Biodegradable Nanoparticles of Polyacrylic Acid–Stabilized Amorphous CaCO3 for Tunable pH‐Responsive Drug Delivery and Enhanced Tumor Inhibition

Inorganic nanoparticles (NPs) are promising drug delivery carriers owing to their high drug loading efficiency, scalable preparation, facile functionalization, and chemical/thermal stability. However, the clinical translation of inorganic nanocarriers is often hindered by their poor biodegradability and lack of controlled pH response. Herein, a fully degradable and pH‐responsive DOX@ACC/PAA NP (pH 7.4–5.6) is developed by encapsulating doxorubicin (DOX) in poly(acrylic acid) (PAA) stabilized amorphous calcium carbonate (ACC) NPs. The DOX‐loaded NPs have small sizes (62 ± 10 nm), good serum stability, high drug encapsulation efficiency (>80%), and loading capacity (>9%). By doping proper amounts of Sr²⁺ or Mg²⁺, the drug release of NPs can be further modulated to higher pH responsive ranges (pH 7.7–6.0), which enables drug delivery to the specific cell domains of tissues with a less acidic microenvironment. Tumor inhibition and lower drug acute toxicity are further confirmed via intracellular uptake tests and zebrafish models, and the particles also improve pharmacokinetics and drug accumulation in mouse xenograft tumors, leading to enhanced suppression of tumor growth. Owing to the excellent biocompatibility, biodegradability, and tunable drug release behavior, the present hybrid nanocarrier may find broad applications in tumor therapy.     

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.     

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.     

Biocompatible D–A Semiconducting Polymer Nanoparticle with Light‐Harvesting Unit for Highly Effective Photoacoustic Imaging Guided Photothermal Therapy

The development of nanotheranostic agents that integrate diagnosis and therapy for effective personalized precision medicine has obtained tremendous attention in the past few decades. In this report, biocompatible electron donor–acceptor conjugated semiconducting polymer nanoparticles (PPor‐PEG NPs) with light‐harvesting unit is prepared and developed for highly effective photoacoustic imaging guided photothermal therapy. To the best of our knowledge, it is the first time that the concept of light‐harvesting unit is exploited for enhancing the photoacoustic signal and photothermal energy conversion in polymer‐based theranostic agent. Combined with additional merits including donor–acceptor pair to favor electron transfer and fluorescence quenching effect after NP formation, the photothermal conversion efficiency of the PPor‐PEG NPs is determined to be 62.3%, which is the highest value among reported polymer NPs. Moreover, the as‐prepared PPor‐PEG NP not only exhibits a remarkable cell‐killing ability but also achieves 100% tumor elimination, demonstrating its excellent photothermal therapeutic efficacy. Finally, the as‐prepared water‐dispersible PPor‐PEG NPs show good biocompatibility and biosafety, making them a promising candidate for future clinical applications in cancer theranostics.     

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.     

Gold Nanorods Electrostatically Binding Nucleic Acid Probe for In Vivo MicroRNA Amplified Detection and Photoacoustic Imaging‐Guided Photothermal Therapy

Developing a comprehensive platform which has both diagnosis and therapeutic strategies is necessary for efficient tumor treatment. In this work, a F uel I mproved micro R NA E xplorer (FIRE) probe with signal amplification capability is designed for sensitive detection of microRNA‐21 (miR‐21), which is upregulated in most tumor cells. Besides, FIRE could be loaded by polyethylenimine (PEI)‐modified gold nanorods (AuNR‐PEI) via facile electrostatic interaction, which could avoid the complicated processes commonly used to covalently conjugate nucleic acid probes onto AuNRs. The as‐fabricated AuNR‐PEI/FIRE system could efficiently distinguish tumor cells from non‐tumor cells. The fluorescence signals in MCF‐7 breast carcinoma and HeLa cervical carcinoma cells treated with AuNR‐PEI/FIRE are enhanced 7‐ and 4.5‐fold, respectively, compared with non‐amplification system. AuNR‐PEI/FIRE improves tumor detection ability in vivo and exhibits excellent tumor inhibition efficacy under the fluorescence imaging and photoacoustic imaging guided photothermal therapy. This is the first time to utilize the combined application of amplified nucleic acid detection and photothermal effect derived from gold nanorods together with PA imaging in a facile manner to provide a promising theranostic strategy for accurate diagnosis and tumor therapy.     

Phenylboronic Acid‐Decorated Chondroitin Sulfate A‐Based Theranostic Nanoparticles for Enhanced Tumor Targeting and Penetration

Phenylboronic acid‐functionalized chondroitin sulfate A (CSA)–deoxycholic‐acid (DOCA)‐based nanoparticles (NPs) are prepared for tumor targeting and penetration. (3‐Aminomethylphenyl)boronic acid (AMPB) is conjugated to CSA–DOCA conjugate via amide bond formation, and its successful synthesis is confirmed using proton nuclear magnetic resonance spectroscopy (¹H‐NMR). Doxorubicin (DOX)‐loaded CSA–DOCA–AMPB NPs with a mean diameter of ≈200 nm, a narrow size distribution, negative zeta potential, and spherical morphology are prepared. DOX release from NPs is enhanced at acidic pH compared to physiological pH. CSA–DOCA–AMPB NPs exhibit improved cellular uptake in A549 (human lung adenocarcinoma) cells and penetration into A549 multicellular spheroids compared to CSA–DOCA NPs as evidenced by confocal laser scanning microscopy and flow cytometry. In vivo tumor targeting and penetrating by CSA–DOCA–AMPB NPs, based on both CSA–CD44 receptor and boronic acid–sialic acid interactions, is revealed using near‐infrared fluorescence (NIRF) imaging. Penetration of NPs to the core of the tumor mass is observed in an A549 tumor xenografted mouse model and verified by three‐dimensional NIRF imaging. Multiple intravenous injections of DOX‐loaded CSA–DOCA–AMPB NPs efficiently inhibit the growth of A549 tumor in the xenografted mouse model and increase apoptosis. These boronic acid‐rich NPs are promising candidates for cancer therapy and imaging.     

Polymer‐Coated Radioluminescent Nanoparticles for Quantitative Imaging of Drug Delivery

Some theranostic nanoparticle (NP) drug delivery systems are capable of measuring drug release rates in situ. This can provide quantitative information regarding drug biodistribution, and drug dose that is delivered to cells or tissues. Here, X‐ray excited optical luminescent (XEOL) NPs coated with poly(glycolide)‐poly(ethylene glycol) (XGP) are used measure the amount of drug released into cells. The photoactive drug protoporphyrin IX (PpIX) is loaded into XGP and is able to attenuate the XEOL NP emission. Measuring an increase in XEOL intensity as PpIX is released enables the measurement of drug release into glioblastoma cells (GBM). Biodistribution studies in a BALB/c mouse GBM intracranial xenograft model show significant XGP accumulation at the site of the GBM xenograft within the brain, and not in adjacent healthy brain tissues. There is no uptake of XGP in the heart or kidneys, the primary organs associated with drug and gadolinium ion toxicity. NP toxicity is tested with U‐138MG GBM in vitro, and NPs show low cytotoxicity at concentrations of 100 μg/mL. In vivo dose escalation studies in BALB/c mice show no adverse effects at doses up to 75 mg/kg. These theranostic NPs offer an approach to quantitatively measure drug release into cells.     

Ultrasmall Confined Iron Oxide Nanoparticle MSNs as a pH‐Responsive Theranostic Platform

A unique mesoporous silica nanoparticles (MSNs)‐based theranostic platform with ultrasmall iron oxide nanoparticles (NPs) confined within mesopore network has been developed by a facile but efficient physical‐vapor‐infiltration (PVI) method. The highly dispersed Fe species within mesopore channels can synchronously function as the non‐toxic contrast agents for highly efficient T₁‐weighted MR imaging, and as anchoring sites for anti‐cancer drug molecule loading and pH‐responsive release based on the special metal‐ligand coordination bonding between the Fe species and drug molecules. Moreover, the obtained Fe‐MSNs exhibit favorable biocompatibility, enhanced chemotherapeutic efficacy and concurrently diminished side effects due to the non‐specific attack of chemotherapeutic drugs, as well as the capability in circumventing the multidrug resistance (MDR) of cancer cells and suppressing the metastasis of tumor cells in vitro and in vivo. This pH‐resoponsive theranostic agent provides a new promising MSNs‐based anti‐cancer nanomedicine for future biomedical application.     

Multi‐Caged IrOx for Facile Preparation of “Six‐in‐One” Nanoagent for Subcutaneous and Lymphatic Tumors Inhibition against Recurrence and Metastasis

Single nanocarriers with intrinsic characteristics of diagnosis, effective therapy against solid malignancies with fatal metastasis, and tumor microenvironment regulation are promising in construction of a simple and effective multimode nanotheranostic system. Herein, multi‐caged IrO_x nanocarriers are fabricated by direct thermal hydrolysis strategy, which exhibit good sono‐photodynamic response, outstanding gemstone spectral computed tomography, and photoacoustic (PA) imaging capabilities, universal loading, and pinpoint drug release properties. As a proof of concept, a gemstone spectral computed tomography/PA/fluorescence imaging–guided oxygen self‐sufficient sono‐photo‐chemotherapy nanoagent by simple loading of doxorubicin is constructed. The remarkable synergistic therapy and excellent hypoxia releasing capabilities can remove both subcutaneous and sentinel lymph nodes metastasis tumors, and effectively suppress tumor recurrence and lung metastasis, thus greatly prolonging survival time. The study provides an attractive candidate to construct a “six‐in‐one” (tri‐modal therapies and three imaging modalities) tumor theranostic system.     

Engineering Versatile Nanoparticles for Near‐Infrared Light‐Tunable Drug Release and Photothermal Degradation of Amyloid β

Nanomedicines that inhibit/disassemble amyloid β (Aβ) aggregates in Alzheimer's disease (AD) are highly desirable yet remain challenging. Therapeutic efficacy and systemic delivery of reported molecules and nanoparticles (NPs) are hampered by various challenges, including low biocompatibility, off‐target toxicity, and lack of specificity. Herein, a versatile NP is designed by integrating high Aβ‐binding affinity, stimuli‐responsive drug release, and photothermal degradation properties for efficient disassembly of Aβ. Near‐infrared (NIR)‐absorbing conjugated polymer PDPP3T‐O14 serves as a photothermal core while thermal‐responsive polymer 1,2‐dipalmitoyl‐sn‐glycero‐3‐phosphocholine at the outer layer as the NIR‐stimuli gatekeeper. Curcumin, an inhibitor of Aβ aggregation, is loaded into the NP with high encapsulation efficiency. The 5‐mer β‐sheet breaker peptides LPFFD (Leu‐Pro‐Phe‐Phe‐Asp) having high binding affinity toward Aβ are further anchored onto the surface of polyethylene glycol‐lipid shell for active Aβ‐targeting. The resultant NPs exhibit good Aβ‐targeting ability and obvious photothermal dissociation effect together with Aβ aggregation‐dependent fluorescence detection capability. Upon NIR laser irradiation, entrapped curcumin can be effectively released from the unconsolidated NPs to enhance the anti‐amyloid activity. In vitro studies demonstrate that the NPs dramatically lower Aβ‐induced cytotoxicity of PC12 cells, and therefore show great potential for the application in AD treatment.     

Ultralong Circulating Lollipop‐Like Nanoparticles Assembled with Gossypol,Doxorubicin, and Polydopamine via π–π Stacking for Synergistic Tumor Therapy

Long blood circulation in vivo remains a challenge to dual‐drug‐loaded nanocarriers for synergistic chemotherapy. Herein, a novel strategy to prepare lollipop‐like dual‐drug‐loaded nanoparticles (DOX–PDA–gossypol NPs) is developed based on the self‐assembly of gossypol, doxorubicin (DOX), and polydopamine (PDA) via π–π stacking. Dopamine polymerizes to PDA and fills the gaps between the gossypol and DOX molecules to form the super compact long‐circulating nanoparticles. The DOX–PDA–gossypol NPs show a suitable particle size of 59.6 ± 9.6 nm, high drug loading of 91%, superb stability, high maximum‐tolerated dose (MTD) of over 60 mg kg^‐1, and negligible toxicity. These NPs also exhibit pH‐dependent drug release and low combination index (0.23). Notably, they show dramatically ultralong blood circulation (>192 h) with elimination half times 458‐fold and 258‐fold longer than that of free DOX and free gossypol, respectively. These values are markedly higher than most of the reported results. Therefore, the DOX–PDA–gossypol NPs have a high tumor accumulation of 12% remaining on the 8th day postinjection. This characteristic contributes to the excellent tumor comprehensive synergistic therapeutic efficacy (TIR > 90%) with low administration dosage and is benefitted for widening the drug therapeutic window. Thus, the proposed strategy has remarkable potential for tumor synergistic therapy.     

A Versatile Nanotheranostic Agent for Efficient Dual‐Mode Imaging Guided Synergistic Chemo‐Thermal Tumor Therapy

The integration of efficient imaging for diagnosis and synergistic tumor therapy into a single‐component nanoplatform is much promising for high efficacy tumor treatment but still in a great challenge. Herein, a smart and versatile nanotheranostic platform based on hollow mesoporous Prussian blue nanoparticles (HMPBs) with perfluoropentane (PFP) and doxorubicin (DOX) inside, has been designed, for the first time, to achieve the distinct in vivo synergistic chemo‐thermal tumor therapy and synchronous diagnosis and monitoring by ultrasound (US)/photoacoustic (PA) dual mode imaging. The prepared HMPBs show excellent photothermal conversion properties with large molar extinction coefficient (≈1.2 × 10¹¹m ^?1 cm^?1) and extremely high photothermal conversion efficiency (41.4%). Such a novel theranostic nanoplatform is expected to overcome the inevitable tumor recurrence and metastasis resulting from the inhomogeneous ablation of single thermal therapy, which will find a promising prospect in the application of noninvasive cancer therapy.     

Redox‐Responsive and Drug‐Embedded Silica Nanoparticles with Unique Self‐Destruction Features for Efficient Gene/Drug Codelivery

The development of advanced gene/drug codelivery carriers with stimuli‐responsive release manner for complementary cancer therapy is desirable. In this study, novel disulfide‐bridged and doxorubicin (DOX)‐embedded degradable silica nanoparticles (DS‐DOX) with unique self‐destruction features are synthesized by a facile one‐pot method. In order to realize codelivery of genes and drugs, the surface of DS‐DOX nanoparticles is readily functionalized with the assembled polycation (CD‐PGEA), comprising one β‐cyclodextrin core and two ethanolamine‐functionalized poly(glycidyl methacrylate) arms, to achieve DS‐DOX‐PGEA. The redox‐responsive self‐destruction behavior of DS‐DOX imparts DS‐DOX‐PGEA with a better ability to release anticancer drug DOX, while the low‐toxic hydroxyl‐rich CD‐PGEA brushes can efficiently deliver genes for cancer treatment. Very interestingly, the degradation process of DS‐DOX starts from the outside, while the destruction of the degradable silica (DS) nanoparticles without DOX begins from the center of the nanoparticles. The embedded DOX inside the DS‐DOX nanoparticles can significantly influence the structures and facilitate the cellular uptake and the subsequent gene transfection. The as‐developed DS‐DOX‐PGEA nanostructure with coordinating biodegradability, stimuli‐responsiveness, and controlled release manner might be desirable gene/drug codelivery carriers for clinical cancer treatment.     

A Hybrid Carrier System Based on Origami Nanostrucutures and Layer‐by‐Layer Microparticles

Recent progress in DNA nanotechnology allows the fabrication of 3D structures that can be loaded with a large variety of molecular cargos and even be responsive to external stimuli. This makes the use of DNA nanostructures a promising approach for applications in nanomedicine and drug delivery. However, their low stability in the extra‐ and intracellular environment as well as low cellular uptake rates and release rates from endosomes into the cytoplasm hamper the efficient and targeted use of DNA nanostructures in medical applications. Here, such major obstacles are overcome by integrating DNA origami nanostructures into superordinated layer‐by‐layer based microparticles made from biopolymers. The modular assembly of the polymer layer allows a high‐density incorporation of the DNA structures at different depth. This enables controllable protection of the DNA nanostructures over extended durations in a broad range of extra‐ and intracellular conditions without compromising the cell viability. Furthermore, by producing protein‐complexed DNA nanostructures it is demonstrated that molecular cargo can be conveniently integrated into the developed hybrid system. This work provides the basis for a new multistage carrier system allowing for an efficient and protected transport of active agents inside responsive DNA nanostructures.     

Actively Targeted Deep Tissue Imaging and Photothermal‐Chemo Therapy of Breast Cancer by Antibody‐Functionalized Drug‐Loaded X‐Ray‐Responsive Bismuth Sulfide@Mesoporous Silica Core–Shell Nanoparticles

A theranostic platform combining synergistic therapy and real‐time imaging attracts enormous attention but still faces great challenges, such as tedious modifications and lack of efficient accumulation in tumor. Here, a novel type of theranostic agent, bismuth sulfide@mesoporous silica (Bi₂S₃@mPS) core‐shell nanoparticles (NPs), for targeted image‐guided therapy of human epidermal growth factor receptor‐2 (HER‐2) positive breast cancer is developed. To generate such NPs, polyvinylpyrrolidone decorated rod‐like Bi₂S₃ NPs are chemically encapsulated with a mesoporous silica (mPS) layer and loaded with an anticancer drug, doxorubicin. The resultant NPs are then chemically conjugated with trastuzumab (Tam, a monoclonal antibody targeting HER‐2 overexpressed breast cancer cells) to form Tam‐Bi₂S₃@mPS NPs. By in vitro and in vivo studies, it is demonstrated that the Tam‐Bi₂S₃@mPS bear multiple desired features for cancer theranostics, including good biocompatibility and drug loading ability as well as precise and active tumor targeting and accumulation (with a bismuth content in tumor being ≈16 times that of nontargeted group). They can simultaneously serve both as an excellent contrast enhancement probe (due to the presence of strong X‐ray‐attenuating bismuth element) for computed tomography deep tissue tumor imaging and as a therapeutic agent to destruct tumors and prevent metastasis by synergistic photothermal‐chemo therapy.     

Smart Tumor Microenvironment‐Responsive Nanotheranostic Agent for Effective Cancer Therapy

The tumor microenvironment (TME), which includes acidic and hypoxic conditions, severely impedes the therapeutic efficacy of antitumor agents. Herein, MnO₂‐loaded, bovine serum albumin, and PEG co‐modified mesoporous CaSiO₃ nanoparticles (CaM‐PB NPs) are developed as a nanoplatform with sequential theranostic functions for the engineering of TME. The MnO₂ NPs generate O₂ in situ by reacting with endogenous H₂O₂, relieving the hypoxic state of the TME that further modulates the cancer cell cycle status to S phase, which improves the potency of co‐loaded S phase‐sensitive chemotherapeutic drugs. After the hypoxia relief, CaM‐PB can sustainably release drugs due to the enlarged pores of mesoporous CaSiO₃ in the acidic TME, preventing the drug pre‐leakage into the blood circulation and insufficient drug accumulation at tumor sites. Moreover, the Mn²⁺ released from the MnO₂ NPs at tumor sites can potentially serve as a diagnostic agent, enabling the identification of tumor regions by T₁‐weighted magnetic resonance imaging during therapy. In vivo pharmacodynamics results demonstrate that these synergetic effects caused by CaM‐PB NPs significantly contribute to the inhibition of tumor progression. Therefore, the CaM‐PB NPs with sequential theranostic functions are a promising system for effective cancer therapy.     

A Biocompatible Free Radical Nanogenerator with Real‐Time Monitoring Capability for High Performance Sequential Hypoxic Tumor Therapy

Hypoxic microenvironment severely reduces therapeutic efficacy of oxygen‐dependent photodynamic therapy in solid tumor due to the hampered cytotoxic oxygen radicals generation. Herein, a biocompatible nanoparticle (NP) is developed by combining bovine serum albumin, indocyanine green (ICG), and an oxygen‐independent radicals generator (AIPH) for efficient sequential cancer therapy, denoted as BIA NPs. Upon near‐infrared irradiation, the photothermal effect generated by ICG will induce rapid decomposition of AIPH to release cytotoxic alkyl radicals, leading to cancer cell death in both normoxic and hypoxic environments. Moreover, such nanosystem provides the highest AIPH loading capacity (14.9%) among all previously reported radical nanogenerators (generally from 5–8%). Additionally, the aggregation‐quenched fluorescence of ICG molecules in the NPs can be gradually released and recovered upon irradiation enabling real‐time drug release monitoring. More attractively, these BIA NPs exhibit remarkable anticancer effects both in vitro and in vivo, achieving 100% tumor elimination and 100% survival rate among 50 days treatment. These results highlight that this albumin‐based nanoplatform is promising for high‐performance cancer therapy circumventing hypoxic tumor environment and possessing great potential for future clinical translation.     

Silver‐Nanowire‐Based Interferometric Optical Tweezers for Enhanced Optical Trapping and Binding of Nanoparticles

Light‐induced self‐assembly offers a new route to build mesoscale optical matter arrays from nanoparticles (NPs), yet the low stability of optical matter systems limits the assembly of large‐scale NP arrays. Here it is shown that the interferometric optical fields created by illuminating a single Ag nanowire deposited on a coverslip can enhance the electrodynamic interactions among NPs. The Ag nanowire serves as a plasmonic antenna to shape the incident laser beam and guide the optical assembly of colloidal metal (Ag and Au) and dielectric (polystyrene) NPs in solution. By controlling the laser polarization direction, both the mesoscale interactions among multiple NPs and the near‐field coupling between the NPs and nanowire can be tuned, leading to large‐scale and stable optical matter arrays consisting of up to 60 NPs. These results demonstrate that single Ag nanowires can serve as multifunctional antennas to guide the optical trapping and binding of multiple NPs and provide a new strategy to control electrodynamic interactions using hybrid nanostructures.     

pH/Cathepsin B Hierarchical‐Responsive Nanoconjugates for Enhanced Tumor Penetration and Chemo‐Immunotherapy

An ideal cancer nanomedicine should precisely deliver therapeutics to its intracellular target within tumor cells. However, the multiple biological barriers seriously hinder their delivery efficiency, leading to unsatisfactory therapeutic outcome. Herein, pH/cathepsin B hierarchical‐responsive nanoconjugates (HRNs) are reported to overcome these barriers by sequentially responding to extra‐ and intracellular stimuli in solid tumors for programmed delivery of docetaxel (DTX). The HRNs have stable nanostructures (≈40 nm) in blood circulation for efficient tumor accumulation, while the tumor extracellular acidity induces the rapid dissociation of HRNs into polymer conjugates (≈5 nm), facilitating the deep tumor penetration and cellular internalization. After being trapped into the lysosomes, the conjugates are cleaved by cathepsin B to release bioactive DTX into cytoplasm and inhibit cell proliferation. In addition to the direct inhibition effect, HRNs can trigger the in vivo antitumor immune responses via the immunogenic modulation of tumor cells, activation of dendritic cells (DCs), and generation of cytotoxic T‐cell responses. By employing a combination with α‐PD‐1 (programmed cell death 1) therapy, synergistic antitumor efficacy is achieved in B16 expressing ovalbumin (B16OVA) tumor model. Hence, this strategy demonstrates high efficiency for precise intracellular delivery of chemotherapeutics and provides a potential clinical candidate for cancer chemo‐immunotherapy.