Photo‐ and pH‐Triggered Release of Anticancer Drugs from Mesoporous Silica‐Coated Pd@Ag Nanoparticles

A smart drug delivery system integrating both photothermal therapy and chemotherapy for killing cancer cells is reported. The delivery system is based on a mesoporous silica‐coated Pd@Ag nanoplates composite. The Pd@Ag nanoplate core can effectively absorb and convert near infrared (NIR) light into heat. The mesoporous silica shell is provided as the host for loading anticancer drug, doxorubicin (DOX). The mesoporous shell consists of large pores, ～10 nm in diameter, and allows the DOX loading as high as 49% in weight. DOX loaded core–shell nanoparticles exhibit a higher efficiency in killing cancer cells than free DOX. More importantly, DOX molecules are loaded in the mesopores shell through coordination bonds that are responsive to pH and heat. The release of DOX from the core‐shell delivery vehicles into cancer cells can be therefore triggered by the pH drop caused by endocytosis and also NIR irradiation. A synergistic effect of combining chemotherapy and photothermal therapy is observed in our core‐shell drug delivery system. The cell‐killing efficacy by DOX‐loaded core–shell particles under NIR irradiation is higher than the sum of chemotherapy by DOX‐loaded particles and photothermal therapy by core–shell particles without DOX.     

Near‐Infrared Absorbing Polymeric Nanoparticles as a Versatile Drug Carrier for Cancer Combination Therapy

Poly(3,4‐ethylenedioxythiophene):poly(4‐styrenesulfonate) (PEDOT:PSS) nanoparticles, after being coated with polyethylene glycol (PEG), are used as a drug carrier to load various types of aromatic therapeutic molecules, including chemotherapy drugs doxorubicin (DOX) and SN38, as well as a photodynamic agent chlorin e6 (Ce6), through π–π stacking and hydrophobic interaction. Interesting functionalities of PEDOT:PSS‐PEG as an unique versatile drug delivery platform are discovered. Firstly, for water‐insoluble drugs such as SN38, the loading on PEDOT:PSS‐PEG dramatically enhances its water solubility, while maintaining its cytotoxicity to cancer cells. Secondly, the delivery of Ce6 by PEDOT:PSS‐PEG is able to remarkably accelerate the cellular uptake of Ce6 molecules, and thus offers improved photodynamic therapeutic efficacy. Using DOX‐loaded PEDOT:PSS‐PEG as the model system, it is demonstrated that the photothermal effect of PEDOT:PSS‐PEG can be utilized to promote the delivery of this chemotherapeutic agent, achieving a combined photothermal‐ and chemotherapy with an obvious synergistic cancer killing effect. Moreover, it is also shown that multiple types of therapeutic agents could be simultaneously loaded on PEDOT:PSS‐PEG nanoparticles and delivered into cancer cells. This work highlights the great potential of NIR‐absorbing polymeric nanoparticles as multifunctional drug carriers for potential cancer combination therapy with high efficacy.     

Mesoporous Silica Coated Single‐Walled Carbon Nanotubes as a Multifunctional Light‐Responsive Platform for Cancer Combination Therapy

The development of cancer combination therapies, many of which rely on nanoscale theranostic agents, has received increasing attention in recent years. In this work, polyethylene glycol (PEG) modified mesoporous silica (MS) coated single‐walled carbon nanotubes (SWNTs) are fabricated and utilized as a multifunctional platform for imaging guided combination therapy of cancer. A model chemotherapy drug, doxorubicin (DOX), could be loaded into the mesoporous structure of the obtained SWNT@MS‐PEG nano‐carriers with high efficiency. Upon stimulation under near‐infrared (NIR) light, photothermally triggered drug release from DOX loaded SWNT@MS‐PEG is observed inside cells, resulting in a synergistic cancer cell killing effect. As revealed by both photoacoustic (PA) and magnetic resonance (MR) imaging, we further uncover efficient tumor accumulation of SWNT@MS‐PEG/DOX after intravenous injection into mice. In vivo combination therapy using this agent is further demonstrated in a mouse tumor model, achieving a remarkable synergistic anti‐tumor effect superior to that obtained by mono‐therapy. Our work presents a new type of theranostic nano‐platform, which could load therapeutic molecules with high efficiency, be responsive to external NIR stimulation, and at the same time serve as a diagnostic imaging agent.     

NIR‐Activated Supersensitive Drug Release Using Nanoparticles with a Flow Core

Near infrared (NIR) light‐activated supersensitive drug release via photothermal conversion is of particular interest due to its advantages in spatial and temporal control. However, such supersensitive drug release is rarely reported for polymeric nanoparticles. In this study, polymeric nanoparticles observed with flowable core can achieve NIR‐activated supersensitive drug release under the assistance of photothermal agent. It is demonstrated that only 5 s NIR irradiation (808 nm, 0.3 W cm^?2) leads to 17.8% of doxorubicin (DOX) release, while its release is almost completely stopped when the NIR laser is switched off. In contrast, the control, poly(d ,l ‐lactide) nanoparticles with rigid cores, do not exhibit such supersensitive effect. It is demonstrated that intraparticle temperature is notably increased during photothermal conversion by detecting fluorescein lifetime using a time‐correlated single photon counting (TCSPC) technique, which is the main driving force for such supersensitive drug release from hydrophobic flow core. In contrast, rigid chain of nanoparticular core hinders drug diffusion. Furthermore, such NIR light‐activated supersensitive drug release is demonstrated, which significantly enhances its anticancer efficacy, resulting in overcoming of the resistance of cancer cells against DOX treatment in vitro and in vivo. This simple and highly universal strategy provides a new approach to fabricate NIR light‐activated supersensitive drug delivery systems.     

Engineering of Mesoporous Silica Coated Carbon‐Based Materials Optimized for an Ultrahigh Doxorubicin Payload and a Drug Release Activated by pH,T, and NIR‐light

Among the challenges in nanomedicine, engineering nanomaterials able to combine imaging and multitherapies is hugely needed to address issues of a personalized treatment. In that context, a novel class of drug releasing and remotely activated nanocomposites based on carbon‐based materials coated with mesoporous silica (MS) and loaded with an outstanding level of the antitumoral drug doxorubicin (DOX) is designed. First, carbon nanotubes (CNTs) and graphene sheets (called “few‐layer graphene” FLG) are processed to afford a distribution size that is more suitable for nanomedicine applications. Then, the controlled coating of MS shells having a thickness tailored with the sol–gel parameters (amount of precursor, sol–gel time) around the sliced CNTs and exfoliated FLGs is reported. Furthermore, the drug loading in such mesoporous nanocomposites is investigated and the surface modification with an aminopropyltriethoxysilane (APTS) coating leading to a controlled polysiloxane layer provides an ultrahigh payload of DOX (up to several folds the mass of the initial composites). Such new CNT‐based nanocomposites are demonstrated to release DOX at low acidic pH, high temperature (T), and remotely when they are excited by near infrared (NIR) light. Such nanoconstructs may find applications as components of innovative biomedical scaffolds for phototherapy combined with drug delivery.     

Tumor‐Specific Aptamer‐Conjugated Polymeric Photosensitizer for Effective Endo‐Laparoscopic Photodynamic Therapy

Recent advances in medical technology and endo‐laparoscopic devices have enabled the treatment of gastrointestinal (GI) cancers to be minimally invasive through endo‐laparoscopic photodynamic therapy (PDT). To achieve an efficient regional or endo‐laparoscopic PDT, it is necessary to develop a highly target specific photosensitizer (PS) that can be easily treated to the lesion site with endo‐laparoscopic device. Here, an ideal polymeric PS is demonstrated for effective endo‐laparoscopic PDT. In the synthetic process, conventional PS (i.e., Chlorin e6, Ce6) is conjugated with an Aptamer (i.e., AS1411) targeting nucleolin (also called C23) overexpressed on the cancer cell membrane using a water‐soluble polymeric linker (i.e., polyethylene glycol, PEG). The synthesized Aptamer‐PEG‐Ce6 could target nucleolin‐overexpressing tumor cells efficiently and visualize the tumor tissues through optical and fluorescent imaging both in vitro and ex vivo, and effectively kills cancer cells under laser irradiation. Tumor staining with Aptamer‐PEG‐Ce6 is easily accomplished through endoscopic equipment within a few minutes. Furthermore, after laser irradiation, Aptamer‐PEG‐Ce6 is found to penetrate deeply into the tumor tissue and induce apoptosis of tumor cells. Taken together, the tumor‐specific Aptamer‐conjugated polymeric PS developed in this study has great potential as an ideal photomedicine for effective tumor treatment using endo‐laparoscopic PDT.     

High‐Drug‐Loading Mesoporous Silica Nanorods with Reduced Toxicity for Precise Cancer Therapy against Nasopharyngeal Carcinoma

Nanorod‐based drug delivery systems have attracted great interest because of their enhanced cell internalization capacity and improved drug loading property. Herein, novel mesoporous silica nanorods (MSNRs) with different lengths are synthesized and used as nanocarriers to achieve higher drug loading and anticancer activity. As expected, MSNRs‐based drug delivery systems can effectively enhance the loading capacity of drugs and penetrate into tumor cells more rapidly than spherical nanoparticles due to their greater surface area and trans‐membrane transporting rates. Interestingly, these tailored MSNRs also enhance the cellular uptake of doxorubicin (DOX) in cancer cells, thus significantly enhancing its anticancer efficacy for hundreds of times by inducing of cell apoptosis. Internalized MSNRs‐DOX triggers intracellular reactive oxygen species (ROS) overproduction, which subsequently activates p53 and mitogen‐activated protein kinases (MAPKs) pathways to promote cell apoptosis. MSNRs‐DOX nanosystem also shows prolonged blood circulation time in vivo. In addition, MSNRs‐DOX significantly inhibits in vivo tumor growth in nude mice model and effectively reduced its in vivo toxicity. Therefore, this study provides an effective and safe strategy for designing chemotherapeutic agents for precise cancer therapy.     

Unprecedented “All‐in‐One” Lanthanide‐Doped Mesoporous Silica Frameworks for Fluorescence/MR Imaging and Combination of NIR Light Triggered Chemo‐Photodynamic Therapy of Tumors

Designing a single multifunctional nanoparticle that can simultaneously impart both diagnostic and therapeutic functions is considered to be a long‐lasting hurdle for biomedical researchers. Conventionally, a multifunctional nanoparticle can be constructed by integrating organic dyes/magnetic nanoparticles to impart diagnostic functions and anticancer drugs/photosensitizers to achieve therapeutic outcomes. These multicomponents systems usually suffer from severe photobleaching problems and cannot be activated by near‐infrared (NIR) light. Here, it is demonstrated that all‐in‐one lanthanide‐doped mesoporous silica frameworks (EuGdOx@MSF) loaded with an anticancer drug, doxorubicin (DOX) can facilitate simultaneous bimodal magnetic resonance (MR) imaging with approximately twofold higher T₁‐MR contrast as compared to the commercial Gd(III)‐DTPA complex and fluorescence imaging with excellent photostability. Upon a very low dose (130 mW cm^?2) of NIR light (980 nm) irradiation, the EuGdOx@MSF not only can sensitize formation of singlet oxygen (¹O₂) by itself but also can phototrigger the release of the DOX payload effectively to exert combined chemo‐photodynamic therapeutic (PDT) effects and destroy solid tumors in mice completely. It is also discovered for the first time that the EuGdOx@MSF‐mediated PDT effect can suppress the level of the key drug resistant protein, i.e., p‐glycoprotein (p‐gp) and help alleviate the drug resistant problem commonly associated with many cancers.     

Real‐Time Imaging Tracking of Engineered Macrophages as Ultrasound‐Triggered Cell Bombs for Cancer Treatment

Cell‐based drug delivery systems are a promising platform for tumor‐targeted therapy due to their high drug‐loading capacities and inherent tumor‐homing abilities. However, the real‐time tracking of these carrier cells and controlled release of the encapsulated drugs are still challenging. Here, ultrasound‐activatable cell bombs are developed by encapsulating doxorubicin (DOX) and phase transformable perfluoropentane (PFP) into hollow mesoporous organosilica nanoparticles (HMONs) to prepare DOX/PFP‐loaded HMONs (DPH), followed by internalization into macrophages (RAW 264.7 cells). The resulting cell bombs (DPH‐RAWs) can maintain viability and actively home to the tumor. Especially, their migration can be tracked in real time using ultrasound due to the vaporization of a small portion of PFP during cell incubation at 37 °C. After accumulation at the tumor site, the further vaporization of remaining PFP can be triggered by a short‐pulsed high intensity focused ultrasound (HIFU) sonication, resulting in the generation of several large microbubbles, which destroys DPH‐RAWs and allows drug release out of these cells. The DPH‐RAWs combined with short‐pulsed HIFU sonication significantly inhibit tumor growth and prolong survival of tumor‐bearing mice. In conclusion, this study provides a new approach to cell‐based drug delivery systems for real‐time tracking of their migration and targeted cancer treatment.     

Nanoengineered Light‐Activatable Polybubbles for On‐Demand Therapeutic Delivery

Vaccine coverage is severely limited in developing countries due to inefficient protection of vaccine functionality as well as lack of patient compliance to receive the additional booster doses. Thus, there is an urgent need to design a thermostable vaccine delivery platform that also enables release of the bolus after predetermined time. Here, the formation of injectable and light‐activatable polybubbles for vaccine delivery is reported. In vitro studies show that polybubbles enable delayed burst release, irrespective of cargo types, namely small molecule and antigen. The extracorporeal activation of polybubbles is achieved by incorporating near‐infrared (NIR)‐sensitive gold nanorods (AuNRs). Interestingly, light‐activatable polybubbles can be used for on‐demand burst release of cargo. In vitro, ex vivo, and in vivo studies demonstrate successful activation of AuNR‐loaded polybubbles. Overall, the light‐activatable polybubble technology can be used for on‐demand delivery of various therapeutics including small molecule drugs, immunologically relevant protein, peptide antigens, and nucleic acids.     

Metal–Organic Framework Assisted and Tumor Microenvironment Modulated Synergistic Image‐Guided Photo‐Chemo Therapy

The complex tumor microenvironment (TME) and nonspecific drug targeting limit the clinical efficacy of photodynamic therapy in combination with chemotherapy. Herein, a metal–organic framework (MOF) assisted strategy is reported that modulates TME by reducing tumor hypoxia and intracellular glutathione (GSH) and offers targeted delivery and controlled release of the trapped chemodrug. Platinum(IV)‐diazido complex (Pt(IV)) is loaded inside a Cu(II) carboxylate‐based MOF, MOF‐199, and an aggregation‐induced‐emission photosensitizer, TBD, is conjugated to polyethylene glycol for encapsulating Pt(IV)‐loaded MOF‐199. Once the fabricated TBD‐Pt(IV)@MOF‐199 nanoparticles are internalized by cancer cells, MOF‐199 consumes intracellular GSH and decomposes to fragments to release Pt(IV). Upon light irradiation, the released Pt(IV) generates O₂ that relieves hypoxia and produces Pt(II)‐based chemodrug inside cancer cells. Concomitantly, efficient reactive oxygen species generation and bright emission are afforded by TBD, resulting in synergistic image‐guided photo‐chemo therapy with enhanced efficacies and mitigated side effects.     

pH‐Sensitive Dissociable Nanoscale Coordination Polymers with Drug Loading for Synergistically Enhanced Chemoradiotherapy

Although various types of radiosensitizers based on nanoparticles are explored to enhance radiotherapy via different mechanisms, nanoscale radiosensitizers with full biodegradability, sensitive responsiveness to the tumor microenvironment, as well as the ability to greatly amplify radiation‐induced tumor destruction are still demanded. Herein, this study designs nanoscale coordination polymers (NCPs) based on acidic sensitive linker and high Z number element hafnium (Hf) ions. Chloro(triphenylphosphine)gold(I) (TPPGC), a chemotherapeutic drug, is successfully loaded into those NCPs after they are coated with polyethylene glycol (PEG). Owing to the acid‐triggered cleavage of the organic linker, such formed NCP‐PEG/TPPGC nanoparticles would be dissociated under reduced pH within the tumor, leading to the release of TPPGC to induce mitochondrial damage and arrest the cell cycle of tumor cells into the radiosensitive phase (G1). Meanwhile, Hf ions are able to act as radiosensitizers by absorbing X‐ray and depositing radiation energy within tumors. With efficient tumor accumulation after intravenous injection, NCP‐PEG/TPPGC offers remarkable synergistic therapeutic outcome in chemoradiotherapy without appreciable toxic side effect. This work thus presents a biodegradable nano‐radiosensitizer with in vivo tumor‐specific decomposition/drug release profiles and great efficacy in chemoradiotherapy of cancer.     

Biocompatible PEG‐Chitosan@Carbon Dots Hybrid Nanogels for Two‐Photon Fluorescence Imaging,Near‐Infrared Light/pH Dual‐Responsive Drug Carrier,and Synergistic Therapy

This work designs a class of biocompatible PEG‐chitosan@CDs hybrid nanogels by integrating nonlinear poly(ethylene glycol) (PEG), chitosan, and graphitic carbon dots (CDs) into a single nanoparticle for two‐photon fluorescence (TPF) bioimaging, pH and near‐infrared (NIR) light dual‐responsive drug release, and synergistic therapy. Such hybrid nanogels can be simply prepared from a one‐pot surfactant‐free precipitation polymerization of the PEG macromonomers complexed with chitosan and CDs in water, resulting in a semi‐interpenetration of chitosan chains and an immobilization of CDs in the nonlinear PEG networks. The embedded CDs in hybrid nanogels not only serve as an excellent confocal and TPF imaging contrast agent and fluorescent pH‐sensing probe, but also enhance the loading capacity of the hybrid nanogels for hydrophobic anticancer drug. The chitosan can induce a pH‐sensitive swelling/deswelling of the hybrid nanogels for pH‐regulated drug release over the physiologically important range of 5.0–7.4 and surface modulation of embedded CDs to realize fluorescent pH sensing. The thermosensitive nonlinear PEG network can promote the drug release through the local heat produced by the embedded CDs under NIR irradiation. The in vitro results indicate that the hybrid nanogels demonstrated high therapeutic efficacy through the synergistic effect of combined chemo–photothermal treatments.     

Ultrafast Electrochemical Trigger Drug Delivery Mechanism for Nanographene Micromachines

Nano/micromachines with autonomous motion are the frontier of nanotechnology and nanomaterial research. These self‐propelled nano/micromachines convert chemical energy obtained from their surroundings to propulsion. They have shown great potential in diagnostic and therapeutic applications. This work introduces a high‐speed tubular electrically conductive micromachine based on reduced nanographene oxide (n‐rGO) as a platform for drug delivery and platinum (Pt) as the catalytic inner layer. n‐rGO/Pt micromachines are loaded with doxorubicin (DOX) by a simple physical adsorption with a very high loading efficiency, displaying single‐ or multistrand wrapping of DOX monomers on the micromachine cylinders. More importantly, it is found that electron injection into DOX@n‐rGO/Pt micromachines via electrochemistry leads to expulsion of DOX from micromachines in motion within only a few seconds. An in vitro study confirms this efficient release mechanism in the presence of cancerous cells. The unique properties of the n‐rGO/Pt micromotor enable the effective management of DOX release at the tumor site and thus enhances the therapeutic efficiency and reduces the side toxicity toward the healthy tissue. These micromachine drug carriers combine the high loading capacity of conventional carbon‐based drug carriers with a fast and efficient electrochemical drug‐release mechanism.     

Selenium‐Containing Polymer@Metal‐Organic Frameworks Nanocomposites as an Efficient Multiresponsive Drug Delivery System

The development of efficient multiresponsive drug delivery systems (DDSs) to control drug release has been widely explored. Herein, a facile strategy is reported that enables the micelles of the selenium‐containing polymer with the drug to be encapsulated in metal‐organic frameworks (MOFs), which serves as multiresponsive drug release by employing the selenium‐containing polymers with redox‐triggered property and the MOFs with pH‐triggered property in DDS. In this case, the micelles of selenium‐containing polymers, as core easily disassembles in the presence of redox agents, can then release the drug in MOFs matrixes. The ZIF‐8 (one type of MOFs) crystal frameworks serving as shell can collapse only under low pH conditions, and the drug can be further released. In the presence of external redox agents as well as the pH stimuli, the prepared nanocomposite (P@ZIF‐8) drug system exhibits the capability of multiresponsive release of the doxorubicin (DOX) and possesses good selectivity in releasing the DOX under low pH conditions instead of normal pH conditions. In addition, the merits of P@ZIF‐8 such as good biocompatibility, multiresponsive release properties, and especially the selective release properties under different pH conditions make the materials highly promising candidates for the realization of controlled drug delivery in tumor tissue systems.     

Redox Sensitive Hyaluronic Acid‐Decorated Graphene Oxide for Photothermally Controlled Tumor‐Cytoplasm‐Selective Rapid Drug Delivery

Nanocarriers capable of circumventing various biological barriers between the site of administration and the therapeutic target hold great potential for cancer treatment. Herein, a redox‐sensitive, hyaluronic acid‐decorated graphene oxide nanosheet (HSG) is developed for tumor cytoplasm‐specific rapid delivery using near‐infrared (NIR) irradiation controlled endo/lysosome disruption and redox‐triggered cytoplasmic drug release. Hyaluronic acid (HA) modification through redox‐sensitive linkages permits HSG a range of advantages over the standard graphene oxide, including high biological stability, enhanced drug‐loading capacity for aromatic molecules, HA receptor‐mediated active tumor targeting, greater NIR absorption and thermal energy translation, and a sharp redox‐dependent response for accelerated cargo release. Results of in vivo and in vitro testing indicate a high loading of doxorubicin (DOX) onto HSG. Selective delivery to HA‐receptor overexpressing tumors is achieved through passive and active targeting with minimized unfavorable interactions with blood components. Cytoplasm‐specific DOX delivery is then achieved through NIR controlled endo/lysosome disruption along with redox‐triggered release of DOX in glutathione rich areas. HSG's specificity is resulted in enhanced cytotoxicity of chemotherapeutics with minimal collateral damage to healthy tissues in a xenograft animal tumor model. HSG is validated the programmed delivery of therapeutic agents in a spatiotemporally controlled manner to overcome multiple biological barriers results in specific and enhanced cancer treatment.     

pH‐ and NIR Light‐Responsive Micelles with Hyperthermia‐Triggered Tumor Penetration and Cytoplasm Drug Release to Reverse Doxorubicin Resistance in Breast Cancer

The acquisition of multidrug resistance (MDR) is a major hurdle for the successful chemotherapy of tumors. Herein, a novel hybrid micelle with pH and near‐infrared (NIR) light dual‐responsive property is reported for reversing doxorubicin (DOX) resistance in breast cancer. The hybrid micelles are designed to integrate the pH‐ and NIR light‐responsive property of an amphiphilic diblock polymer and the high DOX loading capacity of a polymeric prodrug into one single nanocomposite. At physiological condition (i.e., pH 7.4), the micelles form compact nanostructure with particle size around 30 nm to facilitate blood circulation and passive tumor targeting. Meanwhile, the micelles are quickly dissociated in weakly acidic environment (i.e., pH ≤ 6.2) to release DOX prodrug. When exposed to NIR laser irradiation, the hybrid micelles can trigger notable tumor penetration and cytosol release of DOX payload by inducing tunable hyperthermia effect. In combination with localized NIR laser irradiation, the hybrid micelles significantly inhibit the growth of DOX‐resistant MCF‐7/ADR breast cancer in an orthotopic tumor bearing mouse model. Taken together, this pH and NIR light‐responsive micelles with hyperthermia‐triggered tumor penetration and cytoplasm drug release can be an effective nanoplatform to combat cancer MDR.     

A Drug‐Self‐Gated Mesoporous Antitumor Nanoplatform Based on pH‐Sensitive Dynamic Covalent Bond

To achieve on‐demand drug release, mesoporous silica nanocarriers as antitumor platforms generally need to be gated with stimuli‐responsive capping agents. Herein, a “smart” mesoporous nanocarrier that is gated by the drug itself through a pH‐sensitive dynamic benzoic–imine covalent bond is demonstrated. The new system, which tactfully bypasses the use of auxiliary capping agents, could also exhibit desirable drug release at tumor tissues/cells and enhanced tumor inhibition. Moreover, a facile dynamic PEGylation via benzoic–imine bond further endows the drug‐self‐gated nanocarrier with tumor extracellular pH‐triggered cell uptake and improves therapeutic efficiency in vivo. In short, the paradigm shift in capping agents here will simplify mesoporous nanomaterials as intelligent drug carriers for cancer therapy. Moreover, the self‐gated strategy in this work also shows general potential for self‐controlled delivery of natural biomolecules, for example, DNA/RNA, peptides, and proteins, due to their intrinsic amino groups.     

Programmed Multiresponsive Vesicles for Enhanced Tumor Penetration and Combination Therapy of Triple‐Negative Breast Cancer

Nanomedicine is a promising approach for combination chemotherapy of triple‐negative breast cancer (TNBC). However, the therapeutic efficacy of nanoparticulate drugs is suppressed by a series of biological barriers. The authors herein present a programmed stimuli‐responsive liposomal vesicle to overcome the sequential barriers for enhanced TNBC therapy. The intelligent vesicles are engineered by integrating an enzyme‐cleavable polyethylene glycol (PEG) corona, a light‐responsive photosensitizer pheophorbide a (PPa), and a temperature‐sensitive liposome (TSL) into a single nanoplatform. The resultant enzyme, light, and temperature multisensitive liposome (ELTSL) is sequentially coloaded with a lipophilic oxaliplatin prodrug of hexadecyl‐oxaliplatin carboxylic acid (HOC) and hydrophilic doxorubicin hydrochloride (DOX). Dual drug‐loaded ELTSL displays enhanced tumor penetration and increased cellular uptake upon matrix metalloproteinase 2 mediated cleavage of the PEG corona. Under NIR laser irradiation, PPa induces mild hyperthermia effect to trigger ultrafast drug release in the tumor cells. In combination with PPa‐mediated photodynamic therapy, HOC and DOX coloaded ELTSL show significantly improved antitumor efficacy than monotherapy. Given the clinically translatable potential of the liposomal vesicles, ELTSL might represent a promising nanoplatform for combination TNBC therapy.     

6‐Mercaptopurine‐Induced Fluorescence Quenching of Monolayer MoS2 Nanodots: Applications to Glutathione Sensing,Cellular Imaging,and Glutathione‐Stimulated Drug Delivery

Molybdenum disulfide (MoS₂) nanodots (NDs) with sulfur vacancies have been demonstrated to be suitable to conjugate thiolated molecules. However, thiol‐induced fluorescence quenching of MoS₂ NDs has been rarely explored. In this study, 6‐mercaptopurine (6‐MP) serves as an efficient quencher for the fluorescence of monolayer MoS₂ (M‐MoS₂) NDs. 6‐MP molecules are chemically adsorbed at the sulfur vacancy sites of the M‐MoS₂ NDs. The formed complexes trigger the efficient fluorescence quenching of the M‐MoS₂ NDs due to acceptor‐excited photoinduced electron transfer. The presence of glutathione (GSH) efficiently triggers the release of 6‐MP from the M‐MoS₂ NDs, thereby switching on the fluorescence of the M‐MoS₂ NDs. Thus, the 6‐MP‐M‐MoS₂ NDs are implemented as a platform for the sensitive and selective detection of GSH in erythrocytes and live cells. Additionally, thiolated doxorubicin (DOX‐SH)‐loaded M‐MoS₂ NDs (DOX‐SH/M‐MoS₂ NDs) serve as GSH‐responsive nanocarriers for DOX‐SH delivery. In vitro studies reveal that the DOX‐SH/M‐MoS₂ NDs exhibit efficient uptake by HeLa cells and greater cytotoxicity than free DOX‐SH and DOX. In vivo study shows that GSH is capable of triggering the release of DOX‐SH from M‐MoS₂ ND‐based nanomaterials in mice. It is revealed that the DOX‐SH/M‐MoS₂ NDs can be implemented for simultaneous drug delivery and fluorescence imaging.