Photo‐Induced Charge‐Variable Conjugated Polyelectrolyte Brushes Encapsulating Upconversion Nanoparticles for Promoted siRNA Release and Collaborative Photodynamic Therapy under NIR Light Irradiation

Combination of photodynamic therapy (PDT) with small interfering RNA (siRNA) therapy has become a major strategy in cancer treatment for enhancing anticancer efficacy. However, developing nanoplatform that can promote siRNA release and collaborate with efficient PDT under NIR light irradiation is still a big challenge. Photo‐induced charge‐variable conjugated polyelectrolyte brushes encapsulating upconversion nanoparticles (UCNP@CCPEB) as an efficient nanoplatform are reported. Cationic conjugated polyelectrolyte brush (CCPEB) is synthesized through quaternary ammoniation of N‐functionalized polyfluorene brush by photodegradable 2‐nitrobenzyl‐2‐bromoacetate. CCPEB with abundant positive charges and intrinsic photosensitizer (PS) performance is good for integrating siRNA carrier and PS into one molecule. The obtained CCPEB next encapsulates upconversion nanoparticle for realizing its NIR light excitation. Agarose gel electrophoresis experiments show that UCNP@CCPEB present good stability and excellent siRNA‐loading capacity (1 mol UCNP@CCPEB to at least 32.5 mol siRNA). Under 980 nm light irradiation, UCNP@CCPEB exhibit efficient single oxygen production for PDT. Concurrently, the photoresponsive cationic side‐chain of CCPEB turns into zwitterionic chain and thus accelerates its siRNA release to 80%. In vitro and in vivo experiments show that the successful A549 tumor suppression is achieved by UCNP@CCPEB/siPlk1 complex under 980 irradiation. It is envisioned that UCNP@CCPEB can serve as an efficient platform for combining various phototherapies together.     

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.     

A New Single 808 nm NIR Light‐Induced Imaging‐Guided Multifunctional Cancer Therapy Platform

The NIR light‐induced imaging‐guided cancer therapy is a promising route in the targeting cancer therapy field. However, up to now, the existing single‐modality light‐induced imaging effects are not enough to meet the higher diagnosis requirement. Thus, the multifunctional cancer therapy platform with multimode light‐induced imaging effects is highly desirable. In this work, captopril stabilized‐Au nanoclusters Au₂₅(Capt)₁₈?(Au₂₅) are assembled into the mesoporous silica shell coating outside of Nd³⁺‐sensitized upconversion nanoparticles (UCNPs) for the first time. The newly formed Au₂₅ shell exhibits considerable photothermal effects, bringing about the photothermal imaging and photoacoustic imaging properties, which couple with the upconversion luminescence imaging. More importantly, the three light‐induced imaging effects can be simultaneously achieved by exciting with a single NIR light (808 nm), which is also the triggering factor for the photothermal and photodynamic cancer therapy. Besides, the nanoparticles can also present the magnetic resonance and computer tomography imaging effects due to the Gd³⁺ and Yb³⁺ ions in the UCNPs. Furthermore, due to the photodynamic and the photothermal effects, the nanoparticles possess efficient in vivo tumor growth inhibition under the single irradiation of 808 nm light. The multifunctional cancer therapy platform with multimode imaging effects realizes a true sense of light‐induced imaging‐guided cancer 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.     

Gold Nanoshell Nanomicelles for Potential Magnetic Resonance Imaging,Light‐Triggered Drug Release,and Photothermal Therapy

A novel multifunctional drug‐delivery platform is developed based on cholesteryl succinyl silane (CSS) nanomicelles loaded with doxorubicin, Fe₃O₄ magnetic nanoparticles, and gold nanoshells (CDF‐Au‐shell nanomicelles) to combine magnetic resonance (MR) imaging, magnetic‐targeted drug delivery, light‐triggered drug release, and photothermal therapy. The nanomicelles show improved drug‐encapsulation efficiency and loading level, and a good response to magnetic fields, even after the formation of the gold nanoshell. An enhancement for T₂‐weighted MR imaging is observed for the CDF‐Au‐shell nanomicelles. These nanomicelles display surface plasmon absorbance in the near‐infrared (NIR) region, thus exhibiting an NIR (808 nm)‐induced temperature elevation and an NIR light‐triggered and stepwise release behavior of doxorubicin due to the unique characteristics of the CSS nanomicelles. Photothermal cytotoxicity in vitro confirms that the CDF‐Au‐shell nanomicelles cause cell death through photothermal effects only under NIR laser irradiation. Cancer cells incubated with CDF‐Au‐shell nanomicelles show a significant decrease in cell viability only in the presence of both NIR irradiation and a magnetic field, which is attributed to the synergetic effects of the magnetic‐field‐guided drug delivery and the photothermal therapy. Therefore, such multicomponent nanomicelles can be developed as a smart and promising nanosystem that integrates multiple capabilities for effective cancer diagnosis and therapy.     

A Multi‐synergistic Platform for Sequential Irradiation‐Activated High‐Performance Apoptotic Cancer Therapy

Artificial hyperthermia is an emerging technique to induce apoptotic cancer cell death. However, achieving effective hyperthermic apoptosis is often difficult, as cells typically acquire resistance to thermal stress. With the aid of sequential irradiation, highly integrated nanoassemblies based on reduced graphene oxide–ZnO nanoparticles–hyaluronic acid (rGo‐ZnO‐HA) can serve as a multi‐synergistic platform for targeted high‐performance apoptotic cancer therapy. The surface engineering of ZnO/graphene hybrid with multifunctional HA biomacromolecules simultaneously confers the system colloidal stability, biocompatibility, and a cancer cell targeting ability. After receptor‐mediated endocytosis, enzyme‐mediated fluorescence activation helps track cellular uptake and provides truly molecular imaging. Furthermore, the reactive oxygen species (ROS) generated by ZnO/rGo under light illumination can effectively sensitize cancer cells to the subsequent NIR laser‐induced apoptotic hyperthermia. In particular, photo modulation of cellular ROS to sensitize cells provides a novel approach to increase the efficacy of hyperthermic apoptosis. These findings suggest that a powerful apoptotic therapeutic platform could be achieved based on the multi‐synergistic platform.     

An O2 Self‐Supplementing and Reactive‐Oxygen‐Species‐Circulating Amplified Nanoplatform via H2O/H2O2 Splitting for Tumor Imaging and Photodynamic Therapy

Conventional photodynamic therapy (PDT) has limited applications in clinical cancer therapy due to the insufficient O₂ supply, inefficient reactive oxygen species (ROS) generation, and low penetration depth of light. In this work, a multifunctional nanoplatform, upconversion nanoparticles (UCNPs)@TiO₂@MnO₂ core/shell/sheet nanocomposites (UTMs), is designed and constructed to overcome these drawbacks by generating O₂ in situ, amplifying the content of singlet oxygen (¹O₂) and hydroxyl radical (?OH) via water‐splitting, and utilizing 980 nm near‐infrared (NIR) light to increase penetration depth. Once UTMs are accumulated at tumor site, intracellular H₂O₂ is catalyzed by MnO₂ nanosheets to generate O₂ for improving oxygen‐dependent PDT. Simultaneously, with the decomposition of MnO₂ nanosheets and 980 nm NIR irradiation, UCNPs can efficiently convert NIR to ultraviolet light to activate TiO₂ and generate toxic ROS for deep tumor therapy. In addition, UCNPs and decomposed Mn²⁺ can be used for further upconversion luminescence and magnetic resonance imaging in tumor site. Both in vitro and in vivo experiments demonstrate that this nanoplatform can significantly improve PDT efficiency with tumor imaging capability, which will find great potential in the fight against tumor.     

Fabricating Aptamer‐Conjugated PEGylated‐MoS2/Cu1.8S Theranostic Nanoplatform for Multiplexed Imaging Diagnosis and Chemo‐Photothermal Therapy of Cancer

Fabricating theranostic nanoparticles combining multimode disease diagnosis and therapeutic has become an emerging approach for personal nanomedicine. However, the diagnostic capability, biocompatibility, and therapeutic efficiency of theranostic nanoplatforms limit their clinic widespread applications. Targeting to the theme of accurate diagnosis and effective therapy of cancer cells, a multifunctional nanoplatform of aptamer and polyethylene glycol (PEG) conjugated MoS₂ nanosheets decorated with Cu_1.8S nanoparticles (ATPMC) is developed. The ATPMC nanoplatform accomplishes photoluminescence imaging, photoacoustic imaging, and photothermal imaging for in vitro and in vivo tumor cells imaging diagnosis. Meanwhile, the ATPMC nanoplatform facilitates selective delivery of gene probe to detect intracellular microRNA aberrantly expressed in cancer cells and anticancer drug doxorubicin (DOX) for chemotherapy. Moreover, the synergistic interaction of MoS₂ and Cu_1.8S renders the ATPMC nanoplatform with superb photothermal conversion efficiency. The ATPMC nanoplatform loaded with DOX displays near‐infrared laser‐induced programmed chemotherapy and advanced photothermal therapy, and the targeted chemo‐photothermal therapy presents excellent antitumor efficiency.     

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.     

Near‐Infrared Photoregulated Drug Release in Living Tumor Tissue via Yolk‐Shell Upconversion Nanocages

Phototrigger‐controlled drug‐release devices (PDDs) can be conveniently manipulated by light to obtain on‐demand release patterns, thereby affording an improved therapeutic efficacy. However, no example of the PDDs has been demonstrated beyond the cellular level to date. By loading 7‐amino‐coumarin derivative caged anticancer drug chlorambucil to yolk–shell structured nanocages possessing upconversion nanophosphors (UCNPs) as moveable core and silica as mesoporous shell, a near‐infrared (NIR)‐regulated PDD is successfully created. In vitro experiments demonstrate that drug release from the PDD could be triggered by continuous‐wave 980 nm light in a controlled pattern. The PDD could be taken up by cancer cells and release the drug to kill cancer cells upon NIR irradiation. Further in vivo studies demonstrate that the PDD can effectively response the NIR stimuli in living tissue. This is the first example of successful NIR‐regulated drug release in living animal model. Such achievement resolves the problem of low tissue penetration depth for traditional PDDs by adopting UCNPs as an NIR light switcher, which gives impetus to practical applications.     

A Near‐Infrared Light‐Triggered Nanocarrier with Reversible DNA Valves for Intracellular Controlled Release

A near‐infrared (NIR) light‐triggered nanocarrier is developed for intracellular controlled release with good stability, high nuclease resistance, and good biocompatibility. The nanocarrier consists of a gold nanorod core and mesoporous silica shell, capped with reversible single‐stranded DNA valves, which are manipulated by switching between the laser on/off states. Upon laser irradiation, the valves of the nanocarrier open and the cargo molecules can be released from the mesopores. When the NIR laser is turned off, the valves close and the nanocarrier stops releasing the cargo molecules. The release amount of the cargo molecules can be controlled precisely by adjusting the irradiation time and the laser on‐off cycles. Confocal fluorescence imaging shows that the nanocarrier can be triggered by the laser irradiation and the controlled release can be accomplished in living cells. Moreover, the therapeutic effect toward cancer cells can also be regulated when the chemotherapeutic drug doxorubicin is loaded into the nanocarrier. This novel approach provides an ideal platform for drug delivery by a NIR light‐activated mechanism with precise control of area, time, and especially dosage.     

A Multifunctional Nanoplatform against Multidrug Resistant Cancer: Merging the Best of Targeted Chemo/Gene/Photothermal Therapy

Synergistic therapy that combines chemo‐, gene‐, or photothermal means shows great potential for enhancing the therapeutic effects on cancers. Tumor‐targeted nanoparticles based on a doxorubicin (DOX)‐gated mesoporous silica nanocore (MSN) encapsulated with permeability glycoprotein (P‐gp) small interfering RNA (siRNA) and a polydopamine (PDA) outer layer for DOX loading and folic acid decoration are designed. The multifunctional nanoplatform tactfully integrates chemo‐ (DOX), gene‐ (P‐gp siRNA), and photothermal (PDA layer) substances in one system. In vitro results reveal that DOX release behaviors are both pH‐ and thermal‐responsive and the release of co‐delivered P‐gp siRNA is also pH‐dependent due to the pH‐cleavable DOX gatekeeper on MSN. In addition, due to the near‐infrared light‐responsive PDA outer layer and folic acid conjugation, the nanoparticles exhibit outstanding photothermal activity and selective cell targeting ability. Subsequently, in vitro and in vivo antitumor experiments both demonstrate the enhanced antitumor efficacy of the multifunctional nanoparticles, indicating the significance of synergistic therapy combining chemo‐, gene‐, and photothermal treatments in one system.     

Long‐Term Oxygen Storage Nanosystem for Near‐Infrared Light‐Triggered Oxygen Supplies to Antagonize Hypoxia‐Induced Therapeutic Resistance in Nasopharyngeal Carcinoma

O₂‐delivering nanosystems have been used to antagonize hypoxia‐induced tumor therapeutic resistance. However, short‐time oxygen storage is still a bottleneck for these O₂‐delivering nanosystems, which results in a decrease in blood circulation time and accumulation of oxygen in tumors, thus reducing the tumor therapeutic efficacy. Herein, a long‐term oxygen storage nanosystem (O₂‐PIr@Si@PDA) is designed to overcome hypoxia for the treatment of nasopharyngeal carcinoma. This nanosystem is constructed by using perfluorooctyl bromide (PFOB) core as the oxygen carrier, functionalized with an oxygen sensitive probe (Ir(III) complex) and subsequently enclosed with an ultrathin‐walled silica shell. Due to the silica shell, this nanosystem can store oxygen for longer than 7 days. The oxygen in the O₂‐PIr@Si@PDA nanosystem can be released quickly with the temperature‐responsive rupture of the silicon shell under near‐infrared (NIR) irradiation. The oxygen storage and release can be self‐monitored using the Ir(III) complex with its luminescence effect. As expected, this multifunctional nanosystem in combination with NIR irradiation not only inhibits tumor growth by alleviating hypoxia, but also enhances the effect of oxygen‐sensitized radiotherapy against nasopharyngeal carcinoma. Taken together, this study offers a novel strategy for designing long‐term oxygen storing nanosystem to relieve tumor hypoxia, thus improving the precise cancer therapeutic efficacy.     

SnTe@MnO2‐SP Nanosheet–Based Intelligent Nanoplatform for Second Near‐Infrared Light–Mediated Cancer Theranostics

Near infrared light, especially the second near‐infrared light (NIR II) biowindows with deep penetration and high sensitivity are widely used for optical diagnosis and phototherapy. Here, a novel kind of 2D SnTe@MnO₂‐SP nanosheet (NS)‐based nanoplatform is developed for cancer theranostics with NIR II‐mediated precise optical imaging and effective photothermal ablation of mouse xenografted tumors. The 2D SnTe@MnO₂‐SP NSs are fabricated via a facile method combining ball‐milling and liquid exfoliation for synthesis of SnTe NSs, and surface coating MnO₂ shell and soybean phospholipid (SP). The ultrathin SnTe@MnO₂‐SP NSs reveal notably high photothermal conversion efficiency (38.2% in NIR I and 43.9% in NIR II). The SnTe@MnO₂‐SP NSs inherently feature tumor microenvironment (TME)‐responsive biodegradability, and the main metabolite TeO₃^2? shows great antitumor effect, coupling synergetic chemotherapy for cancer. Moreover, the SnTe@MnO₂‐SP NSs also exhibit great potential for fluorescence, photoacoustic (PA), and photothermal imaging agents in the NIR II biowindow with much higher resolution and sensitivity. This is the first report, as far as is known, with such an inorganic nanoagent setting fluorescence/PA/photothermal imaging and photothermal therapy in NIR II biowindow and TME‐responsive biodegradability rolled into one, which provide insight into the clinical potential for cancer theranostics.     

High‐Yield Synthesis of Multifunctional Tellurium Nanorods to Achieve Simultaneous Chemo‐Photothermal Combination Cancer Therapy

Tellurium (Te) is an important semiconductor material with low band‐gap energy, which has attracted considerable attention in recent years, due to its special chemical and physical properties and wide potential in electrochemistry, optoelectronics, and biological fields. This study demonstrates a facile and high‐yield synthesis strategy of Te nanorods (PTW‐TeNRs) decorated by polysaccharide–protein complex, which can achieve simultaneous chemo‐photothermal combination therapy against cancers. PTW‐TeNRs alone possess high stability under physiological conditions, potent anticancer activities through induction of reactive oxygen species overproduction, and high selectivity among tumor and normal cells. More importantly, they exhibit strong near‐infrared (NIR) absorbance and good photothermal conversion ability from NIR light to heat energy. Furthermore, in combination with NIR laser irradiation, PTW‐TeNRs exhibit excellent chemo‐photothermal efficiency and low toxicity as evidenced by highly efficient tumor ablation ability, but show no obvious histological damage to the major organs. Taken together, this study provides a valid tactic for facile synthesis of multifunctional tellurium nanorods for efficient and combinational cancer therapy.     

Photoresponsive Protein–Graphene–Protein Hybrid Capsules with Dual Targeted Heat‐Triggered Drug Delivery Approach for Enhanced Tumor Therapy

A novel photo‐responsive protein–graphene–protein (PGP) capsule that doubles as a photothermal agent with core/shell structure is constructed by anchoring reduced graphene oxide nanosheets on one‐component protein (lactoferrin) shell through a double emulsion method. PGP capsules can transport fully concealed hydrophilic anticancer cargo, doxorubicin (Dox), with a large payload (9.43 μmol g^‐1) to be later unloaded in a burst‐like manner by photo‐actuation triggered by near‐infrared irradiation. Being biocompatible yet with a high cancer cell targeting efficiency, PGP capsules have successfully eradicated subcutaneous tumors in 10 d following a single 5 min NIR irradiation without distal damage. Besides, the photochemothermal therapy of PGP capsules eradicates tumor cells not only in the light‐treating area but also widely light‐omitted tumor cells, overcoming the tumor recurrence due to efficient cell killing efficacy. These results demonstrate that the PGP capsule is a potential new drug delivery platform for local‐targeting, on‐demand, photoresponsive, combined chemotherapy/hyperthermia for tumor treatment and other biomedical applications.     

Imaging‐Guided pH‐Sensitive Photodynamic Therapy Using Charge Reversible Upconversion Nanoparticles under Near‐Infrared Light

Photodynamic therapy (PDT) based on upconversion nanoparticles (UCNPs) can effectively destroy cancer cells under tissue‐penetrating near‐infrared light (NIR) light. Herein, we synthesize manganese (Mn²⁺)‐doped UCNPs with strong red light emission at ca. 660 nm under 980 nm NIR excitation to activate Chlorin e6 (Ce6), producing singlet oxygen (¹O₂) to kill cancer cells. A layer‐by‐layer (LbL) self‐assembly strategy is employed to load multiple layers of Ce6 conjugated polymers onto UCNPs via electrostatic interactions. UCNPs with two layers of Ce6 loading (UCNP@2xCe6) are found to be optimal in terms of Ce6 loading and ¹O₂ generation. By further coating UCNP@2xCe6 with an outer layer of charge‐reversible polymer containing dimethylmaleic acid (DMMA) groups and polyethylene glycol (PEG) chains, we obtain a UCNP@2xCe6‐DMMA‐PEG nanocomplex, the surface of which is negatively charged and PEG coated under pH 7.4; this could be converted to have a positively charged naked surface at pH 6.8, significantly enhancing cell internalization of nanoparticles and increasing in vitro NIR‐induced PDT efficacy. We then utilize the intrinsic optical and paramagnetic properties of Mn²⁺‐doped UCNPs for in vivo dual modal imaging, and uncover an enhanced retention of UCNP@2xCe6‐DMMA‐PEG inside the tumor after intratumoral injection, owing to the slightly acidic tumor microenvironment. Consequently, a significantly improved in vivo PDT therapeutic effect is achieved using our charge‐reversible UCNP@2xCe6‐DMMA‐PEG nanoparticles. Finally, we further demonstrate the remarkably enhanced tumor‐homing of these pH‐responsive charge‐switchable nanoparticles in comparison to a control counterpart without pH sensitivity after systemic intravenous injection. Our results suggest that UCNPs with finely designed surface coatings could serve as smart pH‐responsive PDT agents promising in cancer theranostics.     

Design and Synthesis of “All‐in‐One” Multifunctional FeS2 Nanoparticles for Magnetic Resonance and Near‐Infrared Imaging Guided Photothermal Therapy of Tumors

The ideal theranostic nanoplatform for tumors is a single nanoparticle that has a single semiconductor or metal component and contains all multimodel imaging and therapy abilities. The design and preparation of such a nanoparticle remains a serious challenge. Here, with FeS₂ as a model of a semiconductor, the tuning of vacancy concentrations for obtaining “all‐in‐one” type FeS₂ nanoparticles is reported. FeS₂ nanoparticles with size of ≈30 nm have decreased photoabsorption intensity from the visible to near‐infrared (NIR) region, due to a low S vacancy concentration. By tuning their shape/size and then enhancing the S vacancy concentration, the photoabsorption intensity of FeS₂ nanoparticles with size of ≈350 nm (FeS₂‐350) goes up with the increase of the wavelength from 550 to 950 nm, conferring the high NIR photothermal effect for thermal imaging. Furthermore, this nanoparticle has excellent magnetic properties for T₂‐weighted magnetic resonance imaging (MRI). Subsequently, FeS₂‐350 phosphate buffer saline (PBS) dispersion is injected into the tumor‐bearing mice. Under the irradiation of 915‐nm laser, the tumor can be ablated and the metastasis lesions in liver suffer significant inhibition. Therefore, FeS₂‐350 has great potential to be used as novel “all‐in‐one” multifunctional theranostic nanoagents for MRI and NIR dual‐modal imaging guided NIR‐photothermal ablation therapy (PAT) of tumors.     

Remotely Controlled Red Blood Cell Carriers for Cancer Targeting and Near‐Infrared Light‐Triggered Drug Release in Combined Photothermal–Chemotherapy

Red blood cells (RBCs), the “innate carriers” in blood vessels, are gifted with many unique advantages in drug transportation over synthetic drug delivery systems (DDSs). Herein, a tumor angiogenesis targeting, light stimulus‐responsive, RBC‐based DDS is developed by incorporating various functional components within the RBC platform. An albumin bound near‐infrared (NIR) dye, together with a chemotherapy drug doxorubicin, is encapsulated inside RBCs, the surfaces of which are modified with a targeting peptide to allow cancer targeting. Under stimulation by an external NIR laser, the membrane of the RBCs would be destroyed by the light‐induced photothermal heating, resulting in effective drug release. As a proof of principle, RBC‐based cancer cell targeted drug delivery and light‐controlled drug release is demonstrated in vitro, achieving a marked synergistic therapeutic effect through the combined photothermal–chemotherapy. This work presents a novel design of smart RBC carriers, which are inherently biocompatible, promising for targeted combination therapy of cancer.     

An Integrated Multifunctional Nanoplatform for Deep‐Tissue Dual‐Mode Imaging

The combination of biocompatible superparamagnetic and photoluminescent nanoparticles (NPs) is intensively studied as highly promising multifunctional (magnetic confinement and targeting, imaging, etc.) tools in biomedical applications. However, most of these hybrid NPs exhibit low signal contrast and shallow tissue penetration for optical imaging due to tissue‐induced optical extinction and autofluorescence, since in many cases, their photoluminescent components emit in the visible spectral range. Yet, the search for multifunctional NPs suitable for high photoluminescence signal‐to‐noise ratio, deep‐tissue imaging is still ongoing. Herein, a biocompatible core/shell/shell sandwich structured Fe₃O₄@SiO₂@NaYF₄:Nd³⁺ nanoplatform possessing excellent superparamagnetic and near‐infrared (excitation) to near‐infrared (emission), i.e., NIR‐to‐NIR photoluminescence properties is developed. They can be rapidly magnetically confined, allowing the NIR photoluminescence signal to be detected through a tissue as thick as 13 mm, accompanied by high T₂ relaxivity in magnetic resonance imaging. The fact that both the excitation and emission wavelengths of these NPs are in the optically transparent biological windows, along with excellent photostability, fast magnetic response, significant T₂‐contrast enhancement, and negligible cytotoxicity, makes them extremely promising for use in high‐resolution, deep‐tissue dual‐mode (optical and magnetic resonance) in vivo imaging and magnetic‐driven applications.