Smart Carbon Nanotubes with Laser‐Controlled Behavior in Gene Delivery and Therapy through a Non‐Digestive Trafficking Pathway

Near‐infrared (NIR) laser‐controlled gene delivery presents some benefits in gene therapy, inducing enhanced gene transfection efficiency. In this study, a “photothermal transfection” agent is obtained by wrapping poly(ethylenimine)‐cholesterol derivatives (PEI‐Chol) around single‐walled carbon nanotubes (SWNTs). The PEI‐Chol modified SWNTs (PCS) are effective in compressing DNA molecules and protecting them from DNaseI degradation. Compared to the complexes formed by PEI with DNA (PEI/DNA), complexes of PCS and DNA that are formed (PCS/DNA) exhibit a little lower toxicity to HEK293 and HeLa cells under the same PEI molecule weight and weight ratios. Notably, caveolae‐mediated cellular uptake of PCS/DNA occurs, which results in a safer intracellular transport of the gene due to the decreased lysosomal degradation in comparison with that of PEI/DNA whose internalization mainly depends on clathrin rather than caveolae. Furthermore, unlike PEI/DNA, PCS/DNA exhibits a photothermal conversion ability, which promotes DNA release from PCS under NIR laser irradiation. The NIR laser‐mediated photothermal transfection of PCS_10K/plasmid TP53 (pTP53) results in more apoptosis and necrosis of HeLa cells in vitro than other groups, and achieves a higher tumor‐growth inhibition in vivo than naked pTP53, PEI_25K/pTP53, and PCS_10K/pTP53 alone. The enhanced transfection efficiency of PCS/DNA can be attributed to more efficient DNA internalization into the tumor cells, promotes detachment of DNA from PCS under the mediation of NIR laser and higher DNA stability in the cells due to caveolae‐mediated cellular uptake of the complexes.     

J‐Aggregates of Organic Dye Molecules Complexed with Iron Oxide Nanoparticles for Imaging‐Guided Photothermal Therapy Under 915‐nm Light

Recently, the development of nano‐theranostic agents aiming at imaging guided therapy has received great attention. In this work, a near‐infrared (NIR) heptamethine indocyanine dye, IR825, in the presence of cationic polymer, polyallylamine hydrochloride (PAH), forms J‐aggregates with red‐shifted and significantly enhanced absorbance. After further complexing with ultra‐small iron oxide nanoparticles (IONPs) and the followed functionalization with polyethylene glycol (PEG), the obtained IR825@PAH‐IONP‐PEG composite nanoparticles are highly stable in different physiological media. With a sharp absorbance peak, IR825@PAH‐IONP‐PEG can serve as an effective photothermal agent under laser irradiation at 915 nm, which appears to be optimal in photothermal therapy application considering its improved tissue penetration compared with 808‐nm light and much lower water heating in comparison to 980‐nm light. As revealed by magnetic resonance (MR) imaging, those nanoparticles after intravenous injection exhibit high tumor accumulation, which is then harnessed for in vivo photothermal ablation of tumors, achieving excellent therapeutic efficacy in a mouse tumor model. This study demonstrates for the first time that J‐aggregates of organic dye molecules are an interesting class of photothermal material, which when combined with other imageable nanoprobes could serve as a theranostic agent for imaging‐guided photothermal therapy of cancer.     

Water‐Dispersible Candle Soot–Derived Carbon Nano‐Onion Clusters for Imaging‐Guided Photothermal Cancer Therapy

Herein, water‐dispersible carbon nano‐onion clusters (CNOCs) with an average hydrodynamic size of ≈90 nm are prepared by simply sonicating candle soot in a mixture of oxidizing acid. The obtained CNOCs have high photothermal conversion efficiency (57.5%), excellent aqueous dispersibility (stable in water for more than a year without precipitation), and benign biocompatibility. After polyethylenimine (PEI) and poly(ethylene glycol) (PEG) modification, the resultant CNOCs‐PEI‐PEG have a high photothermal conversion efficiency (56.5%), and can realize after‐wash photothermal cancer cell ablation due to their ultrahigh cellular uptake (21.3 pg/cell), which is highly beneficial for the selective ablation of cancer cells via light‐triggered intracellular heat generation. More interestingly, the cellular uptake of CNOCs‐PEI‐PEG is so high that the internalized nanoagents can be directly observed under a microscope without fluorescent labeling. Besides, in vivo experiments reveal that CNOCs‐PEI‐PEG can be used for photothermal/photoacoustic dual‐modal imaging‐guided photothermal therapy after intravenous administration. Furthermore, CNOCs‐PEI‐PEG can be efficiently cleared from the mouse body within a week, ensuring their excellent long‐term biosafety. To the best of the authors' knowledge, the first example of using candle soot as raw material to prepare water‐dispersible onion‐like carbon nanomaterials for cancer theranostics is represented herein.     

Programmable NIR‐II Photothermal‐Enhanced Starvation‐Primed Chemodynamic Therapy using Glucose Oxidase‐Functionalized Ancient Pigment Nanosheets

Chemodynamic therapy (CDT) has attracted considerable attention recently, but the poor reaction kinetics restrict its practical utility in clinic. Herein, glucose oxidase (GOx) functionalized ancient pigment nanosheets (SrCuSi₄O₁₀, SC) for programmable near‐infrared II (NIR‐II) photothermal‐enhanced starvation primed CDT is developed. The SC nanosheets (SC NSs) are readily exfoliated from SC bulk suspension in water and subsequently functionalized with GOx to form the nanocatalyst (denoted as SC@G NSs). Upon laser irradiation, the photothermal effect of SC NSs can enhance the catalytic activity of GOx for NIR‐II photothermal‐enhanced starvation therapy, which effectively eliminates intratumoral glucose and produces abundant hydrogen peroxide (H₂O₂). Importantly, the high photothermal‐conversion efficiency (46.3%) of SC@G NSs in second biological window permits photothermal therapy of deep‐seated tumors under the guidance of NIR‐II photoacoustic imaging. Moreover, the acidity amplification due to gluconic acid generation will in turn accelerate the degradation of SC NSs, facilitating the release of strontium (Sr) and copper (Cu) ions. Both the elevated H₂O₂ and the released ions will prime the Cu²⁺/Sr²⁺‐H₂O₂ reaction for enhanced CDT. Thus, a programmable NIR‐II photothermal‐enhanced starvation primed CDT is established to combat cancer with minimal side effects.     

Glutathione Depletion in a Benign Manner by MoS2‐Based Nanoflowers for Enhanced Hypoxia‐Irrelevant Free‐Radical‐Based Cancer Therapy

Tumor hypoxia significantly diminishes the efficacy of reactive oxygen species (ROS)‐based therapy, mainly because the generation of ROS is highly oxygen dependent. Recently reported hypoxia‐irrelevant radical initiators (AIBIs) exhibit promising potential for cancer therapy under different oxygen tensions. However, overexpressed glutathione (GSH) in cancer cells would potently scavenge the free radicals produced from AIBI before their arrival to the specific site and dramatically limit the therapeutic efficacy. A synergistic antitumor platform (MoS₂@AIBI‐PCM nanoflowers) is constructed by incorporating polyethylene‐glycol‐functionalized molybdenum disulfide (PEG‐MoS₂) nanoflowers with azo initiator and phase‐change material (PCM). Under near‐infrared laser (NIR) irradiation, the photothermal feature of PEG‐MoS₂ induces the decomposition of AIBI to produce free radicals. Furthermore, PEG‐MoS₂ can facilitate GSH oxidation without releasing toxic metal ions, greatly promoting tumor apoptosis and avoiding the introduction of toxic metal ions. This is the first example of the use of intelligent MoS₂‐based nanoflowers as a benign GSH scavenger for enhanced cancer treatment.     

Photothermally Controlled Gene Delivery by Reduced Graphene Oxide–Polyethylenimine Nanocomposite

Externally stimuli‐triggered spatially and temporally controlled gene delivery can play a pivotal role in achieving targeted gene delivery with maximized therapeutic efficacy. In this study, a photothermally controlled gene delivery carrier is developed by conjugating low molecular‐weight branched polyethylenimine (BPEI) and reduced graphene oxide (rGO) via a hydrophilic polyethylene glycol (PEG) spacer. This PEG–BPEI–rGO nanocomposite forms a stable nano‐sized complex with plasmid DNA (pDNA), as confirmed by physicochemical studies. For the in vitro gene transfection study, PEG–BPEI–rGO shows a higher gene transfection efficiency without observable cytotoxicity compared to unmodified controls in PC‐3 and NIH/3T3 cells. Moreover, the PEG–BPEI–rGO nanocomposite demonstrates an enhanced gene transfection efficiency upon NIR irradiation, which is attributed to accelerated endosomal escape of polyplexes augmented by locally induced heat. The endosomal escaping effect of the nanocomposite is investigated using Bafilomycin A1, a proton sponge effect inhibitor. The developed photothermally controlled gene carrier has the potential for spatial and temporal site‐specific gene delivery.     

Sub‐10‐nm Pd Nanosheets with Renal Clearance for Efficient Near‐Infrared Photothermal Cancer Therapy

Efficient renal clearance is of fundamentally important property of nanoparticles for their in vivo biomedical applications. In this work, we report the successful synthesis of ultra‐small Pd nanosheets (SPNS) with an average diameter of 4.4 nm and their application in photothermal cancer therapy using a near infrared laser. The ultra‐small Pd nanosheets have strong optical absorption in the NIR region and high photothermal conversion efficiency (52.0%) at 808 nm. After being surface‐functionalized with reduced glutathione (GSH), the SPNS‐GSH was administered to mice to investigate the biodistribution, photothermal efficacy and tumor ablation in vivo. The in vivo photothermal therapy studies clearly demonstrate that surface modification with GSH allows the nanosheets to exhibit prolonged blood circulation and thus high accumulation in tumors. Upon 808 nm NIR irradiation, the tumors can be completely ablated. More importantly, with the size below the renal filtration limit (<10 nm), the GSHylated Pd nanosheets can be nicely cleared from body through the renal excretion route and into urine. Together with the high efficacy of NIR photothermal therapy, the unique renal clearance properties make the ultra‐small Pd nanosheets promising for practical use in photothermal cancer therapy.     

Dual‐Peak Absorbing Semiconducting Copolymer Nanoparticles for First and Second Near‐Infrared Window Photothermal Therapy: A Comparative Study

Near‐infrared (NIR) light is widely used for noninvasive optical diagnosis and phototherapy. However, current research focuses on the first NIR window (NIR‐I, 650–950 nm), while the second NIR window (NIR‐II, 1000–1700 nm) is far less exploited. The development of the first organic photothermal nanoagent (SPN_I‐II) with dual‐peak absorption in both NIR windows and its utilization in photothermal therapy (PTT) are reported herein. Such a nanoagent comprises a semiconducting copolymer with two distinct segments that respectively and identically absorb NIR light at 808 and 1064 nm. With the photothermal conversion efficiency of 43.4% at 1064 nm generally higher than other inorganic nanomaterials, SPN_I‐II enables superior deep‐tissue heating at 1064 nm over that at 808 nm at their respective safety limits. Model deep‐tissue cancer PTT at a tissue depth of 5 mm validates the enhanced antitumor effect of SPN_I‐II when shifting laser irradiation from the NIR‐I to the NIR‐II window. The good biodistribution and facile synthesis of SPN_I‐II also allow it to be doped with an NIR dye for fluorescence‐imaging‐guided NIR‐II PTT through systemic administration. Thus, this study paves the way for the development of new polymeric nanomaterials to advance phototherapy.     

Direct Reprogramming of Human Suspension Cells into Mesodermal Cell Lineages via Combined Magnetic Targeting and Photothermal Stimulation by Magnetic Graphene Oxide Complexes

Suspension cells can provide a source of cells for cellular reprogramming, but they are difficult to transfect by nonviral vectors. An efficient and safe nonviral vector (GO‐Fe₃O₄‐PEI complexes) based on iron oxide nanoparticle (Fe₃O₄)‐decorated graphene oxide (GO) complexed with polyethylenimine (PEI) for the first time is developed for delivering three individual episomal plasmids (pCXLE‐hOCT3/4‐shp53, pCXLE‐hSK, and pCXLE‐hUL) encoding pluripotent‐related factors of Oct3/4, shRNA against p53, Sox2, Klf4, L‐Myc, and Lin28 into human peripheral blood mononuclear cells (PBMCs) simultaneously. The combined treatment of magnetic stirring and near‐infrared (NIR)‐laser irradiation, which can promote contact between the complexes and floating cells and increase the cell membrane permeability, respectively, is used to conduct multiple physical stimulations for suspension PBMCs transfection. The PCR analysis shows that the combinatorial effect of magnetic targeting and photothermal stimulation obviously promoted the transfection efficiency of suspension cells. The transfected cells show positive expression of the pluripotency markers, including Nanog, Oct4, and Sox2, and have potential to differentiate into mesoderm and ectoderm cells. The results demonstrate that the GO‐Fe₃O₄‐PEI complex provides a safe, convenient, and efficient tool for reprogramming PBMCs into partially induced pluripotent stem cells, which are able to rapidly transdifferentiate into mesodermal lineages without full reprogramming.     

Multifunctional RbxWO3 Nanorods for Simultaneous Combined Chemo‐photothermal Therapy and Photoacoustic/CT Imaging

Light‐triggered drug delivery based on near‐infrared (NIR)‐mediated photothermal nanocarriers has received tremendous attention for the construction of cooperative therapeutic systems in nanomedicine. Herein, a new paradigm of light‐responsive drug carrier that doubles as a photothermal agent is reported based on the NIR light‐absorber, Rb _x WO₃ (rubidium tungsten bronze, Rb‐TB) nanorods. With doxorubicin (DOX) payload, the DOX‐loaded Rb‐TB composite (Rb‐TB‐DOX) simultaneously provides a burst‐like drug release and intense heating effect upon 808‐nm NIR light exposure. MTT assays show the photothermally enhanced antitumor activity of Rb‐TB‐DOX to the MCF‐7 cancer cells. Most remarkably, Rb‐TB‐DOX combined with NIR irradiation also shows dramatically enhanced chemotherapeutic effect to DOX‐resistant MCF‐7 cells compared with free DOX, demonstrating the enhanced efficacy of combinational chemo‐photothermal therapy for potentially overcoming drug resistance in cancer chemotherapy. Furthermore, in vivo study of combined chemo‐photothermal therapy is also conducted and realized on pancreatic (Pance‐1) tumor‐bearing nude mice. Apart from its promise for cancer therapy, the as‐prepared Rb‐TB can also be employed as a new dual‐modal contrast agent for photoacoustic tomography and (PAT) X‐ray computed tomography (CT) imaging because of its high NIR optical absorption capability and strong X‐ray attenuation ability, respectively. The results presented in the current study suggest promise of the multifunctional Rb _x WO₃ nanorods for applications in cancer theranostics.     

Graphene Nanomesh Promises Extremely Efficient In Vivo Photothermal Therapy

Reduced graphene oxide nanomesh (rGONM), as one of the recent structures of graphene with a surprisingly strong near‐infrared (NIR) absorption, is used for achieving ultraefficient photothermal therapy. First, by using TiO₂ nanoparticles, graphene oxide nanoplatelets (GONPs) are transformed into GONMs through photocatalytic degradation. Then rGONMs functionalized by polyethylene glycol (PEG), arginine–glycine–aspartic acid (RGD)‐based peptide, and cyanine 7 (Cy7) are utilized for in vivo tumor targeting and fluorescence imaging of human glioblastoma U87MG tumors having α_νβ₃ integrin receptors, in mouse models. The rGONM‐PEG suspension (1 μg mL^?1) exhibits about 4.2‐ and 22.4‐fold higher NIR absorption at 808 nm than rGONP‐PEG and graphene oxide (GO) with lateral dimensions of ≈60 nm and ≈2 μm. In vivo fluorescence imaging demonstrates high selective tumor uptake of rGONM‐PEG‐Cy7‐RGD in mice bearing U87MG cells. The excellent NIR absorbance and tumor targeting of rGONM‐PEG‐Cy7‐RGD results in an ultraefficient photothermal therapy (100% tumor elimination 48 h after intravenous injection of an ultralow concentration (10 μg mL^?1) of rGONM‐PEG‐Cy7‐RGD followed by irradiation with an ultralow laser power (0.1 W cm^?2) for 7 min), whereas the corresponding rGO‐ and rGONP‐based composites do not present remarkable treatments under the same conditions. All the mice treated by rGONM‐PEG‐Cy7‐RGD survived over 100 days, whereas the mice treated by other usual rGO‐based composites were dead before 38 days. The results introduce rGONM as one of the most promising nanomaterials in developing highly desired ultraefficient photothermal therapy.     

Multifunctional Mesoporous Silica Nanoparticles with Thermal‐Responsive Gatekeeper for NIR Light‐Triggered Chemo/Photothermal‐Therapy

In this work, a matrix metalloproteinase (MMP)‐triggered tumor targeted mesoporous silica nanoparticle (MSN) is designed to realize near‐infrared (NIR) photothermal‐responsive drug release and combined chemo/photothermal tumor therapy. Indocyanine green (ICG) and doxorubicin (DOX) are both loaded in the MSN modified with thermal‐cleavable gatekeeper (Azo‐CD), which can be decapped by ICG‐generated hyperthermia under NIR illumination. A peptidic sequence containing a short PEG chain, matrix metalloproteinase (MMP) substrate (PLGVR) and tumor cell targeting motif (RGD) are further decorated on the MSN via a host–guest interaction. The PEG chain can protect the MSN during the circulation and be cleaved off in the tumor tissues with overexpressed MMP, and then the RGD motif is switched on to target tumor cells. After the tumor‐triggered targeting process, the NIR irradiation guided by ICG fluorescence can trigger cytosol drug release and realize combined chemo/photothermal therapy.     

Laser‐Ignited Relay‐Domino‐Like Reactions in Graphene Oxide/CL‐20 Films for High‐Temperature Pulse Preparation of Bi‐Layered Photothermal Membranes

Light‐ignited combustions have been proposed for a variety of industrial and scientific applications. They suffer, however, from ultrahigh light ignition thresholds and poor self‐propagating combustion of typical high‐energy density materials, e.g., 2,4,6,8,10,12‐(hexanitrohexaaza)cyclododecane (CL‐20). Here, reported is that both light ignition and combustion performance of CL‐20 are greatly enhanced by embedding ε‐CL‐20 particles in a graphene oxide (GO) matrix. The GO matrix yields a drastic temperature rise that is sufficient to trigger the combustion of GO/CL‐20 under low laser irradiation (35.6 mJ) with only 6 wt% of GO. The domino‐like reduction‐combustion of the GO matrix can serve as a relay and deliver the decomposition‐combustion of CL‐20 to its neighbor sites, forming a relay‐domino‐like reaction. In particular, a synergistic reaction between GO and CL‐20 occurrs, facilitating more energy release of the GO/CL‐20 composite. The novel relay‐domino‐like reaction coupled with the synergistic reaction of CL‐20 and GO results in a deflagration of the material, which generates a high‐temperature pulse (HTP) that can be guided to produce advanced functional materials. As a proof of concept, a bi‐layered photothermal membrane is prepared by HTP treatment in an extremely simple and fast way, which can serve as a model architecture for efficient interfacial water evaporation.     

Near‐Infrared Light Triggers Release of Paclitaxel from Biodegradable Microspheres: Photothermal Effect and Enhanced Antitumor Activity

Despite advances in controlled drug delivery, reliable methods for activatable, high‐resolution control of drug release are needed. The hypothesis that the photothermal effect mediated by a near‐infrared (NIR) laser and hollow gold nanospheres (HAuNSs) could modulate the release of anticancer agents is tested with biodegradable and biocompatible microspheres (1–15 µm) containing the antitumor drug paclitaxel (PTX) and HAuNSs (≈35 nm in diameter), which display surface plasmon absorbance in the NIR region. HAuNS‐containing microspheres exhibit a NIR‐induced thermal effect similar to that of plain HAuNSs. Rapid, repetitive PTX release from the PTX/HAuNS‐containing microspheres is observed upon irradiation with NIR light (808 nm), whereas PTX release is insignificant when the NIR light is switched off. The release of PTX from the microspheres is readily controlled by the output power of the NIR laser, duration of irradiation, treatment frequency, and concentration of HAuNSs embedded inside the microspheres. In vitro, cancer cells incubated with PTX/HAuNS‐loaded microspheres and irradiated with NIR light display significantly greater cytotoxic effects than cells incubated with the microspheres alone or cells irradiated with NIR light alone, owing to NIR‐light‐triggered drug release. Treatment of human U87 gliomas and MDA‐MB‐231 mammary tumor xenografts in nude mice with intratumoral injections of PTX/HAuNS‐loaded microspheres followed by NIR irradiation results in significant tumor‐growth delay compared to tumors treated with HAuNS‐loaded microspheres (no PTX) and NIR irradiation or with PTX/HAuNS‐loaded microspheres alone. The data support the feasibility of a therapeutic approach in which NIR light is used for simultaneous modulation of drug release and induction of photothermal cell killing.     

Somatostatin Receptor‐Mediated Tumor‐Targeting Nanocarriers Based on Octreotide‐PEG Conjugated Nanographene Oxide for Combined Chemo and Photothermal Therapy

Nano‐sized in vivo active targeting drug delivery systems have been developed to a high anti‐tumor efficacy strategy against certain cancer‐cells‐specific. Graphene based nanocarriers with unique physical and chemical properties have shown significant potentials in this aspect. Here, octreotide (OCT), an efficient biotarget molecule, is conjugated to PEGylated nanographene oxide (NGO) drug carriers for the first time. The obtained NGO‐PEG‐OCT complex shows low toxicity and excellent stability in vivo and is able to achieve somatostatin receptor‐mediated tumor‐specific targeting delivery. Owing to the high loading efficiency and accurate targeting delivery of anti‐cancer drug doxorubicin (DOX), our DOX loaded NGO‐PEG‐OCT complex offers a remarkably improved cancer‐cell‐specific cellular uptake, chemo‐cytotoxicity, and decreased systemic toxicity compared to free DOX or NGO‐PEG. More importantly, due to its strong near‐infrared absorption, the NGO‐PEG‐OCT complex further enhances efficient photothermal ablation of tumors, delivering combined chemo and photothermal therapeutic effect against cancer cells.     

A Rationally Designed Semiconducting Polymer Brush for NIR‐II Imaging‐Guided Light‐Triggered Remote Control of CRISPR/Cas9 Genome Editing

The clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR‐associated protein 9 (Cas9) genome‐editing system has shown great potential in biomedical applications. Although physical approaches, viruses, and some nonviral vectors have been employed for CRISPR/Cas9 delivery and induce some promising genome‐editing efficacy, precise genome editing remains challenging and has not been reported yet. Herein, second near‐infrared window (NIR‐II) imaging‐guided NIR‐light‐triggered remote control of the CRISPR/Cas9 genome‐editing strategy is reported based on a rationally designed semiconducting polymer brush (SPPF). SPPF can not only be a vector to deliver CRISPR/Cas9 cassettes but also controls the endolysosomal escape and payloads release through photothermal conversion under laser irradiation. Upon laser exposure, the nanocomplex of SPPF and CRISPR/Cas9 cassettes induces effective site‐specific precise genome editing both in vitro and in vivo with minimal toxicity. Besides, NIR‐II imaging based on SPPF can also be applied to monitor the in vivo distribution of the genome‐editing system and guide laser irradiation in real time. Thus, this study offers a typical paradigm for NIR‐II imaging‐guided NIR‐light‐triggered remote control of the CRISPR/Cas9 system for precise genome editing. This strategy may open an avenue for CRISPR/Cas9 genome‐editing‐based precise gene therapy in the near future.     

Multibuilding Block Janus Synthesized by Seed‐Mediated Self‐Assembly for Enhanced Photothermal Effects and Colored Brownian Motion in an Optical Trap

The asymmetrical features and unique properties of multibuilding block Janus nanostructures (JNSs) provide superior functions for biomedical applications. However, their production process is very challenging. This problem has hampered the progress of JNS research and the exploration of their applications. In this study, an asymmetrical multibuilding block gold/iron oxide JNS has been generated to enhance photothermal effects and display colored Brownian motion in an optical trap. JNS is formed by seed‐mediated self‐assembly of nanoparticle‐loaded thermocleavable micelles, where the hydrophobic backbones of the polymer are disrupted at high temperatures, resulting in secondary self‐assembly and structural rearrangement. The JNS significantly enhances photothermal effects compared to their homogeneous counterpart after near‐infrared (NIR) light irradiation. The asymmetrical distribution of gold and iron oxide within JNS also generates uneven thermophoretic force to display active colored Brownian rotational motion in a single‐beam gradient optical trap. These properties indicate that the asymmetrical JNS could be employed as a strong photothermal therapy mediator and a fuel‐free nanoscale Janus motor under NIR light.     

Flexible Photothermal Assemblies with Tunable Gold Patterns for Improved Imaging‐Guided Synergistic Therapy

Self‐assembly of gold nanoparticles demonstrates a promising approach to realize enhanced photoacoustic imaging (PAI) and photothermal therapy (PTT) for accurate diagnosis and efficient cancer therapy. Herein, unique photothermal assemblies with tunable patterns of gold nanoparticles (including arcs, rings, ribbons, and vesicles) on poly(lactic‐co‐glycolic acid) (PLGA) spheres are constructed taking advantage of emulsion‐confined and polymer‐directed self‐assembly strategies. The influencing factors and formation mechanism to produce the assemblies are investigated in details. Both the emulsion structure and migration behaviors of amphiphilic block copolymer tethered gold nanoparticles are found to contribute to the formation of versatile photothermal assemblies. Hyaluronic acid‐modified R‐PLGA‐Au (RPA) exhibits outstanding photothermal performances under NIR laser irradiation, which is induced by strong plasmonic coupling between adjacent gold nanoparticles. It is interesting that secondary assembly of RPA can be triggered by NIR laser irradiation. Prolonged residence time in tumors is achieved after RPA assemblies are fused into superstructures with larger sizes, realizing real‐time monitoring of the therapeutic processes via PAI with enhanced photoacoustic signals. Notably, synergistic effect resulting from PTT‐enhanced chemotherapy is realized to demonstrate high antitumor performance. This work provides a facile strategy to construct flexible photothermal assemblies with favorable properties for imaging‐guided synergistic therapy.     

Intracellular Imaging with a Graphene‐Based Fluorescent Probe

Graphene is an increasingly important nanomaterial that has shown great promise in the area of nanotechnology. In this study, fluorescein‐functionalized graphene oxide (GO) is synthesized via a polyethylene glycol (PEG) bridge and its application in intracellular imaging is explored. GO is an oxide form of graphene that provides an ideal platform to prepare graphene‐based functional nanomaterials via chemical modification. The PEG bridge was introduced to prevent GO‐induced quenching of conjugated fluorescein. The fluorescein–PEG–GO conjugate thus prepared exhibits excellent pH‐tunable fluorescent properties and, more significantly, can be efficiently taken up by cells and serve as a fluorescent nanoprobe for intracellular imaging.     

Rhenium‐188 Labeled Tungsten Disulfide Nanoflakes for Self‐Sensitized,Near‐Infrared Enhanced Radioisotope Therapy

Radioisotope therapy (RIT), in which radioactive agents are administered or implanted into the body to irradiate tumors from the inside, is a clinically adopted cancer treatment method but still needs improvement to enhance its performances. Herein, it is found that polyethylene glycol (PEG) modified tungsten disulfide (WS₂) nanoflakes can be easily labeled by ¹⁸⁸Re, a widely used radioisotope for RIT, upon simple mixing. Like other high‐Z elements acting as radiosensitizers, tungsten in the obtained ¹⁸⁸Re‐WS₂‐PEG would be able to absorb ionization radiation generated from ¹⁸⁸Re, enabling ‘‘self‐sensitization’’ to enhance the efficacy of RIT as demonstrated in carefully designed in vitro experiments of this study. In the meanwhile, the strong NIR absorbance of WS₂‐PEG could be utilized for NIR light‐induced photothermal therapy (PTT), which if applied on tumors would be able to greatly relieve their hypoxia state and help to overcome hypoxia‐associated radioresistance of tumors. Therefore, with ¹⁸⁸Re‐WS₂‐PEG as a multifunctional agent, which shows efficient passive tumor homing after intravenous injection, in vivo self‐sensitized, NIR‐enhanced RIT cancer treatment is realized, achieving excellent tumor killing efficacy in a mouse tumor model. This work presents a new concept of applying nanotechnology in RIT, by delivering radioisotopes into tumors, self‐sensitizing the irradiation‐induced cell damage, and modulating the tumor hypoxia state to further enhance the therapeutic outcomes.