MOFs-based nanoagent enables dual mitochondrial damage in synergistic antitumor therapy via oxidative stress and calcium overload

Wireless discharge of piezoelectric nanogenerator opens voltage-gated ion channels for calcium overload-mediated tumor treatment

Calcium overload-mediated tumor treatment conventionally necessitates calcium-containing drugs. However, these drugs are susceptible to calcium ion leakage during in vivo delivery, potentially causing adverse effects such as hypercalcemia and hypertension. Furthermore, voltage-gated ion channels (VGICs) on the tumor cell membrane stringently regulate calcium ion influx to preserve intracellular calcium homeostasis. To address these issues, a calcium-free piezoelectric nanogenerator, (K, Na) NbO3 (KNN), capable of local and wireless discharge (at a voltage of up to 0.4 mV) into tumors under ultrasound (US) excitation, is designed to open VGICs. Given the significantly higher extracellular calcium ion concentration compared to intracellular levels (approximately 15,000-fold), a substantial influx of calcium ions ensures, leading to intracellular calcium overload. Concurrently, US stimulates KNN to undergo piezoelectric catalysis, converting water into reactive oxygen species (ROS). The synergistic effect of calcium overload and high ROS oxidation induces mitochondrial damage, culminating in tumor elimination. Additionally, the calcium ion influx induces polarization of tumor-associated macrophages from an immunosuppressive M2 phenotype to an immunity-promoting M1 phenotype, thereby enhancing systemic anti-tumor immune responses. This study demonstrates that local electric field within tumors can open VGICs for efficient and safe calcium overload-mediated tumor treatment, showing great potential for clinical translation.

In situ forming AIEgen-alginate hydrogel for remodeling tumor microenvironment to boost FLASH immunoradiotherapy

FLASH radiotherapy, which involves the delivery of an ultra-high radiation dose rate exceeding 40 Gy/s, has emerged as a promising tumor ablation strategy. While this approach generally spares normal tissues, the incomplete killing of tumors may sometimes lead to recurrence due to the immunosuppressive tumor microenvironment (TME). Herein, an aggregation-induced-emission luminogen (AIEgen)-alginate hydrogel was used to sensitize colon cancer via photodynamic therapy (PDT). Flower-like calcium carbonate nanoparticles, doped with an AIEgen termed CQu, were designed and applied as a cocktail with sodium alginate. When exposed to the acidic TME, Ca2+ is released from this structure, resulting in sodium alginate termed FA forming a hydrogel in situ within the TME. This hydrogel also captures high concentrations of CQu in the local TME. Under laser irradiation, the CQu can generate sustained reactive oxygen species (ROS) production, thereby facilitating Ca2+ influx and causing mitochondrial damage. Through a single injection of established FA hydrogel, followed by PDT and FLASH radiotherapy, immunogenic tumor cell death was induced which promoted antitumor immunity, thereby protecting against tumor recurrence while realizing abscopal effect. The results highlight the potential to improve the sensitivity of tumor cells to FLASH radiotherapy through sustained ROS production and Ca2+ overload, thereby yielding optimal immunotherapy outcomes.

Nanotherapeutic strategies exploiting biological traits of cancer stem cells

Cancer stem cells (CSCs) represent a distinct subpopulation of cancer cells that orchestrate cancer initiation, progression, metastasis, and therapeutic resistance. Despite advances in conventional therapies, the persistence of CSCs remains a major obstacle to achieving cancer eradication. Nanomedicine-based approaches have emerged for precise CSC targeting and elimination, offering unique advantages in overcoming the limitations of traditional treatments. This review systematically analyzes recent developments in nanomedicine for CSC-targeted therapy, emphasizing innovative nanomaterial designs addressing CSC-specific challenges. We first provide a detailed examination of CSC biology, focusing on their surface markers, signaling networks, microenvironmental interactions, and metabolic signatures. On this basis, we critically evaluate cutting-edge nanomaterial engineering designed to exploit these CSC traits, including stimuli-responsive nanodrugs, nanocarriers for drug delivery, and multifunctional nanoplatforms capable of generating localized hyperthermia or reactive oxygen species. These sophisticated nanotherapeutic approaches enhance selectivity and efficacy in CSC elimination, potentially circumventing drug resistance and cancer recurrence. Finally, we present an in-depth analysis of current challenges in translating nanomedicine-based CSC-targeted therapies from bench to bedside, offering critical insights into future research directions and clinical implementation. This review aims to provide a comprehensive framework for understanding the intersection of nanomedicine and CSC biology, contributing to more effective cancer treatment modalities.

Calcium peroxide functionalized mesoporous polydopamine nanoparticles triggered calcium overload for synergistic tumor gas/photothermal therapy

Cancer remains a significant global health challenge due to its high mortality rates and the limitations of conventional therapies, which are often associated with severe side effects and limited efficacy. Calcium (Ca2+) overload therapy has emerged as a promising strategy for inducing tumor cell apoptosis. However, existing methods that rely on direct Ca2+ delivery often face limited efficacy due to tumor adaptation mechanisms. In this study, we developed a multifunctional nanoparticle system (MLCH NPs) that synergistically combines Ca2+ overload, gas therapy (GT), and photothermal therapy (PTT). This nanoparticle system was based on mesoporous polydopamine (MPDA) nanoparticles loaded with l-arginine (LA) and calcium peroxide (CaO2), with hyaluronic acid (HA) modification to ensure tumor targeting and protect CaO2 from premature degradation. In the tumor microenvironment (TME), MLCH NPs released Ca2+, hydrogen peroxide (H2O2), and nitric oxide (NO), creating a self-sustaining Ca2+-H2O2-NO cycle that induced oxidative stress, mitochondrial damage, and sustained Ca2+ overload, leading to tumor cell apoptosis. The nanoparticles also harnessed the photothermal effect under 808 nm near-infrared irradiation to amplify NO and Ca2+ release, enhancing oxidative stress and sensitizing tumor cells. Both in vitro and in vivo studies confirmed that MLCH NPs significantly suppressed tumor progression through the synergistic effects of Ca2+ overload, GT, and PTT. This study proposes a novel platform for Ca2+/NO co-delivery and offers a promising approach for enhancing tumor therapies based on Ca2+ overload.

Regulated cell death mechanisms in mitochondria-targeted phototherapy

Phototherapy, comprising photodynamic therapy (PDT) and photothermal therapy (PTT), was first introduced over a century ago and has since evolved into a versatile cancer treatment modality. While numerous studies have explored regulated cell death (RCD) mechanisms induced by phototherapy, a comprehensive synthesis centered on mitochondria-targeted phototherapeutic strategies and agents as mediators of RCD is still lacking. This review provides a systematic and in-depth analysis of recent advances in mitochondria-centered mechanisms driving phototherapy-induced death pathways, including apoptosis, autophagy, pyroptosis, immunogenic cell death, ferroptosis, and cuproptosis. We highlight the critical role of mitochondria as central regulators of these death pathways in response to phototherapeutic interventions. Moreover, we discuss fundamental design strategies for developing precision-targeted phototherapeutic materials to enhance efficacy and minimize off-target effects. Finally, we identify prevailing challenges and propose future research directions to address these hurdles, paving the way for next-generation mitochondria-targeted phototherapy as a highly effective strategy for cancer management.

Thermal responsive nanobombs generating reactive oxygen species for synergistic anticancer therapy

The nano-based therapeutics to induce cellular oxidative damage is considered promising in cancer treatment. Photodynamic therapy (PDT) is a primary antitumor oxidative damage treatment method. However, the hypoxic environment of tumor tissues and the short lifetime of singlet oxygen significantly hampers PDT efficacy. Fortunately, nitric oxide (NO), as a form of gas therapy, can generate more toxic oxidative peroxynitrite ions (ONOO-) with hydrogen peroxide (H2O2), which significantly enhance the efficacy of PDT. In this context, we fabricated a thermally controlled reactive oxygen nanobombs CaO2@LA-ICG@TD (CAI@TD), which can release many reactive oxygen species (ROS) to enhance the synergistic anticancer efficiency under a. The cellular studies revealed that CAI@TD could produce oxygen and H2O2 to heighten the efficacy of PDT and NO and induce necrotic-apoptosis of MDA-MB-231 cells by mitochondria damage, lipid peroxidation, and DNA fragments. Moreover, CAI@TD with 808 nm laser irradiation achieved a significant inhibition on the xenograft tumor growth. This work provides an efficient strategy to produce a high amount of ROS for synergistic anticancer therapy, offering a ray of hope in the fight against cancer.

Superoxide Anion (O2-•) Leading to Pulmonary Toxicity of Metal-Organic Frameworks (MOFs)

Metal-organic frameworks (MOFs) have attracted significant attention for their versatility in therapeutic and diagnostic roles, yet their potential impact on pulmonary toxicity remains largely unexplored. There is an urgent necessity to comprehensively investigate their biological impacts. Herein, we examined the cytotoxicity, oxidative stress, and pulmonary injury after UIO-66, ZIF-8, and MOF-199 stimulation, with a focus on their impact on lung cells and tissue. Crucially, our mechanistic investigations definitively elucidated that the pulmonary toxicity of MOF-199 is primarily driven by the excessive generation of superoxide anion (O2-•). This superoxide-driven ROS cascade subsequently underlies the observed cellular damage, including calcium dysregulation and apoptosis, and instigates the inflammatory response leading to lung tissue injury. Conversely, UIO-66 and ZIF-8 generated the minimal superoxide level. This study provides crucial insights into the safety of MOFs and stresses the need for careful design to optimize both their functionality and biocompatibility for safe biomedical use.

Mitochondrial Reactive Oxygen Species (mROS) Generation and Cancer: Emerging Nanoparticle Therapeutic Approaches

Mitochondrial reactive oxygen species (mROS) are generated as byproducts of mitochondrial oxidative phosphorylation. Changes in mROS levels are involved in tumorigenesis through their effects on cancer genome instability, sustained cancer cell survival, metabolic reprogramming, and tumor metastasis. Recent advances in nanotechnology offer a promising approach for precise regulation of mROS by either enhancing or depleting mROS generation. This review examines the association between dysregulated mROS levels and key cancer hallmarks. We also discuss the potential applications of mROS-targeted nanoparticles that artificially manipulate ROS levels in the mitochondria to achieve precise delivery of antitumor drugs.

Amplifying Ca2+ overload by engineered biomaterials for synergistic cancer therapy

Ca2+ overload is one of the most widely causes of inducing apoptosis, pyroptosis, immunogenic cell death, autophagy, paraptosis, necroptosis, and calcification of tumor cells, and has become the most valuable therapeutic strategy in the field of cancer treatment. Nevertheless, several challenges remain in translating Ca2+ overload-mediated therapeutic strategies into clinical applications, such as the precise control of Ca2+ dynamics, specificity of Ca2+ homeostasis dysregulation, as well as comprehensive mechanisms of Ca2+ regulation. Given this, we comprehensively reviewed the Ca2+-driven intracellular signaling pathways and the application of Ca2+-based biomaterials (such as CaCO3-, CaP-, CaO2-, CaSi-, CaF2-, and CaH2-) in mediating cancer diagnosis, treatment, and immunotherapy. Meanwhile, the latest researches on Ca2+ overload-mediated therapeutic strategies, as well as those combined with multiple-model therapies in mediating cancer immunotherapy are further highlighted. More importantly, the critical challenges and the future prospects of the Ca2+ overload-mediated therapeutic strategies are also discussed. By consolidating recent findings and identifying future research directions, this review aimed to advance the field of oncology therapy and contribute to the development of more effective and targeted treatment modalities.

Fullerenols hijack lysosomes to disrupt inter-organellar crosstalk and block autophagy pre-activated by mTOR inhibitors for cancer cell PANoptosis

Subcellular inter-organellar crosstalk among lysosome, endoplasmic reticulum (ER), and mitochondrion is crucial for cancer cell survival and is a promising target in cancer treatment; however, efficiently disrupting these interactive networks is challenging. Herein, a communication interception strategy is presented, which specifically disrupts inter-organellar crosstalk by lysosomal contents leakage along with their trajectory and pre-activates autophagic flux to augment the lysosome-associated autophagy blocking for preventing the self-repair of this subcellular disorder. Briefly, fullerenols containing multiple hydroxyl groups (MF) tear the lysosomal phospholipid membrane through direct interaction, which causes lysosomal contents (calcium ions and cathepsins) to leak into the cytoplasm, subsequently leading to endoplasmic reticulum stress and mitochondrial dysfunction with redox imbalance and metabolic reprogramming. mTOR inhibitors activate and amplify autophagy, then impaired lysosomes prevent their fusion with autophagosome, and thus autophagy is paralyzed along with autolysosome accumulation. Consequently, the cellular homeostasis is compromised by destroyed inter-organellar networks without self-repair by autophagy, thereby triggering PANoptotic processes and leading to a remarkable anti-tumor therapeutic efficacy in vitro and in vivo. This strategy demonstrates the selective cytotoxicity of non-toxic nanomaterials that interfere with subcellular inter-organellar crosstalk, offering a novel method for designing tumor therapies.

A Nanotherapeutic Agent for Synergistic Tumor Therapy: Co-Activation of Photochemical-Biological Effects

Single-mode photodynamic therapy (PDT) based on photochemical reactions is limited by the tumor microenvironment, which reduces the ablation efficiency for solid tumors. Making it vital to seek ways to improve the tumor therapeutic effect. Based on this, we propose a dual-mode intelligent nanotherapeutic system (HAP@BMPns) based on photochemical-biological effects. HAP@BMPns is composed of an acid-responsive high-calcium biomimetic nanomaterial (HAP) and photosensitizer (BMP), which can spontaneously activate photochemical (Type-I PDT) and biological effects for synergistic cancer therapy. HAP@BMPns breaks down upon entering tumor cells under acidic conditions, releasing a large amount of Ca2+ and BMP. Triggering intracellular Ca2+ overload, which induces mitochondrial damage, leading to apoptosis. Synchronously, Type-I PDT of BMP under two-photon (800 nm) laser irradiation becomes activated, resulting in enhanced destruction of tumor cells by the photochemical effect. Cell studies have indicated that HAP@BMPns (41.6 μg/mL) exhibits a strong inhibitory efficiency on tumor cells growth, with low (22.4 %) survival rate. However, the individual components, i. e. BMP (5.0 μM) and HAP (41.6 μg/mL) display low inhibitory efficiency with high survival rates (55.9 % and 63.0 % respectively). Therefore, this dual-mode synergistic treatment strategy using acid-triggered photochemical-biological effects significantly enhances the ablation of solid tumors, realizing the synergistic effect. We hope that this design strategy can provide guidance for the design and development of a tumor therapeutic platform.

Improving ferroptosis-mediated immunotherapy for colorectal cancer through lysosome-targeted photodynamic therapy

Lysosomes is emerging as a promising therapeutic target for improving immunotherapy, which dysfunction would trigger lysosomal membrane permeabilization increase and subsequent leakage of reduced iron, which contributed to ferroptosis through cell-intrinsic Fenton chemistry. However, the integrity of lysosomal membranes is not susceptible to disrupt, owing to the presence of several Endo-lysosomal damage-response mechanisms. Herein, we developed a lysosome-targeted photosensitizer (TLA), which possessed robust light stability, good bio-compatibility, and high photodynamic therapy (PDT) effect. Upon internalized by cancer cells, TLA was specifically accumulated in lysosome, and which would destroy the integrity of lysosomal membranes and inhibit protective autophagy upon exposure to light irradiation. Subsequently, the cancer cells were suffered from ferroptosis through triggering cell-intrinsic Fenton chemistry and mitochondrial dysfunction, which would release damage-associated molecular pattern molecules (DAMPs) to induce immunogenic cell death and remodel immunosuppressive tumor microenvironment. Notably, combined with PD-L1 antibody and TLA could greatly potentiate the immune response and exhibit highest anti-tumor effects. In summary, this novel lysosome-targeted photosensitizer could serve as a promising strategy for the treatment of colorectal cancer.

Intracellular dehydrogenation catalysis leads to reductive stress and immunosuppression

Imbalanced redox homeostasis, involving either oxidative stress or reductive stress, can profoundly impact cellular functions, contributing to various diseases. While the implications of oxidative stress in the adverse effects of nanoparticles have been extensively studied, our comprehension of reductive stress within the context of nano-redox system interactions remains limited. Here we illuminate a domino effect initiated by the dehydrogenase-like activity of transition metal borides. Specifically, seven transition metal borides were identified to emulate the enzymatic activity of natural dehydrogenases, resulting in heightened levels of reductive constituents within critical biological redox pairs in cells. Mass cytometry analysis provides compelling evidence that reductive stress initiates an immunosuppressive environment within lung tissues, promoting the metastasis of breast cancer cells to the lungs. In summary, our study unveils the chemical basis of nano-induced reductive stress and establishes a mechanistic axis that interlinks dehydrogenase-like activity, reductive stress, immunosuppression and tumour metastasis.

Programmed enhancement of endogenous iron-mediated lysosomal membrane permeabilization for tumor ferroptosis/pyroptosis dual-induction

Ferroptosis and pyroptosis, as emerging regulated forms of cell death capable of overcoming apoptotic resistance, demonstrate promising potential in tumor therapy. Given that iron manipulation and reactive oxygen species elevation serve as common stimuli for both processes, inducing lysosomal membrane permeabilization (LMP) with ensuing release of lysosomal contents (including iron ions and cathepsins) is anticipated to realize dual induction of ferroptosis/pyroptosis. Herein, we report a folic acid and croconaine molecule-functionalized upconversion nanoparticle (UCNP-Cro/FA) that is able to mobilize intracellular stores of endogenous iron and spatiotemporally control the lysosome-intrinsic Fenton chemistry, thereby triggering LMP-associated cell death. The process of endogenous iron mobilization occurs through two key steps: Cro-mediated coordination of abundant Fe3+ ions within lysosomes, followed by UV-emitting upconversion core-mediated photoreduction, resulting in Fe2+ ions release. Both in vitro and in vivo experiments show that UCNP-Cro/FA + NIR treatment effectively boost LMP by endogenous iron-mediated •OH production, ultimately triggering irreversible tumor cell death via ferroptosis and Caspase-1/GSDMD-dependent pyroptosis pathways. Moreover, this process potentiates tumor immunogenicity, holding promise for tumor immunotherapy. Overall, this work proposes a feasible tumor therapy strategy that integrates ferroptosis and pyroptosis through the efficient application and activation of endogenous iron.

Biocompatible nanozyme with dual catalytic activities for high-performance multimodality therapy against glioblastoma

Nanozymes based on metals have been regarded as a promising candidate in the metabolic reprogramming of low-survival, refractory glioblastoma multiforme (GBM). However, due to size limitations, nanozymes struggle to balance catalytic activity with the ability to cross the blood-brain barrier (BBB), limiting their efficiency in GBM therapy. Herein, we establish a hybrid nanocluster, AuMn NCs, by cross-linking ultrasmall nano-gold (Au) and manganese oxide (MnO2), which overcomes the size requirement conflict for integrating catalytic activities, long-period circulation, photothermal effect, glucose consumption, and chemodynamic effect for multimodality treatment against GBM. After administered intravenously, the overall large-size AuMn NCs can escape kidney filtration and cross the BBB for GBM accumulation. Then the individual ultrasmall nano-MnO2components effectively catalyze H2O2degradation as catalase to produce oxygen, which is utilized by individual ultrasmall nano-Au components to consume glucose as glucose oxidase for starvation therapy. The H2O2generated during Au-catalyzed glucose consumption further facilitates MnO2catalytic activity. Such positive feedback overwhelmingly intervenes in the glucose metabolism of GBM. Concurrently, clustered Au-induced photothermal effect and released Mn2+-induced chemodynamic effect further contribute to eliminating GBM cells. The versatile clustered nanozyme offers a feasible strategy for the multimodality intervention of GBM.

Bidirectional amplification of oxidative stress through the mitochondria-targeted Co-Delivery of nanogolds and chlorin e6 Using ROS-responsive organosilica nanocarriers

Bidirectional amplification of oxidative stress within the mitochondria is essential to enhance photodynamic therapy (PDT), and efficient co-delivery of reducing agents and reactive oxygen species (ROS)-generating agents is critical for achieving this with minimal side effects. However, the absence of an effective platform for mitochondria-targeted co-delivery and spatially controlled tumor-specific therapy limits the potential applicability of this strategy. In this study, we developed an ROS-sensitive organosilica nanocarrier, encapsulating nanogold and introducing chlorin e6 (Ce6) and triphenylphosphine (TPP) through a one-pot sol-gel process. Following TPP-mediated mitochondria-targeted delivery, ROS generated by Ce6 under near-infrared (NIR) irradiation not only damaged the mitochondria but also disrupted the nanoparticles within the tumor, leading to the release of nanogold. These ultra-small nanogolds, due to their high surface area, exhibited enhanced glutathione scavenging capacity, which, in combination with ROS, synergistically amplified oxidative stress to overcome the high resistance of tumor cells. Both in vitro and in vivo experiments confirmed the effectiveness of this strategy, demonstrating efficient co-delivery, controlled drug release, spatially targeted oxidative stress amplification, and synergistic antitumor effects. Thus, we present a facile platform for the spatially controlled bidirectional amplification of oxidative stress with minimal side effects. STATEMENT OF SIGNIFICANCE: Mitochondrial oxidative stress involves both ROS generation and GSH depletion, indicating that bidirectional amplification is required for mitochondria-targeted antitumor therapy. However, most of existing strategies just focus on ROS generation, which limits the amplification level of oxidative stress. Thus, the mitochondria-targeted co-delivery of photodynamic agent and GSH scavenging agent is an effective approach to address this limitation. Besides, the lack of facile nanoplatform also hinders the application of strategies aimed at bidirectionally amplifying oxidative stress. In this study, we developed a facile nanoplatform for mitochondria-targeted co-delivery of the photodynamic agent Chlorin e6 and GSH scavenging agent nanogold using a ROS-responsive organosilica nanocarrier. This approach successfully achieved bidirectional amplification of oxidative stress, resulting in a synergistic antitumor effect with minimal side effects.

Renal-clearable and tumor-retained nanodots overcoming metabolic reprogramming to boost mitochondrial-targeted photodynamic therapy in triple-negative breast cancer

BACKGROUND

Targeting tumor metabolism reprogramming has demonstrated a synergistic antitumor effect in photodynamic therapy of triple-negative breast cancer (TNBC). However, such a combination therapeutic regimen has encountered challenges, such as limited photosensitizer bioavailability and severe drug toxicity.

METHODS AND RESULTS

Herein, ultrasmall metal-organic frameworks (MOFs) nanodots (MSPC) that encapsulate metabolism inhibitors and mitochondria-targeted photosensitizers are designed and fabricated for synergistic photodynamic therapy (PDT) of TNBC. The MSPC exhibits an acidic-sensitive drug release, leading to glutathione depletion and mitochondrial respiration suppression. Significantly, MSPC substantially reduces intracellular adenosine triphosphate (ATP) levels by simultaneously disrupting oxidative phosphorylation and impeding aerobic glycolysis. Therefore, the glutathione depletion combined with metabolism inhibitor increases oxidative stress, which improves the efficacy of mitochondria-targeted PDT. Additionally, the increased retention of photosensitizers within tumors, facilitated by aggregation-enhanced retention (AER) effect, extends the time window for long-term fluorescence/photoacoustic imaging-guided PDT of TNBC. MSPC-sensitized PDT significantly suppresses tumor growth with a single-dose injection and repeatable PDT.

CONCLUSIONS

In summary, these renal-clearable and aggregation-enhanced tumor-retained nanodots indicate the feasibility of overcoming resistance to reactive oxygen species induced by metabolic reprogramming, thus holding significant implications for boosting PDT of TNBC.

Engineering probiotic biohydrogen micro-factories to initiate reductive stress for boosting tumor vulnerability

Disruption of redox homeostasis profoundly affects cellular metabolism and activities. While oxidative stress is extensively studied in cancer therapies, research on reductive stress remains in its infancy. Molecular hydrogen (H2), a well-known antioxidant, holds significant potential to induce reductive stress due to its strong antioxidative properties, making it a promising candidate for cancer therapy. However, it remains a major challenge to develop a sustainable H2 delivery system in vivo. Herein, we designed a micro-factory by engineering a gel-based microcapsule that encapsulates Enterobacter aerogenes, a.k.a. probiotic biohydrogen microcapsules (PBMCs), enabling the sustained H2 generation within tumor microenvironment. Notably, PBMCs effectively suppressed the proliferation of eight tumor cell lines as well as drug-resistant cancer cells. The prolonged H2 release from PBMCs induced reductive stress, as evidenced by a significant increase in the GSH/GSSG ratio in 4T1 cells. Moreover, PBMCs displayed significant antitumor effects in breast, melanoma and liver cancer models. The inhibition of PI3K-AKT pathway and the activation of MAPK pathway were identified as key mechanisms responsible for inducing tumor cell cycle arrest and apoptosis. The PBMCs also exhibited synergistic effects in combination with chemotherapeutics, resulting in robust inhibitions of preinvasive carcinoma growth and commonly associated pulmonary metastasis. Overall, our study introduces an innovative strategy to manipulate reductive stress in the tumor microenvironment through in situ H2 generation, thereby enhancing tumor vulnerability.

Extracellular vesicles-hitchhiking boosts the deep penetration of drugs to amplify anti-tumor efficacy

Developing drug delivery systems capable of achieving deep tumor penetration is a challenging task, yet there is a significant demand for such systems in cancer treatment. Hitchhiking on tumor-derived extracellular vesicles (EVs) represents a promising strategy for enhancing drug penetration into tumors. However, the limited drug assembly on EVs restricts its further application. Here, we present a novel approach to efficiently attach antitumor drugs to EVs using an engineered cell membrane-based vector. This vector includes the AS1411 aptamer for tumor-specific targeting, the vesicular stomatitis virus glycoprotein (VSV-G) for tumor cell membrane fusion, and a photosensitizer as the therapeutic agent while ensuring optimal drug encapsulation and stability. Upon injection, photosensitizers are firstly transferred to the tumor cell membrane and subsequently piggybacked onto EVs with the inherent secretion process. By hitchhiking with EVs, photosensitizers can be transferred layer by layer deep into the solid tumors. The results suggest that this EVs-hitchhiking strategy enables photosensitizers to penetrate deeply into tumor tissue, thereby enhancing the efficacy of phototherapy. This study offers broad application prospects for delivering drugs deeply into tumor tissues.

Recent research progress on metal ions and metal-based nanomaterials in tumor therapy

Tumors, as a disease that seriously threatens human health, have always been a major challenge in the field of medicine. Currently, the main methods of tumor treatment include surgery, radiotherapy, chemotherapy, etc., but these traditional treatment methods often have certain limitations. In addition, tumor recurrence and metastasis are also difficult problems faced in clinical treatment. In this context, the importance of metal-based nanomaterials in tumor therapy is increasingly highlighted. Metal-based nanomaterials possess unique physical, chemical, and biological properties, providing new ideas and methods for tumor treatment. Metal-based nanomaterials can achieve targeted therapy for tumors through various mechanisms, reducing damage to normal tissues; they can also serve as drug carriers, improving the stability and bioavailability of drugs; at the same time, some metal-based nanomaterials also have photothermal, photodynamic, and other characteristics, which can be used for phototherapy of tumors. This review examines the latest advances in the application of metal-based nanomaterials in tumor therapy within past 5 years, and presents prospective insights into the future applications.

An ionic liquid-based delivery system of small interfering RNA targeting Bcl-2 for melanoma therapy

Melanoma, characterized by rapid tumour progression and a strong tendency to metastasize, poses significant challenges in clinical treatment. Given the vital role of B-cell lymphoma 2 (Bcl-2) protein overexpression in inhibiting apoptosis in tumour cells, the suppression of Bcl-2 has emerged as a promising anticancer therapy. Here, we have developed a straightforward and effective delivery system that combines small interfering RNA (siRNA) targeting Bcl-2 (siBcl-2) with ionic liquids (ILs) for treating melanoma. The unique properties of ILs including structural tunability, inherent charge, and chemical stability have garnered significant attention in the biomedical fields; however, their application in siRNA delivery remains nascent. Rather than the weak function of free siBcl-2, our delivery system (1-hexyl-3-methylimidazolium-siBcl-2, designated as C6-siBcl-2) demonstrated an outstanding capacity to improve the cellular uptake and lysosomal escape, resulting in robust apoptosis and cytotoxicity in melanoma cells. In addition to exhibiting superior gene silencing activity in vitro, such events were also evident in mice bearing melanoma tumours. In particular, this IL-based delivery system showed advantages in suppressing tumour growth, preventing metastasis, and enhancing the survival time of mice with melanoma tumours. Therefore, our study offered a novel and powerful nanoplatform that integrated ILs and RNA interference therapy, presenting new strategies for cancer treatment.

Molecular Photoswitching Unlocks Glucose Oxidase for Synergistically Reinforcing Fenton Reactions for Antitumor Chemodynamic Therapy

We have developed a new type of nanoparticles with potent antitumor activity photoactivatable via the combination of molecular photoswitching of spiropyran (SP) and enzymatic reaction of glucose oxidase (GOx). As two key processes involved therein, Fe(III)-to-Fe(II) photoreduction in Fe(III) metal-organic frameworks (MOFs) brings about the release of free Fe2+/Fe3+ while the photoswitching of SP to merocyanine (MC) unlocks the enzymatic activity of GOx that was pre-passivated by SP. The release of free Fe3+ boosts its hydrolysis and therefore enables the acidification of microenvironment, which is further reinforced by one of the products of the GOx-mediated glucose oxidation reaction, gluconic acid (GlcA). Based on the generation of Fe2+ and acidic milieu together with another product of the oxidation reaction, hydrogen peroxide (H2O2), these two processes jointly present triple enabling factors for generating lethal hydroxyl radicals (⋅OH) species via Fenton reactions and therefore oxidative stress capable of inhibiting tumor. The antitumor potency of such nanoparticle is verified in tumor-bearing model mice in vivo, proclaiming its potential as a potent and safe agent based on the unique mechanism of optically manipulating enzyme activity for synergistic antitumor therapeutics with high spatial precision, enhanced efficacy and minimized side effects.

Recent advances in ferrocene-based nanomedicines for enhanced chemodynamic therapy

Malignant tumors have been a serious threat to human health with their increasing incidence. Difficulties with conventional treatments are toxicity, drug resistance, and recurrence. For this reason, non-invasive treatment modalities such as photothermal therapy (PTT), photodynamic therapy (PDT), chemodynamic therapy (CDT), and others have received much attention. Among them, Ferrocene (Fc)-based nanomedicines for enhanced Chemodynamic Therapy (ECDT) is a new therapeutic strategy based on the Fenton reaction. Based on ferrocene's good biocompatibility, potentiation in medicinal chemistry, and good stability of divalent iron ions, scientists are increasingly using it as a Fenton's iron donor for tumor therapy. Such ferrocene-based ECDT nanoplatforms have shown remarkable promise for clinical applications and have significantly increased the efficacy of CDT treatment. Ferrocene-based nanomedicines exhibit exceptional consistency owing to their low toxicity, high stability, enhanced bioavailability, and a multitude of advantages over conventional approaches to cancer treatment. As a consequence, a number of tactics have been investigated in recent years to raise the effectiveness of ferrocene-based ECDT. In this review, we detail the different forms and strategies used to enhance Ferrocene-based ECDT efficiency.

Advances in nanotherapeutics for tumor treatment by targeting calcium overload

Traditional antitumor strategies are facing challenges such as low therapeutic efficacy and high side effects, highlighting the significance of developing non-toxic or low-toxic alternative therapies. As a second messenger, calcium ion (Ca2+) plays an important role in cellular metabolism and communication. However, persistent Ca2+ overload leads to mitochondrial structural and functional dysfunction and ultimately induced apoptosis. Therefore, an antitumor strategy based on calcium overload is a promising alternative. Here, we first reviewed the classification of calcium-based nanoparticles (NPs) for exogenous Ca2+ overload, including calcium carbonate (CaCO3), calcium phosphate (CaP), calcium peroxide (CaO2), and hydroxyapatite (HA), calcium hydroxide, etc. Next, the current endogenous Ca2+ overload strategies were summarized, including regulation of Ca2+ channels, destruction of membrane integrity, induction of abnormal intracellular acidity and oxidative stress. Due to the specificity of the tumor microenvironment, it is difficult to completely suppress tumor development with monotherapy. Therefore, we reviewed the progress based on mitochondrial Ca2+ overload, which improved the treatment efficiency by combining photothermal therapy (PTT), photodynamic therapy (PDT), chemodynamic therapy (CDT), sonodynamic therapy (SDT), immunogenic cell death (ICD) and gas therapy. We further explored in detail the advantages and promising new targets of this combination antitumor strategies to better address future opportunities and challenges.

Photo-Activated Oxidative Stress Amplifier: A Strategy for Targeting Glutathione Metabolism and Enhancing ROS-Mediated Therapy in Triple-Negative Breast Cancer Treatment

Amplifying oxidative stress within tumor cells can effectively inhibit the growth and metastasis of triple-negative breast cancer (TNBC). Therefore, the development of innovative nanomedicines that can effectively disrupt the redox balance represents a promising yet challenging therapeutic strategy for TNBC. In this study, an oxidative stress amplifier, denoted as PBCH, comprising PdAg mesoporous nanozyme and a CaP mineralized layer, loaded with GSH inhibitor L-buthionine sulfoximine (BSO), and further surface-modified with hyaluronic acid that can target CD44, is introduced. In the acidic tumor microenvironment, Ca2+ is initially released, thereby leading to mitochondrial dysfunction and eventually triggering apoptosis. Additionally, BSO suppresses the synthesis of intracellular reduced GSH and further amplifies the level of oxidative stress in cancer cells. Furthermore, PdAg nanozyme can be activated by near-infrared light to induce photothermal and photodynamic effects, causing a burst of ROS and simultaneously promoting cell apoptosis via provoking immunogenic cell death. The high-performance therapeutic effects of PBCH, based on the synergistic effect of aforementioned multiple oxidative damage and photothermal ablation, are validated in TNBC cells and animal models, declaring its potential as a safe and effective anti-tumor agent. The proposed approach offers new perspectives for precise and efficient treatment of TNBC.

Stress survival and longevity of Caenorhabditis elegans lacking NCS-1

Although dysfunctional Ca2+ signaling can trigger biochemical reactions that lead to cell death, the role of calcium-binding proteins (CBPs) in this process is still a topic of debate. Neuronal calcium sensor 1 (NCS-1) is a CBP that is highly conserved and has been shown to increase cell survival against various types of injuries. As such, we hypothesized that NCS-1 could also be a stress-responsive protein with potential effects on survival and longevity. To explore this possibility, we conducted experiments to examine how Caenorhabditis elegans ncs-1 mutant nematodes fared under three different stress conditions: hyperosmotic, thermal, and chemical oxidant challenges. Our results showed that while the lack of NCS-1 had no effect on survival responses to hyperosmotic and thermal stresses, ncs-1 worms demonstrated remarkable resistance to the oxidant paraquat in a dose-dependent manner. Based on these findings, we conclude that C. elegans may employ adaptive mechanisms in the absence of NCS-1 to survive specific oxidative stress stimuli.

Salidroside rescues hypoxic cardiomyocytes by regulating the EGLN1/HIF‑1α pathway

Myocardial infarction is characterized by oxygen deficiency caused by arterial flow restriction. Salidroside (SAL) protects against myocardial damage via antioxidant production and inhibition of apoptosis. The present study aimed to investigate potential rescue mechanism of SAL on hypoxic cardiomyocytes. H9C2 cardiomyocytes were divided into normoxia, hypoxia and hypoxia + SAL groups. The inhibitory rate of hypoxia and the optimal concentration and rescue effect of SAL were determined using Cell Counting Kit-8 assay and flow cytometry. Ca2+ concentration following hypoxia treatment and SAL intervention were detected by Fluo-4/acetoxymethyl. Tandem mass tag (TMT) proteomics was used to analyze the differential expression of hypoxia-associated proteins among the three groups. SAL exerted a protective effect on hypoxia-injured cardiomyocytes by enhancing aerobic metabolism during hypoxia and rescuing cardiomyocytes from hypoxic damage. SAL promoted cell proliferation, decreased apoptosis and increased Ca2+ levels in cell membranes of hypoxic cardiomyocytes. TMT proteomics results showed that the expression levels of intracellular hypoxia inducible factor-1 (HIF)-1α and Egl-9 family HIF 1 (EGLN1) in H9C2 cells were elevated under hypoxic conditions. However, SAL significantly decreased expression levels of HIF-1α and EGLN1. SAL inhibited mitochondrial calcium overload in hypoxic cardiomyocytes and attenuated expression of hypoxia-associated factors. SAL exerted its rescue effect on hypoxic cardiomyocytes through the EGLN1/HIF-1α pathway, thereby suppressing cardiomyocyte apoptosis, improving mitochondrial energy metabolism efficiency and rescuing cardiomyocytes from hypoxic injury.

A strategy of "adding fuel to the flames" enables a self-accelerating cycle of ferroptosis-cuproptosis for potent antitumor therapy

Cuproptosis in antitumor therapy faces challenges from copper homeostasis efflux mechanisms and high glutathione (GSH) levels in tumor cells, hindering copper accumulation and treatment efficacy. Herein, we propose a strategy of "adding fuel to the flames" for potent antitumor therapy through a self-accelerating cycle of ferroptosis-cuproptosis. Disulfiram (DSF) loaded hollow mesoporous copper-iron sulfide (HMCIS) nanoparticle with conjugation of polyethylene glycol (PEG) and folic acid (FA) (i.e., DSF@HMCIS-PEG-FA) was developed to swiftly release DSF, H2S, Cu2+, and Fe2+ in the acidic tumor microenvironment (TME). The hydrogen peroxide (H2O2) levels and acidity within tumor cells enhanced by the released H2S induce acceleration of Fenton (Fe2+) and Fenton-like (Cu2+) reactions, enabling the powerful tumor ferroptosis efficacy. The released DSF acts as a role of "fuel", intensifying catalytic effect ("flame") in tumor cells through the sustainable Fenton chemistry (i.e., "add fuel to the flames"). Robust ferroptosis in tumor cells is characterized by serious mitochondrial damage and GSH depletion, leading to excess intracellular copper that triggers cuproptosis. Cuproptosis disrupts mitochondria, compromises iron-sulfur (Fe-S) proteins, and elevates intracellular oxidative stress by releasing free Fe3+. These interconnected processes form a self-accelerating cycle of ferroptosis-cuproptosis with potent antitumor capabilities, as validated in both cancer cells and tumor-bearing mice.

Folic acid and ferritin functionalized reduced Iron-based metal-organic frameworks for anticancer therapy

Anticancer chemotherapies damage normal tissues, and various drug carriers are under consideration to address this issue. Metal-organic frameworks (MOFs) are promising due to their drug-carrying capacity and tunable properties. Target-inspired surface functionalization may further magnify their potential. In this study, we aim to investigate the anticancer activity of reduced iron-based MOFs (RMOFs) functionalized with ferritin and folic acid and loaded with doxorubicin. Successful synthesis and functionalization are confirmed by electron microscopes, Fourier transform infrared spectroscopy and X-ray diffraction. Anticancer activity is evaluated in different tumor cell lines at various doses. Results indicate that the folic acid functionalized and Dox loaded MOF (FADMOF) showed maximum anticancer potential, leaving only 6 % of 4 T1 cells alive at the highest dose. Ferritin and combo MOFs followed closely, while the plain RMOF lagged behind. Furthermore, in HeLa cells, the RMOF showed the best cytotoxicity, reducing cell viability to a mere 30 % at the highest dose. Similarly, in MCF7 cells, theRMOF) showed the best cytotoxicity, reducing cell viability in a dose-dependent manner and to a mere 25 % at the highest dose. Taken together, this study shows that functionalized MOFs have promising anticancer potential across various cancer cell lines. However, loading with doxorubicin reduces their cytotoxicity.

Nanomaterial-based regulation of redox metabolism for enhancing cancer therapy

Altered redox metabolism is one of the hallmarks of tumor cells, which not only contributes to tumor proliferation, metastasis, and immune evasion, but also has great relevance to therapeutic resistance. Therefore, regulation of redox metabolism of tumor cells has been proposed as an attractive therapeutic strategy to inhibit tumor growth and reverse therapeutic resistance. In this respect, nanomedicines have exhibited significant therapeutic advantages as intensively reported in recent studies. In this review, we would like to summarize the latest advances in nanomaterial-assisted strategies for redox metabolic regulation therapy, with a focus on the regulation of redox metabolism-related metabolite levels, enzyme activity, and signaling pathways. In the end, future expectations and challenges of such emerging strategies have been discussed, hoping to enlighten and promote their further development for meeting the various demands of advanced cancer therapies. It is highly expected that these therapeutic strategies based on redox metabolism regulation will play a more important role in the field of nanomedicine.

Advances in research on the relationship between mitochondrial function and colorectal cancer: a bibliometric study from 2013 to 2023

The study provides a thorough examination of literature from 2013 to 2023, delving into the intricate relationship between mitochondrial function and colorectal cancer (CRC). It offers a concise overview of the current landscape and emerging trends in this rapidly evolving research area. The findings indicate a consistent rise in annual publications, reflecting growing interest and significant potential in the field. China emerges as the leading contributor, followed by the United States and India. However, despite China's dominance in output, its average citation rate is lower than that of the US, which leads in citations per publication, highlighting a noticeable disparity. In the realm of research institutions, Shanghai Jiao Tong University and China Medical University are identified as major contributors, yet the potential for inter-institutional collaboration remains largely untapped, suggesting avenues for future synergy. Internationally, China-US collaborations are particularly robust, fostering cross-border knowledge exchange. Hyun Jin Won and Li Wei are recognized as prolific authors, while Ahmedin Jemal is an influential co-cited scholar, noted for his seminal contributions. Keyword analysis reveals research focus areas, such as the complex CRC tumor microenvironment, molecular mechanisms of oxidative stress, and key multidrug resistance pathways. It also highlights the promising potential of mitochondria-targeted therapies and nanomolecular technologies in clinical practice, signaling their growing significance in addressing complex health challenges. The study underscores the imperative to validate complex mitochondrial mechanisms and signaling pathways in CRC, with a particular emphasis on translating these insights into drug targets for clinical trials. Advancing this research is expected to refine and enhance CRC treatment strategies. Additionally, it highlights the urgency of validating mitochondrial complexities in CRC, advocating for collaborative efforts to link these mechanisms with tailored therapeutic interventions for clinical testing. This integrated approach promises significant advancements in developing effective, targeted CRC treatments, ultimately improving patient outcomes.

Metal-Organic Frameworks (MOFs): Classification, Synthesis, Modification, and Biomedical Applications

Metal-organic frameworks (MOFs) are a new variety of solid crystalline porous functional materials. As an extension of inorganic porous materials, it has made important progress in preparation and application. MOFs are widely used in various fields such as gas adsorption storage, drug delivery, sensing, and biological imaging due to their high specific surface area, porosity, adjustable pore size, abundant active sites, and functional modification by introducing groups. In this paper, the types of MOFs are classified, and the synthesis methods and functional modification mechanisms of MOFs materials are summarized. Finally, the application prospects and challenges of metal-organic framework materials in the biomedical field are discussed, hoping to promote their application in multidisciplinary fields.

Evaluating the safety and efficiency of nanomaterials: A focus on mitochondrial health

Nanomaterials (NMs) have extensive application potential in drug delivery, tissue engineering, and various other domains, attributable to their exceptional physical and chemical properties. Nevertheless, an increasing body of literature underscores the diverse safety risks are associated with NMs upon interaction with the human body, including oxidative stress and programmed cell death. Mitochondria, serving as cellular energy factories, play a pivotal role in energy metabolism and the regulation of cell fate. Organs with substantial energy demands, including the heart and brain, are highly sensitive to mitochondrial integrity, with mitochondrial impairment potentially resulting in significant dysfunction and pathologies such as as heart failure and neurodegenerative disease. This review elucidates the pathways by which NMs translocate into mitochondria, their intracellular dynamics, and their impact on mitochondrial morphology, respiratory chain activity, and metabolic processes. We further investigate associated molecular mechanisms, including mitochondrial dynamic imbalance, calcium overload, and oxidative stress, and elucidate the pivotal roles of mitochondria in different forms of programmed cell death such as apoptosis and autophagy. Finally, we offer recommendations regarding the safety and efficacy of NMs for medical applications. By systematically analyzing the interactions and molecular mechanisms between NMs and mitochondria, this paper aims to enhance the toxicological evaluation framework of NMs and provide a foundational reference and theoretical basis for their clinical utilization.

Supramolecularly engineered bacteria mediated calcium overload and immunotherapy of tumors

Intracellular Ca2+ nanogenerators, such as calcium carbonate, calcium peroxide, and calcium phosphate nanoparticles, have shown promise in calcium overload-mediated tumor therapy. However, their effectiveness is often hampered by poor targeting, low accumulation, and limited penetration into tumor cells, leading to suboptimal therapeutic outcomes. This strategy aims to achieve synergistic Ca2+ overload and immunotherapy of tumors. Methods: A supramolecular conjugate of engineered living bacteria (facultative anaerobic Salmonella typhimurium VNP20009, VNP) with CaCO3 nanoparticles was developed for targeted delivery of curcumin-loaded CaCO3 into tumors. Results: Both CaCO3 nanoparticles and the loaded Ca2+ efflux inhibiting agent, curcumin (CUR), demonstrated significant enhancement of intracellular Ca2+ overload, resulting in apoptosis of tumor cells via mitochondrial dysfunction. Moreover, VNP exhibited excellent tumor-targeting ability, colonization in tumor tissues, and anticancer activity with minimal side effects. Conclusion: The conjugate of VNP and CaCO3 not only enhances the efficiency of common cancer treatments but also synergizes Ca2+ overload with cancer immunotherapy, thereby offering a promising approach for improving therapeutic outcomes in cancer treatment.

Integrated design and application of stimuli-responsive metal-organic frameworks in biomedicine: current status and future perspectives

In recent years, metal-organic frameworks (MOFs) have garnered widespread attention due to their distinctive attributes, such as high surface area, tunable properties, biodegradability, extremely low density, high loading capacity, diverse chemical functionalities, thermal stability, well-defined pore sizes, and molecular dimensions. Increasingly, biomedical researchers have turned their focus towards their multifaceted development. Among these, stimuli-responsive MOFs, with their unique advantages, have captured greater interest from researchers. This review will delve into the merits and drawbacks of both endogenous and exogenous stimuli-responsive MOFs, along with their application directions. Furthermore, it will outline the characteristics of different synthesis routes of MOFs, exploring various design schemes and modification strategies and their impacts on the properties of MOF products, as well as how to control them. Additionally, we will survey different types of stimuli-responsive MOFs, discussing the significance of various MOF products reported in biomedical applications. We will categorically summarize different strategies such as anticancer therapy, antibacterial treatment, tissue repair, and biomedical imaging, as well as insights into the development of novel MOFs nanomaterials in the future. Finally, this review will conclude by summarizing the challenges in the development of stimuli-responsive MOFs in the field of biomedicine and providing prospects for future research endeavors.

TRPA1-Related Diseases and Applications of Nanotherapy

Transient receptor potential (TRP) channels, first identified in Drosophila in 1969, are multifunctional ion channels expressed in various cell types. Structurally, TRP channels consist of six membrane segments and are classified into seven subfamilies. Transient receptor potential ankyrin 1 (TRPA1), the first member of the TRPA family, is a calcium ion affinity non-selective cation channel involved in sensory transduction and responds to odors, tastes, and chemicals. It also regulates temperature and responses to stimuli. Recent studies have linked TRPA1 to several disorders, including chronic pain, inflammatory diseases, allergies, and respiratory problems, owing to its activation by environmental toxins. Mutations in TRPA1 can affect the sensory nerves and microvasculature, potentially causing nerve pain and vascular problems. Understanding the function of TRPA1 is important for the development of treatments for these diseases. Recent developments in nanomedicines that target various ion channels, including TRPA1, have had a significant impact on disease treatment, providing innovative alternatives to traditional disease treatments by overcoming various adverse effects.

Acidity-Responsive Fe-PDA@CaCO3 Nanoparticles for Photothermal-Enhanced Calcium-Overload- and Reactive-Oxygen-Species-Mediated Tumor Therapy

Calcium-overload-mediated tumor therapy has received considerable interest in oncology. However, its efficacy has been proven to be inadequate due to insufficient calcium ion concentration at the tumor site coupled with challenges in facilitating efficient calcium uptake by tumors, leading to unsatisfactory therapeutic outcomes. In the present study, calcium carbonate nanoshell mineralized ferric polydopamine nanoparticles (Fe-PDA@CaCO3 NPs) were prepared for achieving Ca2+-overload-mediated tumor therapy. Upon entering the tumor site, the pH-responsive CaCO3 layer, acting as a "Ca2+ storage pool", rapidly degraded and released high quantities of free Ca2+ within the weakly acidic environment. The Fe-PDA core, with its excellent photothermal conversion properties, could significantly increase the temperature upon exposure to near-infrared (NIR) light irradiation, thereby activating the TRPV1 channel and leading to a large influx of released Ca2+ into the cytoplasm. Furthermore, the exposed Fe-PDA core could react with the tumor-overexpressed hydrogen peroxide (H2O2) to efficiently produce hydroxyl radicals (•OH), significantly increasing intracellular reactive oxygen species (ROS) levels and thus inhibiting the activity of the Ca2+ efflux pump, resulting in a high intracellular Ca2+ concentration. Ultimately, the increase in calcium/ROS levels could disrupt mitochondrial homeostasis and activate the apoptosis pathway. The current work presents a promising approach for tumor therapy using photothermal-enhanced calcium-overload-mediated ion interference therapy and chemodynamic therapy.

Determining M2 macrophages content for the anti-tumor effects of metal-organic framework-encapsulated pazopanib nanoparticles in breast cancer

Pazopanib (PAZ), an oral multi-tyrosine kinase inhibitor, demonstrates promising cytostatic activities against various human cancers. However, its clinical utility is limited by substantial side effects and therapeutic resistance. We developed a nanoplatform capable of delivering PAZ for enhanced anti-breast cancer therapy. Nanometer-sized PAZ@Fe-MOF, compared to free PAZ, demonstrated increased anti-tumor therapeutic activities in both syngeneic murine 4T1 and xenograft human MDA-MB-231 breast cancer models. High-throughput single-cell RNA sequencing (scRNAseq) revealed that PAZ@Fe-MOF significantly reduced pro-tumorigenic M2-like macrophage populations at tumor sites and suppressed M2-type signaling pathways, such as ATF6-TGFBR1-SMAD3, as well as chemokines including CCL17, CCL22, and CCL24. PAZ@Fe-MOF reprogramed the inhibitory immune microenvironment and curbed tumorigenicity by blocking the polarization of M2 phenotype macrophages. This platform offers a promising and new strategy for improving the cytotoxicity of PAZ against breast cancers. It provides a method to evaluate the immunological response of tumor cells to PAZ-mediated treatment.

A Dual-Channel Ca2+ Nanomodulator Induces Intracellular Ca2+ Disorders via Endogenous Ca2+ Redistribution for Tumor Radiosensitization

Tumor cells harness Ca2+ to maintain cellular homeostasis and withstand external stresses from various treatments. Here, a dual-channel Ca2+ nanomodulator (CAP-P-NO) is constructed that can induce irreversible intracellular Ca2+ disorders via the redistribution of tumor-inherent Ca2+ for disrupting cellular homeostasis and thus improving tumor radiosensitivity. Stimulated by tumor-overexpressed acid and glutathione, capsaicin and nitric oxide are successively escaped from CAP-P-NO to activate the transient receptor potential cation channel subfamily V member 1 and the ryanodine receptor for the influx of extracellular Ca2+ and the release of Ca2+ in the endoplasmic reticulum, respectively. The overwhelming level of Ca2+ in tumor cells not only impairs the function of organelles but also induces widespread changes in the gene transcriptome, including the downregulation of a set of radioresistance-associated genes. Combining CAP-P-NO treatment with radiotherapy achieves a significant suppression against both pancreatic and patient-derived hepatic tumors with negligible side effects. Together, the study provides a feasible approach for inducing tumor-specific intracellular Ca2+ overload via endogenous Ca2+ redistribution and demonstrates the great potential of Ca2+ disorder therapy in enhancing the sensitivity for tumor radiotherapy.

Strategic disruption of cancer's powerhouse: precise nanomedicine targeting of mitochondrial metabolism

Mitochondria occupy a central role in the biology of most eukaryotic cells, functioning as the hub of oxidative metabolism where sugars, fats, and amino acids are ultimately oxidized to release energy. This crucial function fuels a variety of cellular activities. Disruption in mitochondrial metabolism is a common feature in many diseases, including cancer, neurodegenerative conditions and cardiovascular diseases. Targeting tumor cell mitochondrial metabolism with multifunctional nanosystems emerges as a promising strategy for enhancing therapeutic efficacy against cancer. This review comprehensively outlines the pathways of mitochondrial metabolism, emphasizing their critical roles in cellular energy production and metabolic regulation. The associations between aberrant mitochondrial metabolism and the initiation and progression of cancer are highlighted, illustrating how these metabolic disruptions contribute to oncogenesis and tumor sustainability. More importantly, innovative strategies employing nanomedicines to precisely target mitochondrial metabolic pathways in cancer therapy are fully explored. Furthermore, key challenges and future directions in this field are identified and discussed. Collectively, this review provides a comprehensive understanding of the current state and future potential of nanomedicine in targeting mitochondrial metabolism, offering insights for developing more effective cancer therapies.

Rational design of a lysosome-targeted fluorescent probe for monitoring the generation of hydroxyl radicals in ferroptosis pathways

Ferroptosis is a newly discovered iron-dependent form of regulated cell death associated with high levels of hydroxyl radical (˙OH) production. Meanwhile, lysosome dysfunction has been shown to be one of the causes of ferroptosis. Although a variety of ˙OH-responsive fluorescent probes have been developed for detecting intracellular ˙OH in living cells, there are still only few lysosome-targeted probes to monitor the variation in lysosomal ˙OH levels during ferroptosis. Herein, we report a novel ˙OH-specific fluorescent probe HCy-Lyso, which is composed of the hydrocyanine and morpholine moiety. Upon treatment with ˙OH, its hydrocyanine unit was converted to the corresponding cyanine group, thus leading to a large π-conjugation extension of HCy-Lyso, accompanied by a significant fluorescence off-on response. Moreover, after reacting with ˙OH in an acidic environment, the protonation product of HCy-Lyso exhibits a higher fluorescence enhancement, which is suitable for detecting lysosomal ˙OH variation. HCy-Lyso has been utilized for imaging endogenous ˙OH in living cells under phorbol myristate acetate (PMA) stimuli and monitoring the changes in lysosomal ˙OH levels during ferroptosis. Thus, our study proposes a new strategy to design lysosome-targeted and ˙OH-responsive fluorescent probes to investigate the relationship between lysosomes and ferroptosis.

Osteosarcoma-targeted Cu and Ce based oxide nanoplatform for NIR II fluorescence/magnetic resonance dual-mode imaging and ros cascade amplification along with immunotherapy

BACKGROUND

As the lethal bone tumor, osteosarcoma often frequently occurs in children and adolescents with locally destructive and high metastasis. Distinctive kinds of nanoplatform with high therapeutical effect and precise diagnosis for osteosarcoma are urgently required. Multimodal optical imaging and programmed treatment, including synergistic photothermal-chemodynamic therapy (PTT-CDT) elicits immunogenetic cell death (ICD) is a promising strategy that possesses high bio-imaging sensitivity for accurate osteosarcoma delineating as well as appreciable therapeutic efficacy with ignorable side-effects.

METHODS AND RESULTS

In this study, mesoporous Cu and Ce based oxide nanoplatform with Arg-Gly-Asp (RGD) anchoring is designed and successfully constructed. After loading with indocyanine green, this nanoplatform can be utilized for precisely targeting and efficaciously ablating against osteosarcoma via PTT boosted CDT and the closely following ICD stimulation both in vitro and in vivo. Besides, it provides off-peak fluorescence bio-imaging in the second window of near-infrared region (NIR II, 1000-1700 nm) and Magnetic resonance signal, serves as the dual-mode contrast agents for osteosarcoma tissue discrimination.

CONCLUSION

Tumor targeted Cu&Ce based mesoporous nanoplatform permits efficient osteosarcoma suppression and dual-mode bio-imaging that opens new possibility for effectively diagnosing and inhibiting the clinical malignant osteosarcoma.

Bioinspired Tumor Calcification-Guided Early Diagnosis and Eradication of Hepatocellular Carcinoma

Tumor calcification is found to be associated with the benign prognostic, and which shows considerable promise as a somewhat predictive index of the tumor response clinically. However, calcification is still a missing area in clinical cancer treatment. A specific strategy is proposed for inducing tumor calcification through the synergy of calcium peroxide (CaO2)-based microspheres and transcatheter arterial embolization for the treatment of hepatocellular carcinoma (HCC). The persistent calcium stress in situ specifically leads to powerful tumor calcioptosis, resulting in diffuse calcification and a high-density shadow on computed tomography that enables clear localization of the in vivo tumor site and partial delineation of tumor margins in an orthotopic HCC rabbit model. This osmotic calcification can facilitate tumor clinical diagnosis, which is of great significance in differentiating tumor response during early follow-up periods. Proteome and phosphoproteome analysis identify that calreticulin (CALR) is a crucial target protein involved in tumor calcioptosis. Further fluorescence molecular imaging analysis also indicates that CALR can be used as a prodromal marker of calcification to predict tumor response at an earlier stage in different preclinical rodent models. These findings suggest that upregulated CALR in association with tumor calcification, which may be broadly useful for quick visualization of tumor response.

Porphyrin Derivative with Binary Properties of Photodynamic Therapy and Water-Dependent Reversible Photoacidity Therapy for Treating Hypoxic Tumor

Porphyrin photosensitizers are the classic drugs in clinical photodynamic therapy (PDT), but the hypoxia of tumor environment and the rapid oxygen consumption of PDT severely weaken their therapeutic effect. A recently reported water-dependent reversible photoacidity therapy (W-RPAT) is O2-independence, providing a solution for the treatment of hypoxic tumors. In this work, TPP-O-PEG5, a porphyrin derivative with binary properties of PDT and W-RPAT, is designed and synthesized for the first time. The nanoparticles (NPs) of TPP-O-PEG5 encapsulated with DSPE-mPEG2000, an amphiphilic polymer approved by Food and Drug Administration, can simultaneously produce reactive oxygen species and H+ under irradiation of a 660 nm laser, and revert the H+ back under darkness, presenting strong phototoxicity to multiple tumor cell lines with no obvious difference between the IC50 values tested under normoxic (≈20% O2) and hypoxic (<0.5% O2) conditions. Excitingly, in vivo experiments show that the therapeutic effect of TPP-O-PEG5 NPs on large hypoxic tumors is better than that of NPe6, a clinical porphin PDT drug. This work provides a novel strategy for porphyrin photosensitizers to break through the limitation of hypoxic environment, and significantly improve the phototherapeutic effect on hypoxic tumors.

Recent Advances on NIR-II Light-Enhanced Chemodynamic Therapy

Chemodynamic therapy (CDT) is a particular oncological therapeutic strategy by generates the highly toxic hydroxyl radical (•OH) from the dismutation of endogenous hydrogen peroxide (H2O2) via Fenton or Fenton-like reactions. However, single CDT therapies have been limited by unsatisfactory efficacy. Enhanced chemodynamic therapy (ECDT) triggered by near-infrared (NIR) is a novel therapeutic modality based on light energy to improve the efficiency of Fenton or Fenton-like reactions. However, the limited penetration and imaging capability of the visible (400-650 nm) and traditional NIR-I region (650-900 nm) light-amplified CDT restrict the prospects for its clinical application. Combined with the high penetration/high precision imaging characteristics of the second near-infrared (NIR-II,) nanoplatform, it is expected to kill deep tumors efficiently while imaging the treatment process in real-time, and more notably, the NIR-II region radiation with wavelengths above 1000 nm can minimize the irradiation damage to normal tissues. Such NIR-II ECDT nanoplatforms have greatly improved the effectiveness of CDT therapy and demonstrated extraordinary potential for clinical applications. Accordingly, various strategies have been explored in the past years to improve the efficiency of NIR-II Enhanced CDT. In this review, the mechanisms and strategies used to improve the performance of NIR-II-enhanced CDT are outlined.

Enhancing lipid peroxidation via radical chain transfer reaction for MRI guided and effective cancer therapy in mice

Lipid peroxidation (LPO), the process of membrane lipid oxidation, is a potential new form of cell death for cancer treatment. However, the radical chain reaction involved in LPO is comprised of the initiation, propagation (the slowest step), and termination stages, limiting its effectiveness in vivo. To address this limitation, we introduce the radical chain transfer reaction into the LPO process to target the propagation step and overcome the sluggish rate of lipid peroxidation, thereby promoting endogenous lipid peroxidation and enhancing therapeutic outcomes. Firstly, radical chain transfer agent (CTA-1)/Fe nanoparticles (CTA-Fe NPs-1) was synthesized. Notably, CTA-1 convert low activity peroxyl radicals (ROO·) into high activity alkoxyl radicals (RO·), creating the cycle of free radical oxidation and increasing the propagation of lipid peroxidation. Additionally, CTA-1/Fe ions enhance reactive oxygen species (ROS) generation, consume glutathione (GSH), and thereby inactivate GPX-4, promoting the initiation stage and reducing termination of free radical reaction. CTA-Fe NPs-1 induce a higher level of peroxidation of polyunsaturated fatty acids in lipid membranes, leading to highly effective treatment in cancer cells. In addition, CTA-Fe NPs-1 could be enriched in tumors inducing potent tumor inhibition and exhibit activatable T1-MRI contrast of magnetic resonance imaging (MRI). In summary, CTA-Fe NPs-1 can enhance intracellular lipid peroxidation by accelerating initiation, propagation, and inhibiting termination step, promoting the cycle of free radical reaction, resulting in effective anticancer outcomes in tumor-bearing mice.

Nanozyme-Based Regulation of Cellular Metabolism and Their Applications

Metabolism is the sum of the enzyme-dependent chemical reactions, which produces energy in catabolic process and synthesizes biomass in anabolic process, exhibiting high similarity in mammalian cell, microbial cell, and plant cell. Consequently, the loss or gain of metabolic enzyme activity greatly affects cellular metabolism. Nanozymes, as emerging enzyme mimics with diverse functions and adjustable catalytic activities, have shown attractive potential for metabolic regulation. Although the basic metabolic tasks are highly similar for the cells from different species, the concrete metabolic pathway varies with the intracellular structure of different species. Here, the basic metabolism in living organisms is described and the similarities and differences in the metabolic pathways among mammalian, microbial, and plant cells and the regulation mechanism are discussed. The recent progress on regulation of cellular metabolism mainly including nutrient uptake and utilization, energy production, and the accompanied redox reactions by different kinds of oxidoreductases and their applications in the field of disease therapy, antimicrobial therapy, and sustainable agriculture is systematically reviewed. Furthermore, the prospects and challenges of nanozymes in regulating cell metabolism are also discussed, which broaden their application scenarios.

Photo-Controlled Calcium Overload from Endogenous Sources for Tumor Therapy

Designing reactive calcium-based nanogenerators to produce excess calcium ions (Ca2+ ) in tumor cells is an attractive tumor treatment method. However, nanogenerators that introduce exogenous Ca2+ are either overactive incapable of on-demand release, or excessively inert incapable of an overload of calcium rapidly. Herein, inspired by inherently diverse Ca2+ -regulating channels, a photo-controlled Ca2+ nanomodulator that fully utilizes endogenous Ca2+ from dual sources was designed to achieve Ca2+ overload in tumor cells. Specifically, mesoporous silica nanoparticles were used to co-load bifunctional indocyanine green as a photodynamic/photothermal agent and a thermal-sensitive nitric oxide (NO) donor (BNN-6). Thereafter, they were coated with hyaluronic acid, which served as a tumor cell-targeting unit and a gatekeeper. Under near-infrared light irradiation, the Ca2+ nanomodulator can generate reactive oxygen species that stimulate the transient receptor potential ankyrin subtype 1 channel to realize Ca2+ influx from extracellular environments. Simultaneously, the converted heat can induce BNN-6 decomposition to generate NO, which would open the ryanodine receptor channel in the endoplasmic reticulum and allow stored Ca2+ to leak. Both in vitro and in vivo experiments demonstrated that the combination of photo-controlled Ca2+ influx and release could enable Ca2+ overload in the cytoplasm and efficiently inhibit tumor growth.

Discovery of mitochondrion-targeting copper(II)-plumbagin and -bipyridine complexes as chemodynamic therapy agents with enhanced antitumor activity

Four copper(II)-plumbagin and -bipyridine complexes (Cu1-Cu4) were synthesized as chemodynamic therapy agents with enhanced antitumor activity. As lipophilic and positively charged compounds, Cu1-Cu4 were preferentially accumulated in mitochondria and activated the mitochondrial apoptosis pathway. Mechanistic studies showed that Cu1-Cu4 reacted with GSH to reduce Cu2+ ions to Cu+ ions, catalyzed the formation of toxic hydroxyl radicals (˙OH) from hydrogen peroxide (H2O2) through a Fenton-like reaction, induced mitochondrial dysfunction, and activated caspase-9/3, which eventually led to apoptosis. Cu1-Cu4 arrested HeLa cells in the S phase and eventually killed cancer cells. Cu2 showed a favorable pharmacokinetic profile in mice. Moreover, Cu2 effectively inhibited the growth of HeLa xenografts in nude mice and showed low toxicity in vivo.

Manipulating calcium homeostasis with nanoplatforms for enhanced cancer therapy

Calcium ions (Ca2+) are indispensable and versatile metal ions that play a pivotal role in regulating cell metabolism, encompassing cell survival, proliferation, migration, and gene expression. Aberrant Ca2+ levels are frequently linked to cell dysfunction and a variety of pathological conditions. Therefore, it is essential to maintain Ca2+ homeostasis to coordinate body function. Disrupting the balance of Ca2+ levels has emerged as a potential therapeutic strategy for various diseases, and there has been extensive research on integrating this approach into nanoplatforms. In this review, the current nanoplatforms that regulate Ca2+ homeostasis for cancer therapy are first discussed, including both direct and indirect approaches to manage Ca2+ overload or inhibit Ca2+ signalling. Then, the applications of these nanoplatforms in targeting different cells to regulate their Ca2+ homeostasis for achieving therapeutic effects in cancer treatment are systematically introduced, including tumour cells and immune cells. Finally, perspectives on the further development of nanoplatforms for regulating Ca2+ homeostasis, identifying scientific limitations and future directions for exploitation are offered.