The GT-2000™ 10 GS shoe creates a smooth ride and a supportive fit. Borrowing inspiration from our performance running collection, this shoe is reimagined for energised minds that are always in motion.
The shoe features a removable sockliner with an ASICS FIT CHECKER™ print on the toe which helps kids and parents recognize the right shoe from the left. Additionally, this liner helps them identify when they're outgrowing their shoes.
LITETRUSS™ technology creates a more supportive stride. Its foam material is designed to keep feet feeling balanced in every step. While GEL™ technology provides extra cushioning and increased shock absorption for young runners.
Engineered Mesh
A technical mesh material that stretches in multiple directions, creating a glove, snug like fit that provides a unique balance of comfort and fit.
Flytefoam Propel
Combining a lightweight foam formulation with a high-energy return elastomer for increased bounce and unrivaled toe-off to give you a better performance out of every stride.
Flytefoam Propel Top Layer
Combining a lightweight foam formulation with a high-energy return elastomer for increased bounce and unrivaled toe-off to give you a better performance out of every stride. Located closer to the foot to give that added comfort level.
Gel - Forefoot Twist
Shock absorbing material placed in forefoot of shoe. Shape of units designed for special function under the ball of the foot.
Gel - Visible Rearfoot
Reduces impact during heel strike and allows for a smooth transititon. Shape of units designed for special function under the outside (laterial) side of the foot.
Internal Heel Counter
The internal plastic structure of the shoe which wraps around the heel of your foot. It holds the heel in position during the movements of running improving support.
3D Space Construction
This technology is implemented through a series of strategically planted pillars within the midsole, allowing runners to experience more compression in a specific area without reducing durability or stability. These pillar formations are tuned differently in the men's and women's models to address each gender's biomechanical data