Introduction

Redwood (Sequoia sempervirens) and cedar (Cedrus spp.) trees are reservoirs of bioactive compounds—polyphenols, terpenoids, and essential oils—with significant pharmaceutical potential. Encapsulating these botanical extracts into microparticles can enhance stability, control release, and target delivery, opening avenues for antimicrobial, antioxidant, anti-inflammatory, and anticancer therapies.

Key Phytochemicals

• Cedar essential oils

  • α-himachalene, β-himachalene, γ-himachalene

  • Cedrol and thujopsene

  • Known for antimicrobial, anti-inflammatory, insect-repellent activities

• Redwood heartwood and bark

  • Proanthocyanidins and taxifolin (antioxidant, vascular-protective)

  • Tannins with astringent and potential antitumor effects

  • Cellulose and lignin fractions for biocompatible carrier matrices

Extraction and Isolation

1. Steam distillation for cedar oils, retaining volatile terpenoids

2. Supercritical CO₂ extraction of redwood polyphenols, maximizing yield and purity

3. Solvent partitioning (methanol, ethanol) to fractionate polar and nonpolar constituents

4. Ultrafiltration and chromatography to isolate high-value flavonoids

Microparticle Formulation Techniques

• Spray‐drying • Rapid drying of emulsions containing extract and carrier (maltodextrin, gum arabic) • Produces spherical particles, 1–20 µm

• Emulsion‐Solvent Evaporation • Oil-in-water or water-in-oil emulsions with biodegradable polymers (PLGA, chitosan) • Yields tunable release profiles

• Coaxial Electrospray • Core–shell microparticles encapsulating cedar oil core with polymer shell • Enables precise control of diameter (100 nm–5 µm)

• Supercritical Anti-Solvent (SAS) • Uses CO₂ to precipitate compounds into microparticles without heat degradation • Ideal for thermolabile redwood polyphenols

Physicochemical Characterization

• Particle size and distribution via laser diffraction and dynamic light scattering

• Morphology using scanning electron microscopy (SEM)

• Encapsulation efficiency and loading capacity by HPLC quantification

• Surface charge (zeta potential) for colloidal stability

• In vitro release kinetics in simulated biological fluids

Pharmacological Applications

• Antimicrobial wound dressings • Cedar-oil microparticles embedded in hydrogel dressings • Sustained release combats bacterial biofilms

• Antioxidant nutraceuticals • Redwood polyphenol microparticles in oral tablets • Protects endothelial cells from oxidative stress

• Anti-inflammatory topicals • Chitosan-coated cedar oil microspheres in creams • Reduces cytokine release in keratinocyte cultures

• Anticancer delivery systems • Taxifolin-loaded PLGA microspheres for controlled doxorubicin co-delivery • Enhanced cytotoxicity in breast and colon cancer cell lines

In Vitro and In Vivo Studies

• In vitro assays demonstrate MIC reductions against MRSA and Candida spp.

• Antioxidant capacity (DPPH, ABTS assays) correlates with microparticle release profiles

• Rodent wound-healing models show accelerated closure and reduced inflammation

• Xenograft tumor models reveal improved survival and reduced off-target toxicity

Safety, Toxicity, and Regulatory Considerations

• Cytotoxicity screening in human dermal fibroblasts and hepatocytes

• Hemolysis assays ensure red blood cell compatibility

• Maximum tolerated dose studies in rodents inform first-in-human estimates

• GRAS status for carriers (maltodextrin, gum arabic) accelerates regulatory approval

Challenges and Future Directions

• Scaling up extraction and microparticle production while maintaining batch consistency

• Integrating redwood and cedar waste streams into circular bioeconomy models

• Exploring targeted delivery via surface-modified microparticles (antibodies, peptides)

• Clinical trials to validate efficacy in chronic wound management, cardiovascular protection, and cancer therapy

• Combining botanical microparticles with synthetic drugs for synergistic formulations

Harnessing the unique chemistries of redwood and cedar through innovative microparticle technologies offers a promising frontier in pharmaceutical development. By addressing formulation challenges and rigorously validating bioactivity, these natural resources can be transformed into next-generation therapeutics for global health.