.”

Puncture-resistant gloves are designed to reduce the likelihood of getting puncture injuries, though injuries can still occur even when wearing gloves if enough force is applied. In such cases, the severity of the injury can be drastically reduced by wearing these gloves.

Most puncture-resistant gloves only offer protection on the palm side of the gloves, and industry standards dictate that only the palms need to be tested for puncture resistance. This is because the palms are the most commonly injured part of the hand by puncture wounds. However, many assume that if the palms are protected, so is the back of the hand. While at Superior Glove we do offer gloves with full 360° hand coverage for cut resistance that can offer a degree of puncture protection, it does not automatically mean the gloves are rated at the same level for puncture resistance. However, zoned protection for puncture resistance in other parts of the gloves can also be added and should be made clear by the manufacturer.

Most puncture-resistant gloves incorporate cut-resistant material but cut-resistant material in gloves may not guarantee sufficient protection from puncture hazards. Always determine the type of puncture protection your workers need (standard or hypodermic) and then review the hazard protection ratings for the gloves you are considering.