doxorubicin / LDH Cancer Research Results

doxoR, doxorubicin: Click to Expand ⟱

Features:

Doxorubicin, (brand name Adriamycin) is a chemotherapy medication used to treat breast cancer, bladder cancer, Kaposi's sarcoma, lymphoma, and acute lymphocytic leukemia. Often used together with other chemotherapy agents. Given by injection into a vein.
Doxorubicin is an anthracycline chemotherapy whose core anticancer activity is driven by DNA intercalation and topoisomerase II poisoning (DNA double-strand break stress), with additional contributions from redox cycling/iron-linked oxidative injury in some contexts. Its major clinical limitations are myelosuppression and cumulative dose–dependent cardiomyopathy, plus severe tissue injury if extravasated (leaks outside the vein).
-Cumulative cardiomyopathy risk is real and dose-dependent; labels note higher risk at higher cumulative doses (often cited around >550 mg/m², with lower limits in higher-risk patients).
-Mechanism split: tumor kill is primarily Topo II + DNA damage, while cardiotoxicity is strongly linked to TOP2β/mitochondrial pathways (redox/iron biology remains discussed, but not the only story).
-Administration hazard: extravasation can cause severe local injury;

Rank	Pathway / Axis	Cancer / Tumor Context	Normal Tissue Context	TSF	Primary Effect	Notes / Interpretation
1	Topoisomerase II poisoning (DNA double-strand break stress)	Topo II–DNA cleavage complexes ↑ → DNA breaks ↑ → apoptosis/senescence ↑ (context)	Also affects normal proliferating tissues (marrow, mucosa)	P, R	Core cytotoxic mechanism	Primary anticancer mechanism: stabilization of Topo II–DNA cleavage complexes blocks repair and drives lethal DNA damage responses.
2	DNA intercalation → replication/transcription disruption	DNA/RNA synthesis ↓; replication stress ↑	Off-target in normal dividing cells	P, R	Replication/transcription blockade	Intercalation contributes to replication fork stress and complements Topo II poisoning.
3	Redox cycling / iron-associated oxidative injury (context-dependent)	ROS / oxidative damage ↑ (reported; model-dependent)	Oxidative injury risk in sensitive tissues (esp. heart) ↑	P, R, G	Stress amplification	Often described as semiquinone redox cycling and iron interactions; the relative importance vs Topo II varies by tissue/model.
4	Cardiotoxicity axis (TOP2β + mitochondrial injury; cumulative-dose dependent)	—	Risk of cardiomyopathy/heart failure ↑ with cumulative exposure	R, G	Major dose-limiting toxicity	Clinically important boxed-warning toxicity; risk increases with cumulative dose (labels cite higher risk above ~550 mg/m²; higher-risk patients often use lower limits).
5	Myelosuppression (bone marrow progenitors)	—	Neutropenia/anemia/thrombocytopenia risk ↑	R, G	Dose-limiting toxicity	Expected on-target effect in rapidly dividing marrow cells; infection risk increases when neutrophils are low.
6	p53 / DNA-damage response programs	DDR signaling ↑; p53 pathway engagement ↑ (context)	DDR activation in normal tissues contributes to toxicity	R, G	Cell fate commitment	Downstream of DNA breaks: checkpoint activation, apoptosis, senescence, or mitotic catastrophe depending on genotype and dose.
7	Immunogenic cell death signals (DAMP exposure; context-dependent)	Potential ICD features ↑ (reported in some systems)	—	G	Immune engagement (conditional)	Anthracyclines are often discussed as capable of immunogenic cell death in certain settings; not universal across regimens.
8	Extravasation tissue injury (local)	—	Severe local tissue damage risk if IV leakage occurs	P, R	Administration hazard	Boxed warning emphasizes severe tissue injury with extravasation; requires strict IV administration controls.
9	Secondary malignancy risk (therapy-related AML/MDS; exposure-dependent)	—	Rare long-term risk signal ↑	—	Late toxicity constraint	Listed in boxed warnings/labels as a potential late effect, especially with combination regimens.
10	Cardioprotection strategy (dexrazoxane; selected settings)	—	Cardiotoxicity risk ↓ (when used appropriately)	R, G	Risk mitigation	Dexrazoxane is used to reduce anthracycline cardiotoxicity; mechanistic literature includes TOP2β-linked protection and other hypotheses.

Time-Scale Flag (TSF): P / R / G

P: 0–30 min (direct DNA/Topo interactions begin rapidly)
R: 30 min–3 hr (acute DNA-damage response + stress signaling)
G: >3 hr (gene programs, apoptosis/senescence, phenotype-level outcomes)

LDH, Lactate Dehydrogenase: Click to Expand ⟱

Source:

Type:

LDH is a general term that refers to the enzyme that catalyzes the interconversion of lactate and pyruvate. LDH is a tetrameric enzyme, meaning it is composed of four subunits.
LDH refers to the enzyme as a whole, while LDHA specifically refers to the M subunit. Elevated LDHA levels are often associated with poor prognosis and aggressive tumor behavior, similar to elevated LDH levels.
leakage of LDH is a well-known indicator of cell membrane integrity and cell viability [35]. LDH leakage results from the breakdown of the plasma membrane and alterations in membrane permeability, and is widely used as a cytotoxicity endpoint.

However, it's worth noting that some studies have shown that LDHA is a more specific and sensitive biomarker for cancer than total LDH, as it is more closely associated with the Warburg effect and cancer metabolism.

Dysregulated LDH activity contributes significantly to cancer development, promoting the Warburg effect (Chen et al., 2007), which involves increased glucose uptake and lactate production, even in the presence of oxygen, to meet the energy demands of rapidly proliferating cancer cells (Warburg and Minami, 1923; Dai et al., 2016b). LDHA overexpression favors pyruvate to lactate conversion, leading to tumor microenvironment acidification and aiding cancer progression and metastasis.

Inhibitors:
Flavonoids, a group of polyphenols abundant in fruit, vegetables, and medicinal plants, function as LDH inhibitors.

LDH is used as a clinical biomarker for Synthetic liver function, nutrition

Tier A — Direct LDH Enzyme Inhibitors (Validated Catalytic Inhibition)

Rank	Compound	Type	LDH Target	Potency Level	Primary Effect	Notes
1	NCI-006	Research drug	LDHA / LDHB	High (in vivo active)	Potent glycolysis suppression	Modern benchmark LDH inhibitor used in metabolic oncology models.
2	(R)-GNE-140	Research drug	LDHA (±LDHB)	High (nM range reported)	Lactate production ↓	Widely used experimental LDH inhibitor.
3	FX11	Research drug	LDHA	High (μM range)	Metabolic crisis in LDHA-dependent tumors	Classic LDHA inhibitor; often increases ROS secondary to metabolic stress.
4	Oxamate	Tool compound	LDH (pyruvate-competitive)	Moderate (mM cellular use)	Reduces lactate flux	Classical LDH inhibitor; requires high concentrations in cells.
5	Gossypol	Natural product derivative	LDHA	Moderate–High	Glycolysis inhibition	Also has other targets; safety considerations apply.
6	Galloflavin	Natural compound	LDH isoforms	Moderate	Lactate production ↓	One of the better-supported “natural-like” LDH inhibitors.

Tier B — Indirect LDH-Axis Modulators (Glycolysis / Lactate Reduction Without Confirmed Direct Catalytic Inhibition)

Rank	Compound	Mechanism Type	LDH Claim Type	Primary Axis	Notes / Caution
1	Lonidamine	MCT/MPC modulation	Lactate axis inhibition	Metabolic transport blockade	Better classified as lactate/pyruvate transport modulator.
2	Stiripentol	Repurposed drug	LDH pathway modulation	Metabolic axis modulation	Emerging oncology interest; primarily neurological drug.
3	Quercetin	Flavonoid	Reported LDH inhibition (mixed evidence)	NF-κB / PI3K modulation	Often LDH-release confusion; direct enzymatic proof limited.
4	Ursolic acid	Triterpenoid	Reported LDH interaction	Warburg modulation	More credible as metabolic signaling modulator.
5	Fisetin	Flavonoid	Docking / indirect reports	Apoptosis / survival signaling	Enzyme inhibition not well validated.
6	Resveratrol	Polyphenol	Indirect glycolysis suppression	AMPK / HIF-1α modulation	Reduces lactate via upstream signaling.
7	Curcumin	Polyphenol	Indirect LDH expression modulation	Inflammation + metabolic signaling	Bioavailability limits translational strength.
8	Berberine	Alkaloid	Indirect metabolic modulation	AMPK activation	Closer to metformin-like metabolic pressure.
9	Honokiol	Lignan	Indirect glycolysis effects	Survival pathway suppression	Not validated as catalytic LDH inhibitor.
10	Silibinin	Flavonolignan	Mixed / indirect reports	Inflammation + metabolic axis	Often misclassified as LDH inhibitor.
11	Kaempferol	Flavonoid	Often LDH-release marker confusion	Glucose transport / signaling	Do not list as direct LDH inhibitor without enzyme data.
12	Oleanolic acid / Limonin / Allicin / Taurine	Natural compounds	Weak / indirect evidence	General metabolic modulation	Should not be categorized as true LDH inhibitors.

Tier A = Direct catalytic LDH inhibition (enzyme-level validation).
Tier B = Indirect lactate reduction or glycolytic modulation without strong catalytic inhibition evidence.
Important: LDH release assays (cell damage marker) are not proof of LDH enzymatic inhibition.

Scientific Papers found: Click to Expand⟱

2534-

M-Blu,

doxoR,

PDT,

Methylene Blue-Mediated Photodynamic Therapy in Combination With Doxorubicin: A Novel Approach in the Treatment of HT-29 Colon Cancer Cells

in-vitro,

CRC,

HT-29

LDH↑, ROS↑,

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 ⓘ

ROS↑, 1,

Core Metabolism/Glycolysis ⓘ

LDH↑, 1,

Clinical Biomarkers ⓘ

LDH↑, 1,
Total Targets: 3

Pathway results for Effect on Normal Cells:

Total Targets: 0

Scientific Paper Hit Count for: LDH, Lactate Dehydrogenase

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#:179  Target#:906  State#:%  Dir#:2
  wNotes=0  sortOrder:rid,rpid