TIMP2 Cancer Research Results

TIMP2, Tissue Inhibitor of Metalloproteinases-2: Click to Expand ⟱
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TIMP-2 has been shown to have distinct effects on cancer progression compared to TIMP-1. Research has suggested that TIMP-2 may have anti-tumor effects in certain types of cancer, including:
• Inhibiting tumor growth: TIMP-2 has been shown to inhibit the growth of tumor cells in vitro and in vivo.
High levels of TIMP-2 have been associated with better prognosis and improved survival in some cancers.
High levels of TIMP-2 have been associated with better prognosis and improved survival in some cancers.
High TIMP-2 expression: Breast, Lung, colorectal, Prostrate.
Low TIMP-2 expression: Ovarian, Pancreatic, Gastric.
Scientific Papers found: Click to Expand⟱
247- AL,    Allicin inhibits the invasion of lung adenocarcinoma cells by altering tissue inhibitor of metalloproteinase/matrix metalloproteinase balance via reducing the activity of phosphoinositide 3-kinase/AKT signaling
- in-vitro, Lung, A549 - in-vitro, Lung, H1299
MMP2↓, protein levels of
MMP9↓, protein levels of
TIMP1↑,
TIMP2↑,
p‑Akt↓,
PI3K/Akt↓,

3391- ART/DHA,    Antitumor Activity of Artemisinin and Its Derivatives: From a Well-Known Antimalarial Agent to a Potential Anticancer Drug
- Review, Var, NA
TumCP↓, inhibiting cancer proliferation, metastasis, and angiogenesis.
TumMeta↓,
angioG↓,
TumVol↓, reduces tumor volume and progression
BioAv↓, artemisinin has low solubility in water or oil, poor bioavailability, and a short half-life in vivo (~2.5 h)
Half-Life↓,
BioAv↑, semisynthetic derivatives of artemisinin such as artesunate, arteeter, artemether, and artemisone have been effectively used as antimalarials with good clinical efficacy and tolerability
eff↑, preloading of cancer cells with iron or iron-saturated holotransferrin (diferric transferrin) triggers artemisinin cytotoxicity
eff↓, Similarly, treatment with desferroxamine (DFO), an iron chelator, renders compounds inactive
ROS↑, ROS generation may contribute with the selective action of artemisinin on cancer cells.
selectivity↑, Tumor cells have enhanced vulnerability to ROS damage as they exhibit lower expression of antioxidant enzymes such as superoxide dismutase, catalase, and gluthatione peroxidase compared to that of normal cells
TumCCA↑, G2/M, decreased survivin
survivin↓,
BAX↑, Increased Bax, activation of caspase 3,8,9 Decreased Bc12, Cdc25B, cyclin B1, NF-κB
Casp3↓,
Casp8↑,
Casp9↑,
CDC25↓,
CycB/CCNB1↓,
NF-kB↓,
cycD1/CCND1↓, decreased cyclin D, E, CDK2-4, E2F1 Increased Cip 1/p21, Kip 1/p27
cycE/CCNE↓,
E2Fs↓,
P21↑,
p27↑,
ADP:ATP↑, Increased poly ADP-ribose polymerase Decreased MDM2
MDM2↓,
VEGF↓, Decreased VEGF
IL8↓, Decreased NF-κB DNA binding [74, 76] IL-8, COX2, MMP9
COX2↓,
MMP9↓,
ER Stress↓, ER stress, degradation of c-MYC
cMyc↓,
GRP78/BiP↑, Increased GRP78
DNAdam↑, DNA damage
AP-1↓, Decreased NF-κB, AP-1, Decreased activation of MMP2, MMP9, Decreased PKC α/Raf/ERK and JNK
MMP2↓,
PKCδ↓,
Raf↓,
ERK↓,
JNK↓,
PCNA↓, G2, decreased PCNA, cyclin B1, D1, E1 [82] CDK2-4, E2F1, DNA-PK, DNA-topo1, JNK VEGF
CDK2↓,
CDK4↓,
TOP2↓, Inhibition of topoisomerase II a
uPA↓, Decreased MMP2, transactivation of AP-1 [56, 88] NF-κB uPA promoter [88] MMP7
MMP7↓,
TIMP2↑, Increased TIMP2, Cdc42, E cadherin
Cdc42↑,
E-cadherin↑,

556- ART/DHA,    Artemisinins as a novel anti-cancer therapy: Targeting a global cancer pandemic through drug repurposing
- Review, NA, NA
IL6↓,
IL1↓, IL-1β
TNF-α↓,
TGF-β↓, TGF-β1
NF-kB↓,
MIP2↓,
PGE2↓,
NO↓,
Hif1a↓,
KDR/FLK-1↓,
VEGF↓,
MMP2↓,
TIMP2↑,
ITGB1↑,
NCAM↑,
p‑ATM↑,
p‑ATR↑,
p‑CHK1↑,
p‑Chk2↑,
Wnt/(β-catenin)↓,
PI3K↓,
Akt↓,
ERK↓, ERK1/2
cMyc↓,
mTOR↓,
survivin↓,
cMET↓,
EGFR↓,
cycD1/CCND1↓,
cycE1↓,
CDK4/6↓,
p16↑,
p27↑,
Apoptosis↑,
TumAuto↑,
Ferroptosis↑,
oncosis↑,
TumCCA↑, G0/G1 into M phase, G0/G1 into S phase, G1 and G2/M
ROS↑, ovarian cancer cell line model, artesunate induced oxidative stress, DNA double-strand breaks (DSBs) and downregulation of RAD51 foci
DNAdam↑,
RAD51↓,
HR↓,

3167- Ash,    Withaferin A Inhibits the Proteasome Activity in Mesothelioma In Vitro and In Vivo
- in-vitro, MM, H226
TumCP↓, WA inhibits MPM cell proliferation
cMyc↓, Among the genes that were down-regulated included cell growth and metastasis-promoting oncogenes c-myc, c-fos, c-jun, while tissue inhibitor of metallopeptidases (TIMP)-2 was significantly upregulated
cFos↓,
cJun↓,
TIMP2↑,
Vim↓, WA exposure caused reduced levels of vimentin at 24 h of treatment.
ROS↑, WA treatment generated reactive oxygen species (ROS), causing cell death in HL-60 cells
BAX↑, Consistent with these findings, we found that WA treatments increased pro-apoptotic protein Bax and NF-κB inhibitory protein IκB-α in the patient derived MPM cells.
IKKα↑,
Casp3↑, Indeed, WA treatment induced caspase-3 activation, PARP cleavage,
cl‑PARP↑,

5591- BetA,    Advances and challenges in betulinic acid therapeutics and delivery systems for breast cancer prevention and treatment
- Review, BC, NA
BioAv↓, However, its poor water solubility limits its optimal therapeutic potential.
BioAv↑, nano-drug delivery systems (NDDSs) have gained significant attention as a method to substantially improve low solubility and poor drug bioavailability, enhance targeted drug delivery, and reduce side effects.
selectivity↑, reviews by Simone Fulda23,24 strengthened BA's potential for cancer treatment and prevention, particularly its ability to selectively trigger apoptosis in cancer cells while causing minimal harm to normal cells.
eff↑, It is important to note that the anticancer effects of BA on different types of tumors are more potent at a pH lower than 6.8.34
angioG↓, figure 3
*antiOx↑,
*Inflam↓,
MMP↓, BA-induced mitochondrial depolarization
Bcl-2↓, BA treatment has been shown to lower Bcl-2 expression and increase Bax, resulting in the activation of caspase-9 and caspase-3 through the mitochondrial pathway.63
BAX↑,
Casp9↑,
Casp3↑,
GRP78/BiP?, BA directly targets GRP78, triggering ER stress by activating the PERK-eIF2α-CHOP apoptotic cascade
ER Stress↑,
PERK↑,
CHOP↑,
ChemoSen↑, BA's ability to chemosensitize BC cells to taxanes highlights its importance in situations of drug resistance
SESN2↑, Under hypoxia, BA strongly increases SESN2 expression.
ROS↑, Reducing SESN2 levels enhances BA-induced ROS production, DNA damage, and radiosensitivity, while decreasing autophagic flux, indicating that SESN2-mediated autophagy serves as a protective adaptive response.68
MOMP↓, decreases the mitochondrial outer membrane potential (MOMP),
MAPK↑, This leads to the activation of p38 Mitogen-activated protein kinase (p38 MAPK), the release of cytochrome C, apoptosis-inducing factor (AIF),
Cyt‑c↑,
AIF↑,
STAT3↓, BA suppresses the signal transducer and activator of transcription (STAT) 3 signaling pathways
FAK↓, BA's inhibition of STAT3, as well as FAK, leads to decreased expression of MMPs and elevated TIMP-2, thereby impairing cancer cell migration and invasion
TIMP2↑,
TumCMig↓,
TumCI↓,
Sp1/3/4↓, Sp inhibition reduces cancer gene expression, inhibiting cancer cell growth.
TumCCA↑, It increases cell numbers in the G2/M phase, leading to cell cycle arrest.
DNAdam↑, causes DNA damage, thereby inhibiting the progression and invasion of cancer cells.

2742- BetA,    Betulinic acid impairs metastasis and reduces immunosuppressive cells in breast cancer models
- in-vitro, BC, MDA-MB-231 - in-vivo, BC, 4T1 - in-vitro, BC, MCF-7
tumCV↓, BA decreased the viability of three breast cancer cell lines and markedly impaired cell migration and invasion
TumCMig↓,
TumCI↓,
STAT3↑, BA could inhibit the activation of stat3 and FAK which resulted in a reduction of matrix metalloproteinases (MMPs)
FAK↓,
MMPs↓,
MMP2↓, BA treatment decreased the expression of MMP-2 and MMP-9 while increased the expression of TIMP-2 in 4T1 and MDA-MB-231 cells.
MMP9↓,
TIMP2↑,

2746- BetA,    Betulinic acid induces apoptosis and inhibits metastasis of human colorectal cancer cells in vitro and in vivo
- in-vitro, CRC, HCT116 - in-vivo, CRC, NA
TumCG↓, BA inhibited colorectal cancer cell lines in vitro with a time-dependent and dose-dependent manner.
BAX↑, upregulating expression of Bax and cleaved caspase-3 and downregulating protein of Bcl-2
Bcl-2↓,
ROS↑, BA could increase the production of reactive oxygen species and reduce mitochondrial membrane potential of cancer cell, suggesting that BA induced cancer cells apoptosis by mitochondrial mediated pathways
MMP↓,
TIMP2↑, BA significantly inhibited the migration and invasion of colorectal cancer cells, reduced the expression of matrix metalloproteinase (MMPs) and increased the expression of MMPs inhibitor (TIMP-2).
TumVol↓,

5894- CAR,    Targeting Gastrointestinal Cancers with Carvacrol: Mechanistic Insights and Therapeutic Potential
- Review, Var, NA
AntiCan↑, Carvacrol has demonstrated strong anticancer properties by modulating multiple molecular pathways governing apoptosis, inflammation, angiogenesis, and metastasis.
Apoptosis↑,
Inflam↓,
angioG↓,
TumMeta↓,
selectivity↑, revealed its ability to selectively target cancer cells while sparing healthy tissue
BioAv↑, nanotechnology have further enhanced its pharmacological profile by improving solubility, stability, and tumor-targeted delivery.
ChemoSen↑, synergistic effects when used in combination with conventional chemotherapeutics.
Dose↝, 84.38% of OEO’s contents are ‘carvacrol’.
TumCP↓, limit metastasis, induce apoptosis, suppress tumor cell proliferation, and improve the effectiveness of traditional chemotherapy medications
hepatoP↑, Carvacrol shows biological activities, such as antimicrobial, antitumor, antimutagenic, antigenotoxic, anti-inflammatory, anti-angiogenic, hepatoprotective, and antihepatotoxic properties.
Casp3↑, induced apoptosis by activating caspase-3 and caspase-9 while downregulating Bcl-2 mRNA levels
Casp9↑,
Bcl-2↓,
ROS↑, carvacrol causes oxidative stress by increasing the production of reactive oxygen species (ROS) and depleting GSH levels, which results in strong lethal effects on AGS gastric cancer
GSH↓,
BAX↑, upregulating pro-apoptotic markers such as Bax, caspase-3, caspase-7, caspase-8, caspase-9, cytochrome C, Fas, Fas-associated death domain (FADD), and p53
Casp7↑,
Casp8↑,
Cyt‑c↑,
Fas↑,
FADD↑,
P53↑,
Bcl-2↓, downregulating anti-apoptotic Bcl-2.
TumMeta↓, preventing metastasis by limiting the migration and invasion of cancer cells by upregulating epithelial markers like E-Cadherin and tissue inhibitors of metalloproteinases 2 and 3 (TIMP2 and TIMP3)
TumCMig↓,
TumCI↓,
E-cadherin↑,
TIMP2↑,
TIMP3↑,
N-cadherin↓, downregulating mesenchymal markers like N-Cadherin and ZEB2
ZEB2↓,
*lipid-P↓, protects the liver from diethylnitrosamine (DEN)-induced hepatocellular carcinogenesis by reducing lipid peroxidation, restoring key liver enzymes (AST, ALT, ALP, LDH, cGT)
*AST↓,
*ALAT↓,
*ALP↓,
*LDH↓,
*SOD↑, and enhancing antioxidant defenses (SOD, CAT, GPx, GR, GSH)
*Catalase↑,
*GPx↑,
*GSR↑,
selectivity↑, while selectively inducing apoptosis in cancer cells without harming normal liver tissue
cl‑PARP↑, inhibits HepG2 cancer cell growth by activating caspase-3, promoting PARP cleavage, downregulating Bcl-2, and modulating the MAPK signaling pathway by selectively reducing ERK1/2 phosphorylation while activating p38
ERK↓,
p38↑,
OS↑, rats (aged 6–8 weeks) demonstrated that carvacrol enhances sorafenib efficacy in HCC, improving survival rates, reducing tumor progression, and mitigating sorafenib-induced cardiac and hepatic toxicity.
AFP↓, carvacrol reduces serum alpha-fetoprotein (AFP) and alpha-L-fucosidase (AFU) levels by downregulating COX-2 and oxidative stress, inhibits angiogenesis via VEGF suppression,
COX2↓,
VEGF↓,
PCNA↓, prevents tumor proliferation by downregulating proliferating cell nuclear antigen (PCNA) and Ki-67 through TNF-α suppression.
Ki-67↓,
TNF-α↓,
BioAv↓, Despite carvacrol’s promising effects in vitro and in vivo, limitations such as bioavailability and solubility challenge its therapeutic application.

2790- CHr,    Chrysin: Pharmacological and therapeutic properties
- Review, Var, NA
*hepatoP↑, graphical abstract
*neuroP↓,
*ROS↓,
*cardioP↑,
*Inflam↓,
eff↑, suppression of hTERT and cyclin D1 gene expression in T47D breast cancer cell lines is due to the combined effect of metformin and chrysin
hTERT/TERT↓,
cycD1/CCND1↓,
MMP9↓, nanoparticle-based chrysin in C57B16 mice bearing B16F10 melanoma tumors was markedly presented reductions in the levels of MMP-9, MMP-2, and TERT genes, whereas it enhanced TIMP-2 andTIMP-1 genes expression
MMP2↓,
TIMP1↑,
TIMP2↑,
BioAv↑, nano-encapsulation of chrysin and curcumin improved the delivery of these phytochemicals that significantly inhibited the growth of cancer cells, while it decreased the hTERT gene expression via increased solubility and bioavailability
HK2↓, chrysin treatment restrained tumor growth in HCC xenograft models and significantly reduced HK-2 expression in tumor tissue
ROS↑, showing a significant increase in intracellular reactive oxygen species (ROS), cytotoxicity, mitochondrial membrane potential (MMP) collapse, caspase-3 activation, ADP/ATP ratio, and ultimately apoptosis
MMP↓,
Casp3↑,
ADP:ATP↑,
Apoptosis↑,
ER Stress↑, Likewise, chrysin encouraged endoplasmic reticulum (ER) stress via stimulation of unfolded protein response (UPR
UPR↑,
GRP78/BiP↝, (eIF2α), PRKR-like ER kinase (PERK) and 78 kDa glucose-regulated protein (GRP78).
eff↑, silibinin and chrysin synergistically inhibited growth of T47D BCC and downregulated the hTERT and cyclin D1 level
Ca+2↑, Primarily, increased ROS and cytoplasmic Ca 2+ levels alongside induction of cell death and loss of MMP are involved in inhibition of ovarian cancer through chrysin.

3238- EGCG,    Green tea catechin, epigallocatechin-3-gallate (EGCG): mechanisms, perspectives and clinical applications
- Review, Var, NA
Telomerase↓, EGCG stimulates telomere fragmentation through inhibiting telomerase activity.
DNMTs↓, EGCG reduced DNMTs,
cycD1/CCND1↓, EGCG also reduced the protein expression of cyclin D1, cyclin E, CDK2, CDK4, and CDK6. EGCG also inhibited the activity of CDK2 and CDK4, and caused Rb hypophosphorylation
cycE/CCNE↓,
CDK2↓,
CDK4↓,
CDK6↓,
HATs↓, EGCG can inhibit certain biomedically important molecular targets such as DNMTs, HATs, and HDACs
HDAC↓,
selectivity↑, EGCG has shown higher cytotoxicity in cancer cells than in their normal counterparts.
uPA↓, EGCG blocks urokinase, an enzyme which is essential for cancer growth and metastasis
NF-kB↓, EGCG inhibits NFκB and expression of TNF-α, reduces cancer promotion
TNF-α↓,
*ROS↓, It acts as strong ROS scavenger and antioxidant,
*antiOx↑,
Hif1a↓, ↓ HIF-1α; ↓ VEGF; ↓ VEGFR1;
VEGF↓,
MMP2↓, ↓ MMP-2; ↓ MMP-9; ↓ FAK;
MMP9↓,
FAK↓,
TIMP2↑, TIMP-2; ↑
Mcl-1↓, ↓ Mcl-1; ↓ survivin; ↓ XIAP
survivin↓,
XIAP↓,
PCNA↓, ↓ PCNA; ↑ 16; ↑ p18; ↑ p21; ↑ p27; ↑ pRb; ↑ p53; ↑ mdm2
p16↑,
P21↑,
p27↑,
pRB↑,
P53↑,
MDM2↑,
ROS↑, ↑ ROS; ↑ caspase-3; ↑ caspase-8; ↑ caspase-9; ↑ cytochrome c; ↑ Smac/DIABLO; ↓↑ Bax; Z Bak; ↓ cleaved PPAR;
Casp3↑,
Casp8↑,
Casp9↑,
Cyt‑c↑,
Diablo↑,
BAX⇅,
cl‑PPARα↓,
PDGF↓, ↓ PDGF; ↓ PDGFRb; ↓ EGFR;
EGFR↓,
FOXO↑, activated FOXO transcription factors
AP-1↓, The inhibition of AP-1 activity by EGCG was associated with inhibition of JNK activation but not ERK activation.
JNK↓,
COX2↓, EGCG reduces the activity of COX-2 following interleukin-1A stimulation of human chondrocytes
angioG↓, EGCG inhibits angiogenesis by enhancing FOXO transcriptional activity

2914- LT,    Therapeutic Potential of Luteolin on Cancer
- Review, Var, NA
*antiOx↑, As an antioxidant, Luteolin and its glycosides can scavenge free radicals caused by oxidative damage and chelate metal ions
*IronCh↑,
*toxicity↓, The safety profile of Luteolin has been proven by its non-toxic side effects, as the oral median lethal dose (LD50) was found to be higher than 2500 and 5000 mg/kg in mice and rats, respectively, equal to approximately 219.8−793.7 mg/kg in humans
*BioAv↓, One major problem related to the use of flavonoids for therapeutic purposes is their low bioavailability.
*BioAv↑, Resveratrol, which functions as the inhibitor of UGT1A1 and UGT1A9, significantly improved the bioavailability of Luteolin by decreasing the major glucuronidation metabolite in rats
DNAdam↑, Luteolin’s anticancer properties, which involve DNA damage, regulation of redox, and protein kinases in inhibiting cancer cell proliferation
TumCP↓,
DR5↑, Luteolin was discovered to promote apoptosis of different cancer cells by increasing Death receptors, p53, JNK, Bax, Cleaved Caspase-3/-8-/-9, and PARP expressions
P53↑,
JNK↑,
BAX↑,
cl‑Casp3↑,
cl‑Casp8↑,
cl‑Casp9↑,
cl‑PARP↑,
survivin↓, downregulating proteins involved in cell cycle progression, including Survivin, Cyclin D1, Cyclin B, and CDC2, and upregulating p21
cycD1/CCND1↓,
CycB/CCNB1↓,
CDC2↓,
P21↑,
angioG↓, suppress angiogenesis in cancer cells by inhibiting the expression of some angiogenic factors, such as MMP-2, AEG-1, VEGF, and VEGFR2
MMP2↓,
AEG1↓,
VEGF↓,
VEGFR2↓,
MMP9↓, inhibit metastasis by inhibiting several proteins that function in metastasis, such as MMP-2/-9, CXCR4, PI3K/Akt, ERK1/2
CXCR4↓,
PI3K↓,
Akt↓,
ERK↓,
TumAuto↑, can promote the conversion of LC3B I to LC3B II and upregulate Beclin1 expression, thereby causing autophagy
LC3B-II↑,
EMT↓, Luteolin was identified to suppress the epithelial to mesenchymal transition by upregulating E-cadherin and downregulating N-cadherin and Wnt3 expressions.
E-cadherin↑,
N-cadherin↓,
Wnt↓,
ROS↑, DNA damage that is induced by reactive oxygen species (ROS),
NICD↓, Luteolin can block the Notch intracellular domain (NICD) that is created by the activation of the Not
p‑GSK‐3β↓, Luteolin can inhibit the phosphorylation of the GSK3β induced by Wnt, resulting in the prevention of GSK3β inhibition
iNOS↓, Luteolin in colon cancer and the complications associated with it, particularly the decreasing effect on the expressions of inducible nitric oxide synthase (iNOS) and cyclooxygenase-2 (COX-2)
COX2↓,
NRF2↑, Luteolin has been identified to increase the expression of nuclear factor erythroid 2-related factor 2 (Nrf2), which is a crucial transcription factor with anticarcinogenic properties related
Ca+2↑, caused loss of the mitochondrial membrane action potential, enhanced levels of mitochondrial calcium (Ca2+),
ChemoSen↑, Luteolin enhanced the effect of one of the most effective chemotherapy drugs, cisplatin, on CRC cells
ChemoSen↓, high dose of Luteolin application negatively affected the oxaliplatin-based chemotherapy in a p53-dependent manner [52]. They suggested that the flavonoids with Nrf2-activating ability might interfere with the chemotherapeutic efficacy of anticancer
IFN-γ↓, decreased the expression of interferon-gamma-(IFN-γ)
RadioS↑, suggested that Luteolin can act as a radiosensitizer, promoting apoptosis by inducing p38/ROS/caspase cascade
MDM2↓, Luteolin treatment was associated with increased p53 and p21 and decreased MDM4 expressions both in vitro and in vivo.
NOTCH1↓, Luteolin suppressed the growth of lung cancer cells, metastasis, and Notch-1 signaling pathway
AR↓, downregulating the androgen receptor (AR) expression
TIMP1↑, Luteolin inhibits the migration of U251MG and U87MG human glioblastoma cell lines by downregulating MMP-2 and MMP-9 and upregulating the tissue inhibitor of metalloproteinase (TIMP)-1 and TIMP-2.
TIMP2↑,
ER Stress↑, Luteolin caused oxidative stress and ER stress in the Hep3B cells,
CDK2↓, Luteolin’s ability to decrease Akt, polo-like kinase 1 (PLK1), cyclin B1, cyclin A, CDC2, cyclin-dependent kinase 2 (CDK2) and Bcl-xL
Telomerase↓, Luteolin dose-dependently inhibited the telomerase levels and caused the phosphorylation of NF-κB and the target gene of NF-κB, c-Myc to suppress the human telomerase reverse transcriptase (hTERT)
p‑NF-kB↑,
p‑cMyc↑,
hTERT/TERT↓,
RAS↓, Luteolin was found to suppress the expressions of K-Ras, H-Ras, and N-Ras, which are the activators of PI3K
YAP/TEAD↓, Luteolin caused significant inhibition of yes-associated protein (YAP)/transcriptional co-activator with PDZ-binding motif (TAZ)
TAZ↓,
NF-kB↓, Luteolin was found to have a strong inhibitory effect on the NF-κB
NRF2↓, Luteolin-loaded nanoparticles resulted in a significant reduction in the Nrf2 levels compared to Luteolin alone.
HO-1↓, The expressions of the downstream genes of Nrf2, Ho1, and MDR1 were also reduced, where inhibition of Nrf2 expression significantly increased the cell death of breast cancer cells
MDR1↓,

3267- Lyco,    Lycopene inhibits angiogenesis both in vitro and in vivo by inhibiting MMP-2/uPA system through VEGFR2-mediated PI3K-Akt and ERK/p38 signaling pathways
- in-vitro, Nor, HUVECs
*VEGF↓, highest dose used (400 μg/plug) completely inhibited the formation of vascular endothelial cells induced by vascular endothelial growth factor (VEGF).
*MMP2↓, lycopene inhibited tube formation, invasion, and migration in HUVECs, and such actions were accompanied by reduced activities of matrix metalloproteinase-2, urokinase-type plasminogen activator, and protein expression of Rac1
*uPA↓,
*Rac1↑,
*TIMP2↑, and by enhancing protein expression of tissue inhibitors of metalloproteinase-2 and plasminogen activator inhibitor-1.
*p38↓, lycopene attenuated VEGF receptor-2 (VEGFR2)-mediated phosphorylation of extracellular signal-regulated kinase (ERK), p38, and Akt as well as protein expression of PI3K.
*Akt↓,
*angioG↓, anti-angiogenic effect of lycopene both in vitro and in vivo.

4782- Lyco,    New Insights into Molecular Mechanism behind Anti-Cancer Activities of Lycopene
- Review, Var, NA
AntiCan↑, From an anti-cancer perspective, lycopene is often associated with reduced risk of prostate cancer and people often look for it as a dietary supplement which may help to prevent cancer.
TumCP↓, Lycopene was known to be able to suppress cancerous cell proliferation, migration, invasion and adhesion activity in cell culture studies.
TumCMig↓,
TumCI↓,
TumCA↓,
ROS↓, Such suppression was often observed with changes of cancer-related gene expression and relief of oxidative stress
MMP2↓, In general, lycopene could suppress the expression of MMP-2, MMP-7, MMP-9, Sp1, IGF-1R, VEGF while increasing E-cadherin stabilization, connexin 43, nm23-H1, TIMP-1 and TIMP-2 levels
MMP7↓,
MMP9↓,
VEGF↓,
E-cadherin↑,
TIMP1↑,
TIMP2↑,
BioAv↝, it is recommended to avoid consumption of lycopene concurrently with high dietary fiber intake as several types of dietary fiber were found to be able to reduce the bioavailability of lycopene
*IL12↓, lycopene could suppress proinflammatory cytokines such as IL-12, TNF-α, IL-1, IL-1β, IL-6
*TNF-α↓,
*IL1↓,
*IL1β↓,
*IL6↓,
COX2↓, Sprague Dawley rat model, lycopene treatment after induction by azoxymethane caused suppression of aberrant crypt foci, preneoplastic lesion and biomarkers such as COX-2 and iNOS expression
iNOS↓,
*radioP↑, lycopene before induction of DNA damage via X-irradiation as lycopene treatment after irradiation failed to show such DNA protective effect
NF-kB↓, anti-cancer effect of lycopene was also observed in pancreatic cancer cells (PANC-1 cell line) whereby significant reduction of ROS, NF-κB and anti-apoptotic biomarkers (cIAP1, cIAP2 and survivin) was detected while an increment of caspase-3 and Bax:
survivin↓,
Casp3↑,
Bax:Bcl2↑,

4788- Lyco,    Lycopene as a potential anticancer agent: Current evidence on synergism, drug delivery systems and epidemiology (Review)
- Review, Var, NA
AntiCan↑, It may be associated with a reduction in the morbidity and mortality of several types of cancer, making it a prom‑ ising anticancer agent
ChemoSen↑, present review summarizes the synergistic effects of lycopene as a dietary supplement with other chemotherapy drugs or nutrients, for the enhancement of anticancer effects or the reduction of side effects from chemotherapy drugs.
chemoP↑,
Dose↝, Shao and Hathcock (20) proposed a 75 mg/day intake as the upper limit of lycopene for supplements, as no adverse effects were reported from continuous administration of 75 mg/day lycopene in a 4‑week clinical study
BioAv↑, Thermal processing of tomato products can cause changes in the structure of lycopene to shift and yield cis‑isomers in the product and this form is more bioavailable
BioAv↑, The presence of fat in food also helps enhance the absorption of lycopene (40) and its absorption is influenced by the amount of ingested fat, and the type and emulsification of dietary fat
BioAv↓, avoid the consumption of lycopene concurrently with high dietary fiber, as several types of dietary fiber (e.g. pectin, guar, alginate, etc.) are associated with lower bioavailability of lycopene
cardioP↑, figure 2
AntiDiabetic↑,
hepatoP↑,
neuroP↑,
MAPK↓, 2 mg/kg; 5 mg/kg Inhibition of MAPK signaling pathway (48) and decreased MMP‑2 and MMP‑9 activities through the activation of NM23‑H1, TIMP‑1 and TIMP‑2 expression.
MMP2↓,
MMP9↓,
TIMP1↑,
TIMP2↑,

3745- MFrot,  MF,    The neurobiological foundation of effective repetitive transcranial magnetic brain stimulation in Alzheimer's disease
- Review, AD, NA
*neuroP↑, neuroprotective actions aimed at mitigatingoxidative stress and inflammation, and intense stimulation of neu-rotrophic factors
*ROS↓,
*Inflam↓,
*5HT↑, increase in serotoninand its metabolites and a change in the properties of serotonergicreceptors.
*cFos↑, in rats, a single session of bothLF- (1 Hz) and HF-rTMS (10 Hz) enhanced c-Fos expression in all exam-ined cortical areas
*Aβ↓, rTMS enhances neuronal viability and counteracts oxidative stressors, such as Aβ and glutamate toxicity, in vitro
*memory↑, downregulation results in memory impairments
*BDNF↑, long-term change in synaptic proteinexpression due to BDNF-TrkB pathway activation following rTMSprotocols
*Ach↑, rTMSincreases ACh levels by modulating AChE activity.
*AChE↓,
*cognitive↑, HF-rTMS (20 Hz) and LF-rTMS (1 Hz)—in termsof neurotransmitter circuits and neurogenic signaling. 142 While bothprotocols improved cognition-related behaviors
*BDNF↑, Notably, rTMS could enhance BDNF and NGF expression irrespec-tive of frequency,
*NGF↑,
*β-catenin/ZEB1↑, both LF-rTMS (1 Hz) and HF-rTMS (10 Hz)protocols enhanced cognitive performance through the activation of β-catenin via the regulation of glycogen synthase kinase-3β (GSK-3β) andTau
*p‑Akt↓, 3 weeks, iTBS reducedinflammation and increased anti-inflammatory molecules, specificallylinked to reversing the downregulation of phosphorylated forms ofAkt and the mammalian target of rapamycin.
*mTOR↓,
*MMP1↓, 6 months, patients showed significant reductions in plasma levels of MMP1, MMP9, and MMP10, along with increases in TIMP1 and TIMP2
*MMP9↓,
*MMP-10↓,
*TIMP1↑,
*TIMP2↑,

1807- NarG,    A Systematic Review of the Preventive and Therapeutic Effects of Naringin Against Human Malignancies
- Review, NA, NA
AntiTum↑, antitumor ability of naringin
TumCP↓,
tumCV↓,
TumCCA↑,
Mcl-1↓,
RAS↓,
e-Raf↓, suppressing the Ras/Raf/extracellular
VEGF↓,
AntiAg↑,
MMP2↓,
MMP9↓,
TIMP2↑,
TIMP1↑,
p38↓,
Wnt↓,
β-catenin/ZEB1↑,
Casp↑,
P53↑,
BAX↑,
COX2↓,
GLO-I↓,
CYP1A1↑,
lipid-P↓,
p‑Akt↓,
p‑mTOR↓,
VCAM-1↓,
P-gp↓,
survivin↓,
Bcl-2↓,
ROS↑, ↑oxidative stress, Prostate DU145 cell line 50–250 μM
ROS↑, ↑ROS, Stomach (Gastric) AGS cell line, 1–3 mM
MAPK↑,
STAT3↓,
chemoP↑, flavonoids have excellent radical scavenging and iron-chelating properties (Kaiserová et al., 2007), and they can act as an effective modulator for DOX-induced toxicity

3347- QC,    Recent Advances in Potential Health Benefits of Quercetin
- Review, Var, NA - Review, AD, NA
*antiOx↑, Its strong antioxidant properties enable it to scavenge free radicals, reduce oxidative stress, and protect against cellular damage.
*ROS↓,
*Inflam↓, Quercetin’s anti-inflammatory properties involve inhibiting the production of inflammatory cytokines and enzymes,
TumCP↓, exhibits anticancer effects by inhibiting cancer cell proliferation and inducing apoptosis.
Apoptosis↑,
*cardioP↑, cardiovascular benefits such as lowering blood pressure, reducing cholesterol levels, and improving endothelial function
*BP↓, Quercetin‘s ability to reduce blood pressure was also supported by a different investigation
TumMeta↓, The most important impact of quercetin is its ability to inhibit the spread of certain cancers including those of the breast, cervical, lung, colon, prostate, and liver
MDR1↓, quercetin decreased the expression of genes multidrug resistance protein 1 and NAD(P)H quinone oxidoreductase 1 and sensitized MCF-7 cells to the chemotherapy medication doxorubicin
NADPH↓,
ChemoSen↑,
MMPs↓, Inhibiting CT26 cells’ migration and invasion abilities by inhibiting their expression of tissue inhibitors of metalloproteinases (TIMPs) inhibits their invasion and migration abilities
TIMP2↑,
*NLRP3↓, inhibited NLRP3 by acting on this inflammasome
*IFN-γ↑, quercetin significantly upregulates the gene expression and production of interferon-γ (IFN-γ), which is obtained from T helper cell 1 (Th1), and downregulates IL-4, which is obtained from Th2.
*COX2↓, quercetin is known to decrease the production of inflammatory molecules COX-2, nuclear factor-kappa B (NF-κB), activator protein 1 (AP-1), mitogen-activated protein kinase (MAPK), reactive nitric oxide synthase (NOS), and reactive C-protein (CRP)
*NF-kB↓,
*MAPK↓,
*CRP↓,
*IL6↓, Quercetin suppressed the production of inflammatory cytokines such as IL-6, TNF-α, and IL-1β via upregulating TLR4.
*TNF-α↓,
*IL1β↓,
*TLR4↑,
*PKCδ↓, Quercetin employed suppression on the phosphorylation of PKCδ to control the PKCδ–JNK1/2–c-Jun pathway.
*AP-1↓, This pathway arrested the accumulation of AP-1 transcription factor in the target genes, thereby resulting in reduced ICAM-1 and inflammatory inhabitation
*ICAM-1↓,
*NRF2↑, Quercetin overexpressed Nrf2 and targeted its downstream gene, contributing to increased HO-1 levels responsible for the down-regulation of TNF-α, iNOS, and IL-6
*HO-1↑,
*lipid-P↓, Quercetin acts as a potent antioxidant by scavenging ROS, inhibiting lipid peroxidation, and enhancing the activity of antioxidant enzymes
*neuroP↑, This helps to counteract oxidative stress and protect against neurodegenerative processes that contribute to AD
*eff↑, rats treated with chronic rotenone or 3-nitropropionic acid showed enhanced neuroprotection when quercetin and fish oil were taken orally
*memory↑, Both memory and learning abilities in the test animals increased
*cognitive↑,
*AChE↓, The increase in AChE activity brought on by diabetes was prevented in the cerebral cortex and hippocampus by quercetin at a level of 50 mg/kg body weight.
*BioAv↑, consumption of fried onions compared to black tea, suggesting that the form of quercetin present in onions is better absorbed than that in tea
*BioAv↑, This suggests that dietary fat can increase the absorption of quercetin [180]
*BioAv↑, potential of liposomes to enhance the bioactivity and bioavailability of quercetin has been the subject of several investigations
*BioAv↑, several emulsion types that may be employed to encapsulate quercetin, but oil-in-water (O/W) emulsions are the most widely utilized.
*BioAv↑, the kind of oil (triglyceride oils made up of either long-chain or medium-chain fatty acids) affected the bioaccessibility of quercetin and gastrointestinal stability, emphasizing the significance of picking a suitable oil phase

3371- QC,    Quercetin induces MGMT+ glioblastoma cells apoptosis via dual inhibition of Wnt3a/β-Catenin and Akt/NF-κB signaling pathways
- in-vitro, GBM, T98G
TIMP2↑, MMP2, and MMP9 was significantly decreased by quercetin treatment, while TIMP1 and TIMP2 were upregulated (
TumCG↓, Quercetin significantly suppressed the growth and migration of human GBM T98G cells, induced apoptosis, and arrested cells in the S-phase cell cycle
TumCMig↓,
Apoptosis↑,
TumCCA↑,
MMP↓, collapse of mitochondrial membrane potential, ROS generation, enhanced Bax/Bcl-2 ratio, and strengthened cleaved-Caspase 9 and cleaved-Caspase 3 suggested the involvement of ROS-mediated mitochondria-dependent apoptosis in the process
ROS↑,
Bax:Bcl2↑,
cl‑Casp9↑,
cl‑Casp3↑,
DNAdam↑, quercetin-induced apoptosis was accompanied by intense DNA double-strand breaks (DSBs), γH2AX foci formation, methylation of MGMT promoter, increased cleaved-PARP, and reduced MGMT expression
γH2AX↑,
MGMT↓,
cl‑PARP↑,

3079- RES,    Therapeutic role of resveratrol against hepatocellular carcinoma: A review on its molecular mechanisms of action
- Review, Var, NA
angioG↓, Resveratrol suppresses angiogenesis and metastatic markers to reverse cancer spread.
TumMeta↓,
ChemoSen↑, Resveratrol chemosensitizes chemotherapy and synergizes anti-cancer phytochemicals.
NADPH↑, Both in vitro and in vivo studies indicates that resveratrol enhances various redox enzymes activity, especially nicotinamide adenine dinucleotide phosphate (NADPH)
SIRT1↑, resveratrol effectively modulates both the cytokine and chemokine profiles in immune and endothelial cells by the upregulation of sirtuin-1 (SIRT1)
NF-kB↓, suppression of NF-κB and prevention of the activation of NOD-like receptor family (Nrf) pyrin domain containing-3 inflammasome [
NLRP3↓,
Dose↝, The optimal dose of resveratrol being around 150 mg per day is considered safe by all means.
COX2↓, Cox2 ↓; MMP9 ↓
MMP9↓,
PGE2↓, Cox1 and 2; PGE2↓
TIMP1↑, Resveratrol suppresses the PMA-induced MMP activity in HepG2 cell line, while it also upregulates tissue inhibitor proteins of MMP, namely, TIMP1 and TIMP2, in dose-dependent manner
TIMP2↑,
Sp1/3/4↓, Resveratrol mitigates the expression of SP-1 by inhibiting both phosphorylation of JNK1/2 and expression of urokinase-type plasminogen activator in Huh-7 cell line
p‑JNK↓,
uPAR↓,
ROS↓, Resveratrol attenuates the excessive ROS production and inflammatory cytokine, IL-6, and CXCR4 receptor expression by downregulating Gli-1 expression.
CXCR4↓,
IL6↓,
Gli1↓,
*ROS↓, redox imbalance may be attenuated by resveratrol via downregulating ROS production and simultaneously inducing antioxidant enzymes, GST, SOD, CAT and GPx activities in the cells
*GSTs↑,
*SOD↑,
*Catalase↑,
*GPx↑,
*lipid-P↓, [72] observed that resveratrol treatment not only reduces lipid peroxidation but also increases GSH and GST serum levels in CCl4-treated rats as compared to the CCl4-control animals
*GSH↑,
eff↑, Resveratrol, in combination with thymoquinone (TQ), has been demonstrated to provide a synergistic antiproliferative efficacy against HCC cell lines as reported by Ismail et al.
eff↑, Curcumin, a potential anticancer phytochemical, in combination with resveratrol has been reported to trigger synergistic apoptotic effects against Hepa1–6 cells
eff↑, berberine in combination with resveratrol lowers the cell viability and cell adhesion. At low concentration, berberine significantly induces cell death while resveratrol inhibits cell migration in HepG2 cells

3086- RES,    Resveratrol inhibits the tumor migration and invasion by upregulating TET1 and reducing TIMP2/3 methylation in prostate carcinoma cells
- in-vitro, Pca, LNCaP - in-vitro, Pca, PC3 - in-vitro, Pca, DU145
TET1↑, Res upregulated the 5hmC and TET1 levels and downregulated the 5mC level.
TumCMig↓, Res also inhibited the migration and invasion of PCa cells
TumCI↓,
TIMP2↑, promoted the demethylation of TIMP2 and TIMP3 to upregulate their expressions, and suppressed the expressions of MMP2 and MMP9.
TIMP3↑,
MMP2↓,
MMP9↓,

3332- SIL,    Silibinin inhibits the invasion of human lung cancer cells via decreased productions of urokinase-plasminogen activator and matrix metalloproteinase-2
- in-vitro, Lung, A549
*antiOx↑, Silibinin is a flavonoid antioxidant and wildly used for its antihepatotoxic properties
*hepatoP↑,
MMP2↓, silibinin treatment may decrease the expressions of MMP-2 and u-PA in a concentration- and time-dependent manner and enhance the expression of TIMP-2.
uPA↓,
TIMP2↑,

3131- VitC,    Antioxidant Vitamin C attenuates experimental abdominal aortic aneurysm development in an elastase-induced rat model
- in-vivo, Nor, NA
*MMP2↓, The proteins of matrix metalloproteinase (MMP)-2, MMP-9, and interleukin 6 were markedly downregulated (P < 0.05, respectively)
*MMP9↓,
*TNF-α↓, accompanied with notably reduced messenger RNA expression of tumor necrosis factor-α, MMP-2/9, and interleukin 1β
*IL1β↓,
*TIMP2↑, messenger RNA of tissue inhibitors of metalloproteinase-1 and tissue inhibitors of metalloproteinase-2 were both significantly upregulated in Vitamin C group.
*TIMP1↓,
*antiOx↑, increased level of antioxidant in cooperation with preserving elastin lamellae, inhibiting matrix-degrading proteinases and suppressing inflammatory responses.
*Inflam↓,


Showing Research Papers: 1 to 22 of 22

* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 22

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

CYP1A1↑, 1,   Ferroptosis↑, 1,   GSH↓, 1,   HO-1↓, 1,   lipid-P↓, 1,   NRF2↓, 1,   NRF2↑, 1,   ROS↓, 2,   ROS↑, 12,  

Mitochondria & Bioenergetics

ADP:ATP↑, 2,   AIF↑, 1,   CDC2↓, 1,   CDC25↓, 1,   MMP↓, 4,   Raf↓, 1,   e-Raf↓, 1,   XIAP↓, 1,  

Core Metabolism/Glycolysis

cMyc↓, 3,   p‑cMyc↑, 1,   GLO-I↓, 1,   HK2↓, 1,   NADPH↓, 1,   NADPH↑, 1,   PI3K/Akt↓, 1,   cl‑PPARα↓, 1,   SIRT1↑, 1,  

Cell Death

Akt↓, 2,   p‑Akt↓, 2,   Apoptosis↑, 5,   BAX↑, 7,   BAX⇅, 1,   Bax:Bcl2↑, 2,   Bcl-2↓, 5,   Casp↑, 1,   Casp3↓, 1,   Casp3↑, 6,   cl‑Casp3↑, 2,   Casp7↑, 1,   Casp8↑, 3,   cl‑Casp8↑, 1,   Casp9↑, 4,   cl‑Casp9↑, 2,   p‑Chk2↑, 1,   Cyt‑c↑, 3,   Diablo↑, 1,   DR5↑, 1,   FADD↑, 1,   Fas↑, 1,   Ferroptosis↑, 1,   hTERT/TERT↓, 2,   iNOS↓, 2,   JNK↓, 2,   JNK↑, 1,   p‑JNK↓, 1,   MAPK↓, 1,   MAPK↑, 2,   Mcl-1↓, 2,   MDM2↓, 2,   MDM2↑, 1,   MOMP↓, 1,   NICD↓, 1,   oncosis↑, 1,   p27↑, 3,   p38↓, 1,   p38↑, 1,   survivin↓, 6,   Telomerase↓, 2,   YAP/TEAD↓, 1,  

Kinase & Signal Transduction

Sp1/3/4↓, 2,  

Transcription & Epigenetics

cJun↓, 1,   HATs↓, 1,   pRB↑, 1,   tumCV↓, 2,  

Protein Folding & ER Stress

CHOP↑, 1,   ER Stress↓, 1,   ER Stress↑, 3,   GRP78/BiP?, 1,   GRP78/BiP↑, 1,   GRP78/BiP↝, 1,   PERK↑, 1,   UPR↑, 1,  

Autophagy & Lysosomes

LC3B-II↑, 1,   SESN2↑, 1,   TumAuto↑, 2,  

DNA Damage & Repair

p‑ATM↑, 1,   p‑ATR↑, 1,   p‑CHK1↑, 1,   DNAdam↑, 5,   DNMTs↓, 1,   HR↓, 1,   MGMT↓, 1,   p16↑, 2,   P53↑, 4,   cl‑PARP↑, 4,   PCNA↓, 3,   RAD51↓, 1,   γH2AX↑, 1,  

Cell Cycle & Senescence

CDK2↓, 3,   CDK4↓, 2,   CycB/CCNB1↓, 2,   cycD1/CCND1↓, 5,   cycE/CCNE↓, 2,   cycE1↓, 1,   E2Fs↓, 1,   P21↑, 3,   TumCCA↑, 5,  

Proliferation, Differentiation & Cell State

cFos↓, 1,   cMET↓, 1,   EMT↓, 1,   ERK↓, 4,   FOXO↑, 1,   Gli1↓, 1,   p‑GSK‐3β↓, 1,   HDAC↓, 1,   mTOR↓, 1,   p‑mTOR↓, 1,   NOTCH1↓, 1,   PI3K↓, 2,   RAS↓, 2,   STAT3↓, 2,   STAT3↑, 1,   TAZ↓, 1,   TOP2↓, 1,   TumCG↓, 2,   Wnt↓, 2,   Wnt/(β-catenin)↓, 1,  

Migration

AEG1↓, 1,   AntiAg↑, 1,   AP-1↓, 2,   Ca+2↑, 2,   Cdc42↑, 1,   CDK4/6↓, 1,   E-cadherin↑, 4,   FAK↓, 3,   ITGB1↑, 1,   Ki-67↓, 1,   MMP2↓, 12,   MMP7↓, 2,   MMP9↓, 11,   MMPs↓, 2,   N-cadherin↓, 2,   NCAM↑, 1,   PDGF↓, 1,   PKCδ↓, 1,   TET1↑, 1,   TGF-β↓, 1,   TIMP1↑, 7,   TIMP2↑, 19,   TIMP3↑, 2,   TumCA↓, 1,   TumCI↓, 5,   TumCMig↓, 6,   TumCP↓, 7,   TumMeta↓, 5,   uPA↓, 3,   uPAR↓, 1,   VCAM-1↓, 1,   Vim↓, 1,   ZEB2↓, 1,   β-catenin/ZEB1↑, 1,  

Angiogenesis & Vasculature

angioG↓, 6,   EGFR↓, 2,   Hif1a↓, 2,   KDR/FLK-1↓, 1,   NO↓, 1,   VEGF↓, 7,   VEGFR2↓, 1,  

Barriers & Transport

P-gp↓, 1,  

Immune & Inflammatory Signaling

COX2↓, 7,   CXCR4↓, 2,   IFN-γ↓, 1,   IKKα↑, 1,   IL1↓, 1,   IL6↓, 2,   IL8↓, 1,   Inflam↓, 1,   MIP2↓, 1,   NF-kB↓, 6,   p‑NF-kB↑, 1,   PGE2↓, 2,   TNF-α↓, 3,  

Protein Aggregation

NLRP3↓, 1,  

Hormonal & Nuclear Receptors

AR↓, 1,   CDK6↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 4,   BioAv↑, 6,   BioAv↝, 1,   ChemoSen↓, 1,   ChemoSen↑, 6,   Dose↝, 3,   eff↓, 1,   eff↑, 7,   Half-Life↓, 1,   MDR1↓, 2,   RadioS↑, 1,   selectivity↑, 5,  

Clinical Biomarkers

AFP↓, 1,   AR↓, 1,   EGFR↓, 2,   hTERT/TERT↓, 2,   IL6↓, 2,   Ki-67↓, 1,  

Functional Outcomes

AntiCan↑, 3,   AntiDiabetic↑, 1,   AntiTum↑, 1,   cardioP↑, 1,   chemoP↑, 2,   hepatoP↑, 2,   neuroP↑, 1,   OS↑, 1,   TumVol↓, 2,  
Total Targets: 211

Pathway results for Effect on Normal Cells:


Redox & Oxidative Stress

antiOx↑, 6,   Catalase↑, 2,   GPx↑, 2,   GSH↑, 1,   GSR↑, 1,   GSTs↑, 1,   HO-1↑, 1,   lipid-P↓, 3,   NRF2↑, 1,   ROS↓, 5,   SOD↑, 2,  

Metal & Cofactor Biology

IronCh↑, 1,  

Core Metabolism/Glycolysis

ALAT↓, 1,   LDH↓, 1,  

Cell Death

Akt↓, 1,   p‑Akt↓, 1,   MAPK↓, 1,   p38↓, 1,  

Transcription & Epigenetics

Ach↑, 1,  

Proliferation, Differentiation & Cell State

cFos↑, 1,   mTOR↓, 1,  

Migration

AP-1↓, 1,   MMP-10↓, 1,   MMP1↓, 1,   MMP2↓, 2,   MMP9↓, 2,   PKCδ↓, 1,   Rac1↑, 1,   TIMP1↓, 1,   TIMP1↑, 1,   TIMP2↑, 3,   uPA↓, 1,   β-catenin/ZEB1↑, 1,  

Angiogenesis & Vasculature

angioG↓, 1,   VEGF↓, 1,  

Immune & Inflammatory Signaling

COX2↓, 1,   CRP↓, 1,   ICAM-1↓, 1,   IFN-γ↑, 1,   IL1↓, 1,   IL12↓, 1,   IL1β↓, 3,   IL6↓, 2,   Inflam↓, 5,   NF-kB↓, 1,   TLR4↑, 1,   TNF-α↓, 3,  

Synaptic & Neurotransmission

5HT↑, 1,   AChE↓, 2,   BDNF↑, 2,   NGF↑, 1,  

Protein Aggregation

Aβ↓, 1,   NLRP3↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 1,   BioAv↑, 6,   eff↑, 1,  

Clinical Biomarkers

ALAT↓, 1,   ALP↓, 1,   AST↓, 1,   BP↓, 1,   CRP↓, 1,   IL6↓, 2,   LDH↓, 1,  

Functional Outcomes

cardioP↑, 2,   cognitive↑, 2,   hepatoP↑, 2,   memory↑, 2,   neuroP↓, 1,   neuroP↑, 2,   radioP↑, 1,   toxicity↓, 1,  
Total Targets: 71

Scientific Paper Hit Count for: TIMP2, Tissue Inhibitor of Metalloproteinases-2
3 Betulinic acid
3 Lycopene
2 Artemisinin
2 Quercetin
2 Resveratrol
1 Allicin (mainly Garlic)
1 Ashwagandha(Withaferin A)
1 Carvacrol
1 Chrysin
1 EGCG (Epigallocatechin Gallate)
1 Luteolin
1 Magnetic Field Rotating
1 Magnetic Fields
1 Naringin
1 Silymarin (Milk Thistle) silibinin
1 Vitamin C (Ascorbic Acid)
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

Filter Conditions: Pro/AntiFlg:%  IllCat:%  CanType:%  Cells:%  prod#:%  Target#:308  State#:%  Dir#:2
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