Allicin (mainly Garlic) / NRF2 Cancer Research Results

AL, Allicin (mainly Garlic): Click to Expand ⟱

Features:

Garlic (Allium sativum L.) (active ingredient- Allicin, an active sulfer compound).

Allicin — a reactive organosulfur thiosulfinate generated in situ when garlic (Allium sativum) tissue is crushed (alliin → allicin via alliinase). Functionally, it behaves as a short-lived electrophilic “reactive sulfur species” that rapidly modifies cellular thiols (e.g., glutathione and cysteine residues on proteins), producing broad redox and stress-signaling effects. Classification: small-molecule phytochemical (organosulfur thiosulfinate). Standard abbreviation(s): AL (common in Nestronics), “allicin”. Source/origin: freshly crushed raw garlic; allicin is not present in intact cloves and is chemically unstable, converting to other organosulfur metabolites after formation.

Primary mechanisms (ranked):

Thiol reactivity and redox disruption: rapid GSH/protein-thiol modification (S-thioallylation), shifting redox buffering and triggering oxidative/electrophilic stress signaling.
Mitochondrial stress and intrinsic apoptosis (context-dependent): ΔΨm disruption, cytochrome-c release, caspase activation, ER stress/UPR engagement (often downstream of redox stress).
Inflammatory transcriptional suppression (context-dependent): inhibition of NF-κB–linked programs and, in some models, STAT3 signaling.
Acetate metabolism constraint (model-dependent): reversible inhibition of acetyl-CoA synthetase activity (ACS/ACSS), potentially impacting acetate→acetyl-CoA flux under metabolic stress.
Growth and invasion signaling attenuation (model-dependent): PI3K/AKT and MAPK network modulation with downstream effects on EMT/MMPs and angiogenic programs (e.g., HIF-1α/VEGF).

Bioavailability / PK relevance: “Allicin exposure” is dominated by formation conditions and rapid chemical/biologic turnover. Many oral preparations deliver alliin/alliinase that may generate allicin after ingestion; measured systemic allicin is typically transient, while downstream allyl-sulfur metabolites (e.g., allyl methyl sulfide–related products) are more detectable. Cooking/processing and GI conditions substantially change allicin bioequivalence versus crushed raw garlic.

In-vitro vs systemic exposure relevance: Many anticancer cell studies use ~50–300 µM allicin; whether such free allicin concentrations are achievable at tumor sites after dietary/supplement intake is uncertain because of rapid thiol quenching and conversion to other sulfur species. Reported biological effects at lower concentrations may still occur locally (GI lumen/mucosa) or via metabolites, but direct extrapolation from high-µM in-vitro dosing is high-risk.

Clinical evidence status: Predominantly preclinical (cell/animal) for anticancer mechanisms; human data are mixed and often evaluate garlic preparations rather than purified allicin, with outcomes confounded by formulation-dependent “allicin bioequivalence” and co-occurring organosulfur compounds (e.g., DADS/DATS/SAMC). Cancer-therapeutic evidence remains inconclusive.

DADS (diallyl disulfide is a sulfur-based anticancer drug generated from garlic)
Summary:
- Four main organic sulfides in garlic, diallyl disulfide (DADS), diallyl trisulfide (DATS), S-allylmercaptocysteine (SAMC) and allicin.
- Reversible inhibitor of ACSS2.
- may inhibit NF-κB signaling
- induce oxidative stress in cancer cells by generating ROS
- might downregulate STAT3 activation
- Inconclusive evidence for cancer treatment.
- may inhibit platelet aggregation
Allicin is a reactive sulfur species (RSS) [23] with oxidizing properties, and it is able to oxidize thiols in cells, e.g., glutathione and cysteine residues in proteins.
-Allicin is not present in intact garlic; rather, it is formed when garlic is chopped or crushed. -Using crushed or chopped raw garlic or adding garlic at the end of the cooking process (after the heat is reduced) can help preserve its potential allicin content.
"Consumption of alliinase-inhibited cooked garlic was found to give higher than expected allicin bioequivalence, with AMS formation being about 30% (roasted garlic) or 16% (boiled garlic) that of crushed raw garlic."

-Allicin is not present in intact garlic.
-It's formed enzymatically when alliin (a sulfur-containing amino acid) is converted by alliinase when garlic is chopped or crushed.Best consumed raw immediately after crushing (wait 5–10 min before consuming for full conversion)
-Allicin is unstable, degrading within hours into other sulfur compounds (like diallyl disulfide).

-Note half-life reports vary 2.5-90hrs?.
-moderately water-soluble but rapidly degrades/quenched (especially with thiols), so aqueous solutions have limited practical stability : BioAv

Pathways:
- induce ROS production
- ROS↑ related: MMP↓(ΔΨm), ER Stress↑, Ca+2↑, Cyt‑c↑, Caspases↑, DNA damage↑, UPR↑, cl-PARP↑, HSP↓
- Lowers AntiOxidant defense in Cancer Cells: NRF2↓">NRF2↓, GSH↓
- Raises AntiOxidant defense in Normal Cells: NRF2↑">NRF2↑, SOD↑, GSH↑, Catalase↑,
- lowers Inflammation : NF-kB↓, COX2↓, p38↓, Pro-Inflammatory Cytokines : IL-1β↓, TNF-α↓, IL-6↓, IL-8↓
- PI3K/AKT(Inhibition), JAK/STATs, Wnt/β-catenin, AMPK, MAPK/ERK, and JNK.
- inhibit Growth/Metastases : EMT↓, MMP2↓, MMP9↓, VEGF↓, ERK↓
- reactivate genes thereby inhibiting cancer cell growth : HDAC↓(not commonly listed as inhibitor), DNMT1↓, P53↑, HSP↓
- cause Cell cycle arrest : TumCCA↑, cyclin D1↓, cyclin E↓, CDK2↓, CDK4↓, CDK6↓,
- inhibits Migration/Invasion : TumCMig↓, FAK↓, ERK↓,
- inhibits angiogenesis↓ : VEGF↓, HIF-1α↓, EGFR↓,
- inhibits Cancer Stem Cells : CSC↓,
- Others: PI3K↓, AKT↓, STAT3, Wnt↓, β-catenin↓, AMPK↓, ERK↓, JNK,
- Synergies: chemo-sensitization, chemoProtective, RadioSensitizer, RadioProtective, Others(review target notes), Neuroprotective, Cognitive, Renoprotection, Hepatoprotective, CardioProtective,
- Selectivity: Cancer Cells vs Normal Cells

Allicin has been reported to exhibit a range of effects, including:
Antimicrobial activity: 10-50 μM
Antioxidant activity: 10-100 μM
Anti-inflammatory activity: 20-50 μM
Anticancer activity: 50-100 μM or (50–300uM) (2–5 mg allicin per kilogram of body weight per day)
Cardiovascular health: 20-50 μM

Approximate μM concentrations of allicin that can be achieved:
1 clove of garlic (3g): approximately 10-50 μM of allicin
single clove of garlic may yield about 5–9 mg of allicin,
1 tablespoon of minced garlic (15g): approximately 50-150 μM of allicin
1 cup of chopped garlic (100g): approximately 200-500 μM of allicin
1 tablespoon of chopped garlic chives (15g): approximately 5-20 μM of allicin
1 cup of chopped garlic chives (100g): approximately 20-50 μM of allicin
1 ounce (28g) of garlic microgreens: approximately 50-200 μM of allicin
1 cup of garlic microgreens (100g): approximately 200-500 μM of allicin
1 ounce (28g) of garlic chive microgreens: approximately 20-50 μM of allicin
1 cup of garlic chive microgreens (100g): approximately 50-100 μM of allicin

Allicin is a bioactive compound derived from garlic that has garnered significant interest for its potential anticancer properties through multiple mechanisms, including antioxidant activity, induction of apoptosis, cell cycle arrest, and modulation of key signaling pathways. While regular dietary intake of garlic is associated with cancer prevention benefits, allicin is also being explored as an adjunct to conventional cancer treatments.

Available in supplement tablet/capsule form for example at 2000mg (fresh bulb equilvalent)
IC50 of normal cells it >160mg/mL (large selectivity).
IC50 might be about 12-30ug/ml (approximately 62-185 µM) (which is about 30-90 grams of garlic consumption).
This makes it difficult to consume enough supplements to achieve that level.

Pathways:

ROS Generation and Oxidative Stress (inducing)
• ROS generation is often considered a primary trigger that feeds into downstream pathways (e.g., MAPK activation, mitochondrial membrane permeabilization).
Mitochondrial (Intrinsic) Apoptotic Pathway
• ROS-induced mitochondrial damage can lead to the release of cytochrome c and subsequent activation of caspases (e.g., caspase-9 and caspase-3).
NF-κB Signaling Inhibition (block)
Modulation of MAPK Pathways (e.g., p38 MAPK and JNK)
• ROS generation by allicin can activate stress-responsive kinases such as p38 MAPK and c-Jun N-terminal kinase (JNK).
Inhibition of PI3K/Akt Pathway
ROS levels and PI3K/Akt signaling, with increased oxidative stress often correlating with reduced Akt phosphorylation and activity.

At lower doses, allicin may lead to a modest increase in ROS levels that the cell’s antioxidant defenses (e.g., glutathione, superoxide dismutase) can manage

Allicin (Garlic) — mechanistic axes relevant to oncology

Rank	Pathway / Axis	Cancer Cells	Normal Cells	TSF	Primary Effect	Notes / Interpretation
1	Thiol chemistry and redox buffering	GSH↓, protein thiols modified; ROS↑ (dose-dependent)	Adaptive buffering often stronger; ROS↔/↑ (context-dependent)	P	Electrophilic/thiol stress that re-wires signaling	Central “first-contact” mechanism: allicin rapidly reacts with cysteine/GSH, so many downstream pathway changes are secondary to thiol stress.
2	Mitochondria and intrinsic apoptosis	ΔΨm↓, Cyt-c↑, Caspase↑, cl-PARP↑	Typically less apoptosis at matched doses (selectivity varies)	R	Pro-apoptotic stress execution	Frequently downstream of rank #1; selectivity can reflect baseline redox fragility and metabolic state.
3	ER stress and UPR	ER stress↑, UPR↑ (model-dependent)	UPR↔/↑ (context-dependent)	R	Proteostasis stress amplification	Can couple to Ca²⁺ release, apoptosis, and inflammatory signaling changes.
4	Ca²⁺ signaling	Ca²⁺↑ (model-dependent)	Ca²⁺↔/↑ (context-dependent)	R	Stress coupling to mitochondria/ER	Often reported as part of the ER–mitochondria stress axis rather than a primary target.
5	NF-κB inflammatory axis	NF-κB↓; cytokine programs↓ (context-dependent)	Inflammatory tone↓ (context-dependent)	G	Anti-inflammatory transcriptional suppression	May be beneficial in tumor-promoting inflammation contexts; also relevant to platelet/vascular biology.
6	STAT3 signaling	STAT3↓ (model-dependent)	STAT3↔ (context-dependent)	G	Reduced survival/proliferation programs	Evidence is model-specific; frequently downstream of redox/inflammation modulation.
7	NRF2 antioxidant response	NRF2↓ or maladaptive NRF2 response (context-dependent)	NRF2↑ (context-dependent)	G	Differential stress adaptation	Reported “cancer vs normal” divergence is plausible but not universal; strongly dose/model dependent.
8	Acetate to acetyl-CoA metabolism	ACS/ACSS activity↓ (model-dependent)	ACS/ACSS activity↓ (context-dependent)	R	Limits acetate utilization under stress	Primary biochemical evidence exists for acetyl-CoA synthetase inhibition by allicin; translation to tumor-selective ACSS2 targeting is uncertain without exposure confirmation.
9	PI3K/AKT and MAPK network	PI3K/AKT↓, ERK/JNK↔/↓ (model-dependent)	↔ (context-dependent)	G	Reduced growth/survival signaling	Commonly reported but typically secondary to upstream stress/redox effects.
10	HIF-1α and angiogenesis	HIF-1α↓, VEGF↓ (model-dependent)	↔ (context-dependent)	G	Anti-angiogenic signaling shift	Most supportive data are preclinical; dependent on hypoxia models and dosing.
11	EMT, migration, invasion	EMT↓, MMPs↓ (model-dependent)	↔ (context-dependent)	G	Reduced invasive phenotype	Usually downstream of PI3K/MAPK/inflammation rewiring and/or oxidative stress–driven cytostasis.
12	Radiosensitization and chemosensitization	Sensitization↑ (context-dependent)	Protection↔/↑ (context-dependent)	G	Stress-based therapeutic interaction	Potential bidirectionality: pro-oxidant sensitization in tumors vs antioxidant adaptation in normal tissues depends on schedule and formulation.
13	Clinical Translation Constraint	Chemical instability; rapid thiol quenching; formulation-dependent “allicin bioequivalence”; uncertain tumor-site free-allicin exposure; many in-vitro studies use high µM levels; human cancer outcomes largely from heterogeneous garlic preparations rather than purified allicin.					Primary constraint is exposure control, not target plausibility.

NRF2, nuclear factor erythroid 2-related factor 2: Click to Expand ⟱

Source: TCGA

Type: Antiapoptotic

Nrf2 is responsible for regulating an extensive panel of antioxidant enzymes involved in the detoxification and elimination of oxidative stress. Thought of as "Master Regulator" of antioxidant response.
-One way to estimate Nrf2 induction is through the expression of NQO1.
NQO1, the most potent inducer:
SFN 0.2 μM,
quercetin (2.5 μM),
curcumin (2.7 μM),
Silymarin (3.6 μM),
tamoxifen (5.9 μM),
genistein (6.2 μM ),
beta-carotene (7.2μM),
lutein (17 μM),
resveratrol (21 μM),
indol-3-carbinol (50 μM),
chlorophyll (250 μM),
alpha-cryptoxanthin (1.8 mM),
and zeaxanthin (2.2 mM)

1. Raising Nrf2 enhances the cell's antioxidant defenses and ↓ROS. This strategy is used to decrease chemo-radio side effects.
2. Downregulating Nrf2 lowers antioxidant defenses and ↑ROS. In cancer cells this leads to DNA damage, and cell death.
3. However there are some cases where increasing Nrf2 paradoxically causes an increase in ROS (cancer cells). Such as cases of Mitochondial overload, signal crosstalk, reductive stress

-In some cases, Nrf2 is overexpressed in cancer cells, which can lead to the activation of genes involved in cell proliferation, angiogenesis, and metastasis. This can contribute to the development of resistance to chemotherapy and targeted therapies.
-Increased Nrf2 expression: Lung, Breast, Colorectal, Prostrate.
Decreased Nrf2 expression: Skine, Liver, Pancreatic.
-Nrf2 is a cytoprotective transcription factor which demonstrated both a negative effect as well as a positive effect on cancer
- "promotes Nrf2 translocation from the cytoplasm to the nucleus," means facilitates the movement of Nrf2 into the nucleus, thereby enhancing the cell's antioxidant and cytoprotective responses. -Major regulator of Nrf2 activity in cells is the cytosolic inhibitor Keap1.

Nrf2 Inhibitors and Activators
Nrf2 Inhibitors: Brusatol, Luteolin, Trigonelline, VitC, Retinoic acid, Chrysin
Nrf2 Activators: SFN, OPZ EGCG, Resveratrol, DATS, CUR, CDDO, Api
- potent Nrf2 inducers from plants include sulforaphane, curcumin, EGCG, resveratrol, caffeic acid phenethyl ester, wasabi, cafestol and kahweol (coffee), cinnamon, ginger, garlic, lycopene, rosemany

Nrf2 plays dual roles in that it can protect normal tissues against oxidative damage and can act as an oncogenic protein in tumor tissue.
– In healthy tissues, NRF2 activation helps protect cells from oxidative damage and maintains cellular homeostasis.
– In many cancers, constitutive activation of NRF2 (often through mutations in NRF2 itself or loss-of-function mutations in KEAP1) leads to an enhanced antioxidant capacity.
– This upregulation can promote tumor cell survival by enabling cancer cells to thrive under oxidative stress, resist chemotherapeutic agents, and sustain metabolic reprogramming.
– Elevated NRF2 levels have been implicated in promoting tumor growth, metastasis, and resistance to therapy in various malignancies.
– High or sustained NRF2 activity is frequently associated with aggressive tumor phenotypes, poorer prognosis, and decreased overall survival in several cancer types.
– While its activation is essential for protecting normal cells from oxidative stress, aberrant or sustained NRF2 activation in tumor cells can lead to enhanced survival, therapeutic resistance, and tumor progression.

NRF2 inhibitors: (to decrease antioxidant defenses and increase cell death from ROS).
-Brusatol: most cited natural inhibitors of Nrf2.
-Luteolin: luteolin can reduce Nrf2 activity in specific cancer models and may enhance cell sensitivity to chemotherapy. However, luteolin is also known as an antioxidant, and its influence on Nrf2 can sometimes be context dependent.
-Apigenin: certain studies to down‑regulate Nrf2 in cancer cells: Dose and context dependent .
-Oridonin:
-Wogonin: although its effects might be cell‑ and dose‑specific.
- Withaferin A

Scientific Papers found: Click to Expand⟱

256-

AL,

doxoR,

Allicin Overcomes Doxorubicin Resistance of Breast Cancer Cells by Targeting the Nrf2 Pathway

in-vitro,

BC,

MCF-7

in-vitro,

BC,

MDA-MB-231

NRF2↓, HO-1↓, p‑Akt↓,

Showing Research Papers: 1 to 1 of 1

* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 1

Pathway results for Effect on Cancer / Diseased Cells:

Redox & Oxidative Stress ⓘ

HO-1↓, 1, NRF2↓, 1,

Cell Death ⓘ

p‑Akt↓, 1,
Total Targets: 3

Pathway results for Effect on Normal Cells:

Total Targets: 0

Scientific Paper Hit Count for: NRF2, nuclear factor erythroid 2-related factor 2

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