Matcha Bioavailability — Whole Leaf vs. Steeped Tea
Matcha delivers polyphenols at 2–3× higher bioavailability than equivalent steeped green tea because the whole leaf is ingested rather than discarded. Gut microbiome composition determines whether EGCG is converted to more-bioavailable metabolites, causing large individual variation.
| Measure | Value | Unit | Notes |
|---|---|---|---|
| EGCG bioavailability increase: matcha vs. steeped | 2–3× | Henning et al. 2018; plasma EGCG AUC significantly higher with matcha | |
| Peak plasma EGCG after 2g matcha (fasted) | ~0.1–0.3 | μM | Large individual variation; typically peaks at 1–2 hours post-consumption |
| EGCG absorption rate from matcha | ~30–60 | % of ingested dose | Rest degraded by gut bacteria or excreted; high interindividual variation |
| Effect of milk on EGCG bioavailability | −25 to −35 | % | Casein binds EGCG; reduces absorption; oat milk has less effect than dairy |
| Effect of food matrix (with meal) on bioavailability | Variable; generally reduced | Fasted consumption typically higher absorption than with food | |
| Individual variation in EGCG absorption | 5–10× | Between individuals; gut microbiome composition is primary driver |
The health benefits of matcha depend not just on its polyphenol content but on how much of those polyphenols actually reaches systemic circulation. Bioavailability — the fraction of an ingested compound that enters the bloodstream and is available for biological activity — is the critical link between chemical composition and health effect.
Matcha vs. Steeped Tea: The Whole-Leaf Advantage
The foundational difference is simple: steeped tea leaves ~50–70% of catechins in the discarded leaf. Matcha suspension ingests 100% of the leaf’s polyphenols. The Henning et al. (2018) study directly compared matcha and steeped green tea at equivalent catechin doses and found that matcha produced significantly higher plasma EGCG concentrations (area under the curve, or AUC) — approximately 2–3× higher.
This advantage applies to all polyphenol classes present in the leaf, not just catechins.
The Gastrointestinal Journey
After ingestion:
- Stomach (acidic): EGCG is relatively stable in acidic conditions; pH helps preserve the intact catechin structure
- Small intestine: Primary absorption site; EGCG passes through intestinal epithelial cells via passive diffusion and active transport
- Liver (first-pass): EGCG undergoes conjugation and methylation; conjugated metabolites enter circulation
- Large intestine (colon): Catechins that weren’t absorbed in the small intestine reach gut bacteria, which convert them to various metabolites (ring-fission products, phenolic acids) that are absorbed and may have independent biological activity
The Microbiome Factor
The conversion of EGCG and other catechins to bioactive gut metabolites depends heavily on individual gut microbiome composition. People with specific bacteria (such as strains producing the enzyme EGCG-hydrolyzing enzyme) convert EGCG to more bioavailable smaller molecules. This creates the 5–10× variation in plasma polyphenol levels observed between individuals consuming identical doses.
This is why the health effects of matcha — observed at population level in epidemiological studies — may vary substantially between individuals.
Practical Optimization
To maximize catechin bioavailability from matcha:
- Consume on an empty stomach or at least not with dairy milk
- Use optimal temperature (70–80°C): higher temps may slightly denature some catechins
- Don’t add dairy milk: reduces EGCG absorption by 25–35%
- Pair with vitamin C-rich foods: ascorbic acid protects catechins from intestinal degradation and may increase absorption