Bis-Diglyceryl Polyacyl- Adipate-2 ●
TL;DR. This ingredient is an oil-phase emollient and film-forming binder that adds cushion, gloss, adhesion, and water resistance. It is often used in lip products, balms, creams, and color cosmetics to improve pigment wetting and give a lanolin-like feel.
What does Bis-Diglyceryl Polyacyl- Adipate-2 do in a cosmetic formula?
This ingredient is an oil-phase emollient and film-forming binder that adds cushion, gloss, adhesion, and water resistance. It is often used in lip products, balms, creams, and color cosmetics to improve pigment wetting and give a lanolin-like feel.
Is Bis-Diglyceryl Polyacyl- Adipate-2 clean?
This ingredient is generally well tolerated and is not a common clean-standard restricted-list target. The main clean-beauty caveat is that it is a highly processed ester, so stricter natural frameworks may ask for detailed sourcing and manufacturing documentation.
Is Bis-Diglyceryl Polyacyl- Adipate-2 sustainable?
This material can use fatty components from plant or animal-derived supply chains, with plant-based grades common, so sourcing verification matters. It is expected to break down more readily than persistent silicone fluids, but its high molecular weight and mixed feedstocks make it less straightforward than simple plant oils.
Is Bis-Diglyceryl Polyacyl- Adipate-2 COSMOS-approved?
This ingredient is not an automatic fit for COSMOS-organic or COSMOS-natural, and acceptance depends on whether the supplier documents permitted feedstocks and an allowed esterification route. From a Green Chemistry view, it scores better when renewable fatty inputs are used, but it is still a chemically modified, multi-step ester.
How does Bis-Diglyceryl Polyacyl- Adipate-2 work chemically?
The molecule is a high-molecular-weight polyol polyester built from fatty-acid chains and a diacid linker, which gives it a viscous, tacky, oil-soluble profile. Typical use is about 1 to 10% in emulsions and higher in anhydrous lip or color products, and it is most stable in oil phases or moderate pH systems while strong acid or alkaline conditions can promote ester hydrolysis.
Last updated 2026-05-16