Fe-Based Theranostic Agents Respond to the Tumor Microenvironment for MRI-Guided Ferroptosis-/Apoptosis-Inducing Anticancer Therapy

Developing a Selection Framework for Zinc Ion-Based Biomaterial Design: Guided by the Biosafety Assessment of ZIF-8 and ZnO

In recent years, nanomaterials have gained widespread use in the biomedical field, with ZIF-8 and ZnO emerging as promising candidates due to their remarkable performance in osteogenesis, angiogenesis, and antimicrobial therapy. However, before advancing these nanomaterials for clinical applications, it is imperative to evaluate their biocompatibility. In particular, comparing nanomaterials with similar biomedical functions is crucial for identifying the most suitable nanomaterials for further development and market entry. Our study aimed to compare the biocompatibility of nano-ZIF-8 and nano-ZnO under the same conditions. We found that nano-ZIF-8 exhibited lower toxicity both in vitro and in vivo compared to nano-ZnO. To gain insights into the underlying mechanisms responsible for this difference, we conducted further experiments to investigate lysosome damage, mitochondrial change, and the occurrence of ferroptosis. Additionally, we performed transcriptome sequencing to analyze the expression of relevant genes, thereby providing robust validation for our findings. In summary, our study highlighted the importance of evaluating nanomaterials with similar biomedical effects. Through this comparative study, we have not only shed light on the superior biocompatibility of nano-ZIF-8 over nano-ZnO, but also contributed valuable insights and methodological references for future material screening endeavors. Ultimately, our study served as a stepping stone toward the development of safer and more effective nanomaterials for various biomedical applications.

Unlocking ferroptosis in prostate cancer - the road to novel therapies and imaging markers

Ferroptosis is a distinct form of regulated cell death that is predominantly driven by the build-up of intracellular iron and lipid peroxides. Ferroptosis suppression is widely accepted to contribute to the pathogenesis of several tumours including prostate cancer. Results from some studies reported that prostate cancer cells can be highly susceptible to ferroptosis inducers, providing potential for an interesting new avenue of therapeutic intervention for advanced prostate cancer. In this Perspective, we describe novel molecular underpinnings and metabolic drivers of ferroptosis, analyse the functions and mechanisms of ferroptosis in tumours, and highlight prostate cancer-specific susceptibilities to ferroptosis by connecting ferroptosis pathways to the distinctive metabolic reprogramming of prostate cancer cells. Leveraging these novel mechanistic insights could provide innovative therapeutic opportunities in which ferroptosis induction augments the efficacy of currently available prostate cancer treatment regimens, pending the elimination of major bottlenecks for the clinical translation of these treatment combinations, such as the development of clinical-grade inhibitors of the anti-ferroptotic enzymes as well as non-invasive biomarkers of ferroptosis. These biomarkers could be exploited for diagnostic imaging and treatment decision-making.

A pH/GSH dual responsive nanoparticle with relaxivity amplification for magnetic resonance imaging and suppression of tumors and metastases

Engineered magnetic nanoparticles combining diagnosis and therapy functions into one entity hold great potential to rejuvenate cancer treatment; however, they are still constrained by the "always on" signals and unsatisfactory therapeutic effect. Here, we report an intelligent theranostic probe based on Mn₃O₄ tetragonal bipyramids (MnTBs), which simultaneously respond to H⁺ and glutathione (GSH) with high sensitivity and quickly decompose to release Mn²⁺ in mild acidic and reductive intracellular environments. Mn²⁺ binds to the surrounding proteins to achieve a remarkable relaxivity amplification and selectively brighten the tumors. Particularly, this MR signal improvement is also effective in the detection of millimeter-sized liver metastases, with an ultrahigh contrast of 316%. Moreover, Mn²⁺ would trigger chemodynamic therapy (CDT) by exerting the Fenton-like activity to generate ˙OH from H₂O₂. Subsequently, a significant tumor suppression effect can be achieved by the GSH depletion-enhanced CDT. Besides, MnTBs manifest efficient urinary and hepatic excretions with biodegradability and minimal systemic toxicity. A pH/GSH dual responsive nanoprobe that integrates tumor diagnostic and therapeutic activities was developed to provide a new paradigm for precise diagnosis and treatment of tumors and metastases.

Multiple Strikes Achieve Remarkable Tumor-Inhibition Efficiency via Multi-mechanism Combination

Breast cancer treatment has been challenging all the time because cancer cells have multiple signaling pathways; so, breast cancer still remains a threat to the lives and health of many patients. While common single drug therapies inhibit only one pathway, the combination of multiple mechanisms offers the potential to simultaneously suppress multiple targets and pathways to kill cancer cells more effectively. It is reported that autophagy caused by autophagy inducers and apoptosis caused by some chemotherapeutic drugs can promote ferroptosis to some extent; herein, we combined these three pathways and constructed a multifunctional dual-responsive release nanosystem of Rap@mFe₃O₄-DOX-HA that achieved the ferroptosis-autophagy-apoptosis synergistic effect for cancer treatment. Mesoporous Fe₃O₄ (mFe₃O₄) was set as the carrier and can also release Fe ions for ferroptosis, the autophagy inducer rapamycin (Rap) was wrapped in the carrier to trigger autophagy, and the chemotherapeutic drug doxorubicin (DOX) was used as the apoptosis inducer. At the tumor site, the prepared Rap@mFe₃O₄-DOX-HA nanoparticles split and released DOX/Rap in response to H⁺/GSH. From in vivo and in vitro studies, it was found that Rap@mFe₃O₄-DOX-HA nanoparticles effectively inhibited the migration of 4T1 cells, furthermore, they struck cancer cells through multiple pathways and greatly improved the anti-tumor effect. Therefore, the strategy of multi-mechanism combination achieved a therapeutic effect of 1 + 1 > 2.