Ferroptosis
therapy by catalyzing the Fenton reaction has emerged
as a promising tumor elimination strategy for lung adenocarcinoma
(ADC). However, the unsatisfactory Fenton reaction efficiency, strong
intracellular antioxidant system, and insufficient lung drug accumulation
limits the ferroptosis therapeutic effect. To address these issues,
an inhalable nanoreactor was proposed by spontaneously adsorbing biomimetic
protein corona (PC) composed of matrix metalloproteinase 2 responsive
gelatin and glutamate (Glu) on the surface of cationic nanostructured
lipid carriers (NLC) core loaded with ferrocene (Fc) and fluvastatin.
The prepared Fc-NLC(F)@PC could be nebulized into lung lesions with
2.6 times higher drug accumulation and boost lipid peroxide production
by 3.2 times to enhance ferroptosis therapy. Mechanically, fluvastatin
was proved to inhibit monocarboxylic acid transporter 4 mediated lactate
efflux, inducing tumor acidosis to boost Fc-catalyzing reactive oxygen
species production, while the extracellular elevating Glu concentration
was found to inhibit xCT (system Xc
–)
functions and further collapse the tumor antioxidant system by glutathione
synthesis suppression. Mitochondrial dysfunction and cell membrane
damage were involved in the nanoreactor-driven ferroptotic cell death
process. The enhanced antitumor effects by combination of tumor acidosis
and antioxidant system collapse were confirmed in an orthotopic lung
ADC tumor model. Overall, the proposed nanoreactor highlights the
pulmonary delivery approach for local lung ADC treatment and underscores
the great potential of ferroptosis therapy.
Lung cancer with the highest mortality
poses a great threat to
human health. Ferroptosis therapy has recently been raised as a promising
strategy for lung cancer treatment by boosting the reactive species
(ROS) production and lipid peroxidation (LPO) accumulation intracellularly.
However, the insufficient intracellular ROS level and the unsatisfactory
drug accumulation in lung cancer lesions hamper the efficacy of ferroptosis
therapy. Here, an inhalable biomineralized liposome LDM co-loaded
with dihydroartemisinin (DHA) and pH-responsive calcium phosphate
(CaP) was constructed as a ferroptosis nanoinducer for achieving Ca2+-burst-centered endoplasmic reticulum (ER) stress enhanced
lung cancer ferroptosis therapy. Equipped with excellent nebulization
properties, about 6.80-fold higher lung lesions drug accumulation
than intravenous injection made the proposed inhalable LDM an ideal
nanoplatform for lung cancer treatment. The Fenton-like reaction mediated
by DHA with peroxide bridge structure could contribute to intracellular
ROS production and induce ferroptosis. Assisted by DHA-mediated sarco-/endoplasmic
reticulum calcium ATPase (SERCA) inhibition, the initial Ca2+ burst caused by CaP shell degradation triggered the Ca2+-mediated intense ER stress and subsequently induced mitochondria
dysfunction to further boost ROS accumulation, which strengthens ferroptosis.
The second Ca2+ burst occurred as a result of Ca2+ influx through ferroptotic pores on cell membranes, thus sequentially
constructing the lethal “Ca2+ burst-ER stress-ferroptosis”
cycle. Consequently, the Ca2+-burst-centered ER stress
enhanced ferroptosis process was confirmed as a cell swelling and
cell membrane disruption process driven by notable intracellular ROS
and LPO accumulation. The proposed LDM showed an encouraging lung
retention property and extraordinary antitumor ability in an orthotropic
lung tumor murine model. In conclusion, the constructed ferroptosis
nanoinducer could be a potential tailored nanoplatform for nebulization-based
pulmonary delivery and underscore the application of Ca2+-burst-centered ER stress enhanced lung cancer ferroptosis therapy.
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