Wilson Rush Pro 4.5 Clay Red White Sneakers
Harness your power on the court with the Rush Pro 4.5, our No. 1 franchise designed to offer rock-solid stability, support and abrasion resistance.
REF: WRS333670 EAN: 097512804714
Continuing the evolution of our best-selling franchise, the Rush Pro 4.5 builds on the innovations of the 4.0 with new updates that improve breathability, support and abrasion resistance.
The engineered mesh upper features a graduated pattern, with a mesh of larger holes towards the front to promote airflow and a tighter mesh towards the heel to provide support.
The larger, integrated medial splash guard provides protection and support all around.
In addition, the enlarged rubber drag pad on the side is extra thick to resist abrasion and is anatomically shaped to follow the profile of the foot.
The EVA Lightweight Energy Cell foam under the forefoot provides cushioning at impact and then responds to help you regain position.
Sleek, durable, and with multi-directional support, this Rush Pro 4.5 maximizes the level of your game, especially on clay courts.
The split chassis extends the chassis under the skin for better support and directed propulsion.
The side piece is located from heel to toe for maximum stability and control through dynamic movement.
Minimal layer upper with a mesh design to improve breathability, feel, comfort and a consistent fit.
Fully interior sock design that provides better comfort, stability and an intuitive fit.
The rubber overlay in the medial area provides additional durability and protection when dragging the foot.
High-density OrthoLite foam offers maximum cushioning and impressive longevity.
The heel-to-toe drop (9 mm) provides the best compromise between comfort and performance.
Highly resistant high density that offers abrasion resistance and maximum traction on all surfaces.
Foam in the midsole that offers the best combination of cushioning and rebound for dynamic performance.
Lightweight EVA foam in the forefoot of the midsole offers a softer feel for optimal transfer of body weight at impact, creating more explosive acceleration.