Home The Active Ingredient Matrix Melissa officinalis (Rosmarinic Acid)

Formulation Intelligence

Melissa officinalis (Rosmarinic Acid)

Accelerate your CDMO or DTC pipeline. Map the exact physiochemical constraints, bioavailability synergies, and optimal delivery mechanisms for Melissa officinalis (Rosmarinic Acid).

Melissa officinalis functions as a potent inhibitor of GABA-transaminase and a modulator of muscarinic and nicotinic acetylcholine receptors, providing targeted anxiolytic and cognitive-enhancing effects through the preservation of neurotransmitter concentrations.

Verified Molecular Profiling (NIH PubChem)

PubChem CID

5281792

Molecular Weight

360.3 g/mol

XLogP3 (Lipophilicity)

2.4

IUPAC Name

(2R)-3-(3,4-dihydroxyphenyl)-2-[(E)-3-(3,4-dihydroxyphenyl)prop-2-enoyl]oxypropanoic acid

Pharmacokinetic Synergies & Enhancers

Proven Synergy Pairings

  • Valeriana officinalis for synergistic GABAergic potentiation and improved sleep architecture
  • L-Theanine for enhanced alpha-wave brain activity and attenuation of cortisol-induced stress responses

Biological Formulation Enhancers

  • Piperine for the inhibition of UDP-glucuronosyltransferase to extend the metabolic half-life of rosmarinic acid
  • Phosphatidylcholine for the formation of phytosome complexes to improve the intestinal permeability of polyphenolic constituents

Delivery System Constraints & Modeling

Every active compound behaves uniquely based on the physical matrix it is suspended in. Below are the known physical chemistry challenges for Melissa officinalis (Rosmarinic Acid) across standard consumer modalities.

💊 Standard Capsules

The hygroscopic nature of concentrated Melissa extracts necessitates the use of desiccants or moisture-barrier HPMC shells to prevent powder caking and oxidative degradation.

🍬 Gummy & Pectin Formats

The high phenolic load and inherent astringency of the extract require advanced flavor-masking agents and can potentially disrupt the cross-linking stability of pectin-based matrices.

🔬 Thin-Film Oral Strips

The relatively high therapeutic dosage required for clinical efficacy typically exceeds the limited 30mg payload capacity of standard pullulan or HPMC thin-film architectures.

For Brand Founders

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Ready to launch a product featuring Melissa officinalis (Rosmarinic Acid)? Skip months of expensive wet-lab iterations. Generate a manufacturer-ready formulation in hours, instantly screened for physical incompatibilities and global regulatory compliance.

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Efficacy Evidence

Maximize Melissa officinalis (Rosmarinic Acid) Bioavailability

Need absolute proof that your Melissa officinalis (Rosmarinic Acid) extract actually absorbs? Stop blindly combining generic powders. Run a physics-based PBPK simulation to mathematically engineer peak clinical efficacy and targeted plasma concentrations.

Simulate Bioavailability

For R&D Labs & CDMOs

Melissa officinalis (Rosmarinic Acid) Degradation Testing

Is your Melissa officinalis (Rosmarinic Acid) payload degrading in the capsule before the expiration date? Stop waiting for costly bench testing. Run an accelerated digital twin to precisely model oxidation pathways and pH shifts before finalizing a manufacturing run.

Model Active Degradation