Ozone / Ozonized Ethyl Linolenate

TL;DR. This ingredient is mainly used as a skin-conditioning and deodorizing functional additive, especially in products aimed at blemish-prone skin, scalp care, or freshness claims. Its role comes from a reactive, oxygenated lipid profile rather than classic moisturizing lipid behavior.

What does Ozone / Ozonized Ethyl Linolenate do in a cosmetic formula?

This ingredient is mainly used as a skin-conditioning and deodorizing functional additive, especially in products aimed at blemish-prone skin, scalp care, or freshness claims. Its role comes from a reactive, oxygenated lipid profile rather than classic moisturizing lipid behavior.

Is Ozone / Ozonized Ethyl Linolenate clean?

It sits in yellow territory because the same reactive peroxide character that defines its performance can also raise stinging or sensitization potential, especially on compromised skin. Clean standards may treat it cautiously because quality depends on tight control of residual oxidants and degradation products.

Is Ozone / Ozonized Ethyl Linolenate sustainable?

This material is usually made from a fatty-acid ethyl ester that can come from vegetable oil, then reacted with a strong oxidant generated from oxygen. The ester backbone should be more biodegradable than persistent synthetic film-formers, but energy use, crop sourcing, and reactive residual control are relevant caveats.

Is Ozone / Ozonized Ethyl Linolenate COSMOS-approved?

This ingredient may fit COSMOS as a chemically processed agro-ingredient only when its fatty-ester feedstock and processing route meet the standard’s input and processing rules, so it is not an automatic COSMOS-organic match. From a Green Chemistry view, renewable feedstocks and eventual ester biodegradation are positives, while oxidant generation and a peroxide-rich composition make it less straightforward than simple plant lipids.

How does Ozone / Ozonized Ethyl Linolenate work chemically?

This material starts as an ethyl ester of an 18-carbon triunsaturated fatty acid, then controlled oxidation converts some double-bond sites into oxygenated, peroxide-containing species rather than one single discrete molecule. It is oil-soluble, best handled with cool processing and limited metal exposure, and is sensitive to heat, reducing agents, metals, and strong bases, so opaque packaging and chelation are common formulation considerations.

Last updated 2026-05-14