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| Phenethyl isothiocyanate (PEITC) is a naturally occurring small-molecule phytochemical best known for its role in cancer chemoprevention research. It belongs to the isothiocyanate class of organosulfur compounds and has the chemical formula C₉H₉NS. Source: Derived from glucosinolates in cruciferous vegetables PEITC in plants exists mainly as the glucosinolate precursor (gluconasturtiin). Upon tissue disruption (chewing, chopping), myrosinase converts gluconasturtiin → PEITC. -PEITC bioavailability from fresh, chopped microgreens is high -Co-consumption with other isothiocyanates is additive/synergistic -Peak plasma levels: ~1–3 hours post-consumption -Half-life: ~4–6 hours -Generally well tolerated up to 40 mg/day (mild GI irritation at higher dose) PEITC is best characterized for its dual role in xenobiotic metabolism: Inhibition of Phase I enzymes -Suppresses cytochrome P450 enzymes (e.g., CYP1A1, CYP2E1) -Reduces activation of pro-carcinogens -Selectively depletes GSH in cancer cells -Directly increases ROS beyond buffering capacity Key pathways in cancer cells -GSH depletion -Mitochondrial ROS amplification -ASK1/JNK apoptosis Chemo relevance -Frequently chemo-sensitizing -Opposite of NAC/GSH Induction of Phase II enzymes -Activates NRF2–KEAP1 signaling -Increases expression of detoxification and antioxidant enzymes such as: -Glutathione S-transferases (GSTs) -NAD(P)H quinone oxidoreductase 1 (NQO1) -Heme oxygenase-1 (HMOX1) In preclinical systems, PEITC has been shown to: -Deplete intracellular glutathione (GSH), increasing oxidative stress in cancer cells -Induce mitochondrial dysfunction and apoptosis -Inhibit histone deacetylases (HDACs) (context-dependent) -Suppress pro-survival signaling pathways (e.g., STAT3, NF-κB) -Target cancer stem–like cells in some models Dietary origins PEITC present in vegetables such as: -Watercress (the richest source) -Broccoli -Cabbage -Brussels sprouts -Radish Bioavailability depends on: -Food preparation -Gut microbiota (myrosinase activity if plant enzyme is inactive) watercress microgreens generally have higher PEITC (and/or its precursor gluconasturtiin) per gram than mature watercress. -The enrichment is most pronounced per unit fresh weight in the 7–14 day window. -Absolute values vary substantially with cultivar, light intensity, sulfur/nitrogen nutrition, and post-harvest handling. | Growth stage | Age | PEITC potential (mg / 100 g FW) | Relative | | --------------- | -------: | ------------------------------: | ---------------: | | **Microgreens** | 7–10 d | **3.0–6.0** | **~2–4×** mature | | **Microgreens** | 11–14 d | **2.5–5.0** | ~2–3× | | Baby leaf | 21–28 d | 1.5–3.0 | ~1–2× | | Mature leaf | 35–45+ d | 0.8–1.5 | baseline | Dry weight basis | Growth stage | PEITC potential (mg / g DW) | | --------------------- | --------------------------: | | Microgreens (7–10 d) | **1.8–3.5** | | Microgreens (11–14 d) | 1.5–3.0 | | Mature leaf | 0.6–1.2 | Expect 2–5× variability depending on: -Light spectrum (blue light ↑ glucosinolates) -Sulfur availability Practical optimization tips Lighting -12–16 h/day -150–300 µmol/m²/s PAR (typical shop LEDs at 20–30 cm distance) Soil -Peat or peat-blend preferred -Avoid over-watering (dilutes concentration) Nutrition (optional but effective) -One light watering with ¼-strength sulfate-containing fertilizer around day 4–5 can increase PEITC ~15–30% Harvest & use -Cut, rest 5–10 minutes, then consume (allows myrosinase to fully convert gluconasturtiin → PEITC) Dose: (100 g fresh microgreens ≈ 2–4 mg bioavailable PEITC) -ie below doses are not really acheivable from fresh microgreens Minimum biologically active dose (humans): ~10–15 mg PEITC/day Common efficacy range used in human trials: 20–40 mg/day Upper short-term doses studied (generally tolerated): 60 mg/day Diet-achievable with watercress microgreens: Yes, at realistic portions These doses are chemopreventive / pathway-modulating, not cytotoxic chemotherapy. | PEITC dose (mg/day) | Dominant biological effects | | ------------------: | ----------------------------------------------- | | **5–10 mg** | Phase II enzymes, mild NRF2 | | **10–20 mg** | HDAC inhibition, ROS signaling | | **20–40 mg** | Apoptosis, cell-cycle arrest, anti-inflammatory | | **40–60 mg** | Strong redox stress in cancer cells | | >60 mg | Limited data; GI irritation risk |
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| Source: CGL-CS |
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| Mitogen-activated protein kinases (MAPKs) are a group of proteins involved in transmitting signals from the cell surface to the nucleus, playing a crucial role in various cellular processes, including growth, differentiation, and apoptosis (programmed cell death). MAPK Pathways: The MAPK family includes several pathways, the most notable being: 1.ERK (Extracellular signal-Regulated Kinase): Often associated with cell proliferation and survival. 2.JNK (c-Jun N-terminal Kinase): Typically involved in stress responses and apoptosis. 3.p38 MAPK: Associated with inflammatory responses and apoptosis. Inhibitors: Targeting the MAPK pathway has become a strategy in cancer therapy. For example, BRAF inhibitors (like vemurafenib) are used in treating melanoma with BRAF mutations. Altered Expression Levels: Overexpression: Many cancers exhibit overexpression of MAPK pathway components, such as RAS, BRAF, and MEK. This overexpression can lead to increased signaling activity, promoting cell proliferation and survival. Downregulation: In some cases, negative regulators of the MAPK pathway (e.g., MAPK phosphatases) may be downregulated, leading to enhanced MAPK signaling. The expression levels of MAPK pathway components can serve as biomarkers for cancer diagnosis, prognosis, and treatment response. For example, high levels of phosphorylated ERK (p-ERK) may indicate active MAPK signaling and poor prognosis in certain cancers. Numerous reports indicate that the MAPK pathway plays a major role in tumor progression and invasion, while inhibition of MAPK signaling reduces invasion. |
| 4925- | PEITC, | PEITC triggers multiple forms of cell death by GSH-iron-ROS regulation in K7M2 murine osteosarcoma cells |
| - | in-vitro, | OS, | NA |
Query results interpretion may depend on "conditions" listed in the research papers. Such Conditions may include : -low or high Dose -format for product, such as nano of lipid formations -different cell line effects -synergies with other products -if effect was for normal or cancerous cells
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