Salomon Women's Wings Flyte 2 Trail Running Shoes, Synthetic/Textile, Red (Beet Red/Cabernet/Black), Size: 39 1/3

Salomon wings flyte 2 trail wings flyte 2 are designed for comfortable yet precise foothold, stability & protection for the most technical running trails. Weather working up a long climb or charging down a technical descent, wings flyte 2 gives runners more confidence. Upper - stability & comfort combined. Enveloping the foot with support & comfort, the wings flyte 2 trail employs varying technologies to offer the best fit possible. A 3d open mesh makes up the underlayer which provides maximum breathability, letting fresh air permeate the interior to keep the foot cool & refreshed. Externally it features sensifit technology - a system that wraps to the foot with a precise & secure fit, sensifit cradles the foot from the midsole to the lace system, providing a stable, precise, snug fit all around the system. Moulded into the shoe, reducing weight & brings more comfort. One of the final components to the upper is the simple & user friendly quick lace system. Quicklace is a single kevlar string fed through friction free eyelets. As you pull, the lace closes evenly for a better fit, which delivers precision adjustment & a secure lock down, with a lace pocket to neatly stash away any excess that may get in your way. Trail running can compromise the integrity of the shoe hense why the wing flyte 2 is embedded with synthetic toe cap, forefoot mudguard & a tongue cover which all actively fights against debris from entering & protects the feet through sharp rocks & root out on the trail, without adding weight. It also helps maintain the shoes shape & form. Midsole - quick & cushioned compound. Offering supportive comfort whilst retaining a lightweight embodiment the midsole utilises salomon's proprietary lightweight, injected eva. The foam prevents medial collapse & offers smooth cushioning & gait cycle transitioning. The Format Assists With Keeping Weight Down & Maximising Responsive Underfoot Cushioning By Actively Reducing Forc