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It is actualy used more to make tool production cheaper (Such as cheaper, longer lasting molds, and faster production).
From a production point of view, I cannot see why an extra step to remove the slick layer shouldn't be added. it would be simply one additional step, if at all. A simple solutioin would be to use a mold lubricant that degraded quickly when exposed to oxigen in the air, or uv from sun light.
This is the kind of thing that Tire producers would probably like to know about as a complaint. Both producers looking for an edge over their compeditors, as well as industry regulators need to know that this is a problem.
Mold life won't change by a perceptible amount from the use of mold-release agents. The release agent allows the tire, and its attached vents, to not stick to the mold.
As I wrote earlier, there would be more than a single step. To be more specific, the tire would need to be washed. To be more effective, the washing should penetrate between the tread blocks. This would require some combination of high pressure hot water and rapidly spinning brushes. Keeping water out of the inside of the tire would be necessary, so that drying the inside of the tire could be avoided. This would likely involve mounting the tire on temporary chucks and inflating it (can be done in about 5 seconds). Selecting the chucks for different tires would require a sorting step, and probably moving pallets of tires. After washing, the tire would need to be dried, probably by hot air blown at high speed, something like the driers in automated car washes. The dirty water then needs to be pumped to the factory's waste treatment plant.
Some of the mold release (usually some sort of greasy soap) is probably incorporated into the outer few thousandths of an inch of the tread rubber. To remove that, the tire would need to be buffed. The tire would first be remounted amd inflated on the temporary chucks. Buffing could be manual, using cloth wheels attached to flexible drives. That system would be prone to non-uniformity, gouging the tire at some spots, and missing others. So it would be better to have a series of buffing wheels that would press against the tire while the tire was itself rotated. This would require another sorting step, as each tire would require buffing machine settings to match its profile.
Buffing generates dust, which would have to be controlled, and probably would be done in a booth from which air would be filtered.
Tire treads have marking codes on them, both colored lines and combinations of letter and numbers. The codes are applied as the tread is extruded. Codes tell the factories which tire the tread goes on, what mold an assembled tire goes in, how the tire is to be inspected and balanced, and how it will be handled in warehouses after it leaves the factory. Buffing would likely remove this marking, so another marking codes would need to be applied after buffing.
Not everything can be designed to degrade by exposure to light, and I strongly suspect that mold release agents are among those things.
So, I believe that it is worth the few minutes needed to scrub a new tire with water and a brush, or to ride the bike to a car wash and hit the tires with hot water. Then ride slower, at lower lean angles for a hundred miles.