Magnetic Fields / Fenton Cancer Research Results

MF, Magnetic Fields: Click to Expand ⟱

Features: Therapy

Magnetic Fields can be Static, or pulsed. The most common therapy is a pulsed magnetic field in the uT or mT range.
The main pathways affected are:
Calcium Signaling: -influence the activity of voltage-gated calcium channels.
Oxidative Stress and Reactive Oxygen Species (ROS) Pathways
Heat Shock Proteins (HSPs) and Cellular Stress Responses
Cell Proliferation and Growth Signaling: MAPK/ERK pathway.
Gene Expression and Epigenetic Modifications: NF-κB
Angiogenesis Pathways: VEGF (improving VEGF for normal cells)
PEMF was found to have a 2-fold increase in drug uptake compared to traditional electrochemotherapy in rat melanoma models

Pathways:
- most reports have ROS production increasing in cancer cells , while decreasing in normal cells.
- ROS↑ related: MMP↓(ΔΨm), ER Stress↑, UPR↑, GRP78↑, Ca+2↑, Cyt‑c↑, Caspases↑, DNA damage↑, cl-PARP↑, HSP↓, Prx,
- Raises AntiOxidant defense in Normal Cells: ROS↓, NRF2↑, SOD↑, GSH↑, Catalase↑,
- lowers Inflammation : NF-kB↓, COX2↓, Pro-Inflammatory Cytokines : NLRP3↓, IL-1β↓, TNF-α↓, IL-6↓, IL-8↓
- inhibit Growth/Metastases : TumMeta↓, TumCG↓, VEGF↓(mostly regulated up in normal cells),
- cause Cell cycle arrest : TumCCA↑,
- inhibits Migration/Invasion : TumCMig↓, TumCI↓, TNF-α↓,
- inhibits glycolysis /Warburg Effect and ATP depletion : HIF-1α↓, PKM2↓, GLUT1↓, LDH↓, HK2↓, PFKs↓, PDKs↓, ECAR↓, OXPHOS↓, GRP78↑, Glucose↓, GlucoseCon↓
- inhibits angiogenesis↓ : VEGF↓, HIF-1α↓, Notch↓, FGF↓, PDGF↓, EGFR↓, Integrins↓,
- Others: PI3K↓, AKT↓, STAT↓, Wnt↓, β-catenin↓, ERK↓, JNK, - SREBP (related to cholesterol).
- Synergies: chemo-sensitization, chemoProtective, cytoProtective, RadioSensitizer, RadioProtective, Others(review target notes), Neuroprotective, Hepatoprotective, CardioProtective,

- Selectivity: Cancer Cells vs Normal Cells

Non-Static Magnetic Fields (AC / Pulsed / Oscillating MF)

Rank	Pathway / Axis	Cancer Cells	Normal Cells	TSF	Primary Effect	Notes / Interpretation
1	Reactive oxygen species (ROS)	↑ ROS (P→R); often sustained (G)	↑ ROS (P); ↔/↓ net ROS (R→G)	P, R, G	Upstream redox perturbation	MF perturbs electron/radical dynamics: normal cells often adapt (ROS setpoint ↓), cancer cells less so
2	NRF2 antioxidant response	↔ / insufficient NRF2 induction (R→G)	↑ NRF2 activation (R→G)	R, G	Adaptive redox defense	Explains mixed ROS direction in normal cells (initial ↑ then adaptive ↓)
3	Glutathione (GSH) homeostasis	↓ GSH (R→G)	↔ or transient ↓ (R) with recovery (G)	R, G	Redox buffering capacity	GSH depletion reflects sustained oxidative load; recovery indicates successful adaptation
4	Superoxide dismutase (SOD) / antioxidant enzymes	↔ or inadequate enzyme upshift (G)	↑ SOD/GPx/CAT capacity (G)	G	Longer-term antioxidant remodeling	Often the “endpoint” readout that correlates with ROS-normalization in normal tissue
5	Mitochondrial ETC / respiration	↓ ETC efficiency; ↑ electron leak (P→R)	↔ mild, reversible ETC perturbation (P→R)	P, R	Bioenergetic destabilization	ETC perturbation is a mechanistic bridge between MF exposure and ROS/ΔΨm changes
6	Mitochondrial membrane potential (ΔΨm / MMP)	↓ ΔΨm (R); may progress (G)	↔ preserved or reversible dip (R)	R, G	Mitochondrial dysfunction thresholding	ΔΨm loss typically follows ROS/ETC disruption rather than preceding it
7	Ca²⁺ signaling (VGCC / ER–mitochondria Ca²⁺ flux)	↑ dysregulated Ca²⁺ influx/transfer (P→R); overload may persist (G)	↑ transient Ca²⁺ signaling (P); homeostasis restored (R→G)	P, R, G	Stress signal amplification	Ca²⁺ dysregulation links ROS/ETC perturbation to ER stress and mitochondrial dysfunction (amplifies ΔΨm loss and UPR commitment)
8	Mitochondrial permeability transition pore (MPTP)	↑ MPTP opening propensity (R); sustained opening possible (G)	↔ transient or closed (R→G)	P, R, G	Commitment point for mitochondrial failure	MPTP opening integrates ROS, Ca²⁺ overload, and ΔΨm loss; acts as a threshold event converting reversible stress into irreversible mitochondrial dysfunction
9	ER stress / UPR	↑ ER stress (R); CHOP-commitment possible (G)	↑ adaptive UPR (R); resolves (G)	R, G	Proteostasis stress	Often downstream of ROS + Ca²⁺ handling perturbations
10	DNA damage (oxidative)	↑ damage markers (R→G)	↔ or repaired (G)	R, G	Checkpoint pressure	Generally secondary to ROS; interpret as stress consequence not “direct genotoxicity”
11	LDH / glycolytic flux	↓ glycolytic performance (R→G)	↔ flexible substrate switching (R→G)	R, G	Metabolic vulnerability	Redox imbalance can destabilize high-rate glycolysis in cancer-biased contexts
12	Thioredoxin system (Trx / TrxR)	↓ functional reserve / overload (R→G)	↔ preserved capacity (G)	R, G	Parallel antioxidant system stress	Useful when GSH-only does not explain redox phenotype

Time-Scale Flag: TSF = P / R / G
  P: 0–30 min (physical / electron / radical effects)
  R: 30 min–3 hr (redox signaling & stress response)
  G: >3 hr (gene-regulatory adaptation)

MPTP: opening represents a mitochondrial commitment event integrating ROS and Ca²⁺ stress; sustained opening indicates irreversible bioenergetic failure.

Fenton, Fenton Reaction: Click to Expand ⟱

Source:

Type:

The Fenton reaction is a chemical reaction that involves the catalytic decomposition of hydrogen peroxide (H2O2) by iron ions (Fe2+ or Fe3+). This reaction produces highly reactive oxygen species (ROS), including hydroxyl radicals (·OH) and superoxide anions (O2·-).
Cancer Progression:
Increased oxidative stress from the Fenton reaction can promote cancer cell proliferation, survival, and metastasis. ROS can activate various signaling pathways that support tumor growth and resistance to apoptosis.
Therapeutic Target:
The Fenton reaction has been explored as a potential therapeutic target. Strategies to manipulate iron levels or enhance the production of ROS in cancer cells are being investigated to selectively induce cell death in tumors.

Formula
Fe2+ + H2O2 → Fe3+ + HO• + OH−
Fe3+ + H2O2 → Fe2+ + HOO• + H+
2 H2O2 → HO• + HOO• + H2O net reaction

– The dysregulation of iron metabolism in certain cancers might serve as a biomarker for targeted treatments that employ Fenton reaction-based strategies.
– Researchers are investigating strategies that harness or amplify the Fenton reaction to selectively kill cancer cells.
- With more available iron, the Fenton reaction can be enhanced, resulting in increased production of hydroxyl radicals. Which can lead to cancer cell death.

See the ROS target for more information

Scientific Papers found: Click to Expand⟱

582-

MF,

immuno,

VitC,

Magnetic field boosted ferroptosis-like cell death and responsive MRI using hybrid vesicles for cancer immunotherapy

in-vitro,

Pca,

TRAMP-C1

As shown in Fig. 1a, once AA is released under the MF, ferric ions in IONCs are reduced by AA increasing ferrous ions, which are a stronger inducer for <span class="wphighlight">Fenton</span> reaction compared with ferric ions

in-vivo,

NA,

TRAMP-C1 tumor-bearing mice

Fenton↑, Ferroptosis↑, ROS↑, TumCG↓, Iron↑, GPx4↓,

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 ⓘ

Fenton↑, 1, Ferroptosis↑, 1, GPx4↓, 1, Iron↑, 1, ROS↑, 1,

Cell Death ⓘ

Ferroptosis↑, 1,

Proliferation, Differentiation & Cell State ⓘ

TumCG↓, 1,
Total Targets: 7

Pathway results for Effect on Normal Cells:

Total Targets: 0

Scientific Paper Hit Count for: Fenton, Fenton Reaction

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