Enhanced Antitumor Efficacy by 808 nm Laser‐Induced Synergistic Photothermal and Photodynamic Therapy Based on a Indocyanine‐Green‐Attached W18O49 Nanostructure

A novel nanoplatform based on tungsten oxide (W₁₈O₄₉, WO) and indocyanine green (ICG) for dual‐modal photothermal therapy (PTT) and photodynamic therapy (PDT) has been successfully constructed. In this design, the hierarchical unique nanorod‐bundled W₁₈O₄₉ nanostructures play roles in being not only as an efficient photothermal agent for PTT but also as a potential nanovehicle for ICG molecules via electrostatic adsorption after modified with trimethylammonium groups on their surface. It is found that the ability of ICG to produce cytotoxic reactive oxygen species for PDT is well maintained after being attached on the WO, thus the as‐obtained WO@ICG can achieve a synergistic effect of combined PTT and PDT under single 808 nm near‐infrared (NIR) laser excitation. Notably, compared with PTT or PDT alone, the enhanced HeLa cells lethality of the 808 nm laser triggered dual‐modal therapy is observed. The in vivo animal experiments have shown that WO@ICG has effective solid tumor ablation effect with 808 nm NIR light irradiation, revealing the potential of these nanocomposites as a NIR‐mediated dual‐modal therapeutic platform for cancer treatment.     

An Iridium (III) Complex Bearing a Donor–Acceptor–Donor Type Ligand for NIR-Triggered Dual Phototherapy

Iridium(III) complexes are an important group of photosensitizers for photodynamic therapy (PDT). This work constructs a donor–acceptor–donor structure-based iridium(III) complex (IrDAD) with high reactive oxygen species (ROS) generation efficiency, negligible dark toxicity, and synergistic PDT and photothermal therapy (PTT) effect under near-infrared (NIR) stimulation. This complex self-assembles into metallosupramolecular aggregates with a unique aggregation-induced PDT behavior. Compared with conventional iridium(III) photosensitizers, IrDAD not only achieves NIR light deep tissue penetration but also shows highly efficient ROS and heat generation with ROS quantum yield of 14.6% and photothermal conversion efficiency of 27.5%. After conjugation with polyethylene glycol (PEG), IrDAD is formulated to a nanoparticulate system (IrDAD-NPs) with good solubility. In cancer phototherapy, IrDAD-NPs preferentially accumulate in tumor area and display a significant tumor inhibition in vivo, with 96% reduction in tumor volume, and even tumor elimination.     

Heptamethine Cyanine-Based Nanotheranostics with Catalase-Like Activity for Synergistic Phototherapy of Cancer

Single-molecule photosensitizers (PSs) for synergistic phototherapy are desirable but highly challenging, due to the competitive relationship between photothermal (PTT) and photodynamic therapy (PDT). Herein, a supramolecular strategy is developed that can tune the stacking pattern of PS molecules in their aggregates to optimize the PTT/PDT efficiency. Specifically, near-infrared (NIR) heptamethine cyanines (Cy7) are synthesized using tricyanofuran (TCF) as the acceptor and benzothiazole (BTH)/indole (IND) as the donor, where BTH is a less hydrogen-bonded tecton relative to IND. Both IND-Cy7-TCF and BTH-Cy7-TCF have similar photophysical properties at the molecular level, but BTH-Cy7-TCF in aggregated state exhibits higher singlet oxygen quantum yield (1.3% vs 0.2%) and competitive photothermal conversion efficiency (56.4% vs 62.3%) compared to IND-Cy7-TCF, due to the fine-tuning of hydrogen bonding and intermolecular π–π interactions to form loose molecular stacks. Interestingly, the unique molecular stacking structure provides a binding site and catalytic center for H₂O₂ that exhibits catalase-like activity, which can further ameliorate the efficiency of PDT and enhance the synergistic effect of PDT/PTT phototherapy in vitro and in vivo. This study can provide a simple but effective supramolecular strategy to design small molecule PSs with desirable aggregated structure for synergistic dual-mode phototherapy.     

Mitochondria‐Targeted Small‐Molecule Fluorophores for Dual Modal Cancer Phototherapy

Mitochondria are recognized as the ideal target for cancer treatment because they play a central role in oxidative metabolism and apoptosis. In this work, a mitochondria‐targeted near‐infrared (NIR) photosensitizer (PS) for synchronous cancer photodynamic therapy (PDT) and photothermal therapy (PTT) is synthesized. This multifunctional small‐molecule PS is developed from a variety of synthesized heptamethine cyanine dyes, which are modified with various N‐alkyl side chains on the lipophilic cationic heptamethine core. It is demonstrated to preferentially accumulate in cancer cells by organic‐anion transporting polypeptide mediated active transport and retain in mitochondria by its lipophilic cationic property. As mitochondria are susceptible to hyperthermia and excessive reactive oxygen species, this new PS integrating PTT and PDT treatment exhibits highly efficient phototherapy in multiple cancer cells and animal xenograft models. Furthermore, this targeted PS with NIR imaging property also enables tumors and their margins clearly visualized, providing the potential for precisely imaging‐guided phototherapy and treatment monitoring. This is the first report that a small‐molecule PS integrates both cancer PTT and PDT treatment by targeting mitochondria, significantly increasing the photosensitization. This work may also present a practicable strategy to develop small‐molecule‐based cancer theranostic agents for simultaneous cancer targeting, imaging, and therapy.     

Photostable Iodinated Silica/Porphyrin Hybrid Nanoparticles with Heavy‐Atom Effect for Wide‐Field Photodynamic/Photothermal Therapy Using Single Light Source

Physical therapies including photodynamic therapy (PDT) and photothermal therapy (PTT) can be effective against diseases that are resistant to chemotherapy and remain as incurable malignancies (for example, multiple myeloma). In this study, to enhance the treatment efficacy for multiple myeloma using the synergetic effect brought about by combining PDT and PTT, iodinated silica/porphyrin hybrid nanoparticles (ISP HNPs) with high photostability are developed. They can generate both ¹O₂ and heat with irradiation from a light‐emitting diode (LED), acting as photosensitizers for PDT/PTT combination treatment. ISP HNPs exhibit the external heavy atom effect, which significantly improves both the quantum yield for ¹O₂ generation and the light‐to‐heat conversion efficiency. The in vivo fluorescence imaging demonstrates that ISP HNPs, modified with folic acid and polyethylene glycol (FA‐PEG‐ISP HNPs), locally accumulate in the tumor after 18 h of their intravenous injection into tumor‐bearing mice. The LED irradiation on the tumor area of the mice injected with FA‐PEG‐ISP HNPs causes necrosis of the tumor tissues, resulting in the inhibition of tumor growth and an improvement in the survival rate.     

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.     

Bismuth Ferrite‐Based Nanoplatform Design: An Ablation Mechanism Study of Solid Tumor and NIR‐Triggered Photothermal/Photodynamic Combination Cancer Therapy

Although nanomaterial‐mediated phototherapy, in particular photothermal therapy (PTT) and photodynamic therapy (PDT), is extensively investigated in recent years, the ablation mechanism, evolution, and rehabilitation process of in vivo solid tumor after phototherapy are rarely explored yet and remain a terra incognita. Herein, a kind of bismuth ferrite nanoparticles (abbreviated as BFO NPs) are strategically designed and synthesized with a desirable size and bioactivity as a brand‐new phototherapeutic agent for the phototherapy, which are of strong near infrared (NIR) absorbance, excellent biocompatibility, and outstanding photophysical activity for the hyperthemia and reactive oxygen species generation. Resultantly, BFO NPs can realize simultaneous PTT/PDT synergistic therapy outcome against cancer cells and solid tumor under NIR laser irradiation. Meanwhile, for the first time, more attentions are paid to demonstrate ablation mechanism and evolution process of in vivo solid tumor after phototherapy by B‐mode ultrasonography/magnetic resonance imaging as well as histopathological analysis, all of which verify a series of physiological processes, being in order of necrosis of parenchymal cells, in situ tissue disintegration, liquefaction, and finally encapsulation process.     

A Novel Theranostic Nanoplatform Based on Pd@Pt‐PEG‐Ce6 for Enhanced Photodynamic Therapy by Modulating Tumor Hypoxia Microenvironment

Photodynamic therapy (PDT), which utilizes reactive oxygen species to kill cancer cells, has found wide applications in cancer treatment. However, the hypoxic nature of most solid tumors can severely restrict the efficiency of PDT. Meanwhile, the hydrophobicity and limited tumor selectivity of some photosensitizers also reduce their PDT efficacy. Herein, a photosensitizer‐Pd@Pt nanosystem (Pd@Pt‐PEG‐Ce6) is designed for highly efficient PDT by overcoming these limitations. In the nanofabrication, Pd@Pt nanoplates, exhibiting catalase‐like activity to decompose H₂O₂ to generate oxygen, are first modified with bifunctional PEG (SH‐PEG‐NH₂). Then the Pd@Pt‐PEG is further covalently conjugated with the photosensitizer chlorin e6 (Ce6) to get Pd@Pt‐PEG‐Ce6 nanocomposite. The Pd@Pt‐PEG‐Ce6 exhibits good biocompatibility, long blood circulation half‐life, efficient tumor accumulation, and outstanding imaging properties. Both in vitro and in vivo experimental results clearly indicate that Pd@Pt‐PEG‐Ce6 effectively delivers photosensitizers to cancer cells/tumor sites and triggers the decomposition of endogenous H₂O₂ to produce oxygen, resulting in a remarkably enhanced PDT efficacy. Moreover, the moderate photothermal effect of Pd@Pt nanoplates also strengthen the PDT of Pd@Pt‐PEG‐Ce6. Therefore, by integrating the merits of high tumor‐specific accumulation, hypoxia modulation function, and mild photothermal effect into a single nanoagent, Pd@Pt‐PEG‐Ce6 readily acts as an ideal nanotherapeutic platform for enhanced cancer PDT.     

Covalent Organic Framework‐Supported Molecularly Dispersed Near‐Infrared Dyes Boost Immunogenic Phototherapy against Tumors

Photodynamic therapy (PDT) mediated by near‐infrared (NIR) dyes is a promising cancer treatment modality; however, its use is limited by significant challenges, such as hypoxic tumor microenvironments and self‐quenching of photosensitizers. These challenges hamper its utility in inducing immunogenic cell death (ICD) and triggering potent systemic antitumor immune responses. This study demonstrates that molecular dispersion of NIR dyes in nanocarriers can significantly enhance their ability to produce reactive oxygen species and potentiate synergistic PDT and photothermal therapy against tumors. Specifically, NIR dye indocyanine green (ICG) can be spontaneously adsorbed to covalent organic frameworks (COFs) via π–π conjugations to prevent intermolecular stacking interactions. Then, ICG‐loaded COFs are ultrasonically exfoliated and coated with polydopamine (PDA) to construct a new phototherapeutic agent ICG@COF‐1@PDA with enhanced efficacy. In conjunction with ICG@COF‐1@PDA, a single round of NIR laser irradiation can induce obvious ICD, elicit antitumor immunity in colorectal cancer, and yield 62.9% inhibition of untreated distant tumors. ICG@COF‐1@PDA also exhibits notable phototherapeutic efficacy against 4T1 murine breast to lung metastasis, a spontaneous metastasis mode for triple‐negative breast cancers (TNBCs). Overall, this study reveals a novel nanodelivery system for molecular dispersion of NIR dyes, which may present new therapeutic opportunities against primary and metastatic tumors.     

All‐in‐One Phototheranostics: Single Laser Triggers NIR‐II Fluorescence/Photoacoustic Imaging Guided Photothermal/Photodynamic/Chemo Combination Therapy

Development of single near‐infrared (NIR) laser triggered phototheranostics for multimodal imaging guided combination therapy is highly desirable but is still a big challenge. Herein, a novel small‐molecule dye DPP‐BT is designed and synthesized, which shows strong absorption in the first NIR window (NIR‐I) and fluorescence emission in the second NIR region (NIR‐II). Such a dye not only acts as a dual‐modal contrast agent for NIR‐II fluorescence and photoacoustic (PA) imaging, but also serves as a combined therapeutic agent for photothermal therapy (PTT) and photodynamic therapy (PDT). The single NIR laser triggered all‐in‐one phototheranostic nanoparticles are constructed by encapsulating the dye DPP‐BT, chemotherapy drug DOX, and natural phase‐change materials with a folic acid functionalized amphiphile. Notably, under NIR laser irradiation, DOX can effectively release from such nanoparticles via NIR‐induced hyperthermia of DPP‐BT. By intravenous injection of such nanoparticles into Hela tumor‐bearing mice, the tumor size and location can be accurately observed via NIR‐II fluorescence/PA dual‐modal imaging. From in vitro and in vivo therapy results, such nanoparticles simultaneously present remarkable antitumor efficacy by PTT/PDT/chemo combination therapy, which is triggered by a single NIR laser. Overall, this work provides an innovative strategy to design and construct all‐in‐one nanoplatforms for clinical phototheranostics.     

Significant Enhancement of Photothermal and Photoacoustic Efficiencies for Semiconducting Polymer Nanoparticles through Simply Molecular Engineering

Semiconducting polymer nanoparticles (SP NPs) are employed as efficient nanoagents for “all‐in‐one” theranostic nanoplatforms with dual photoacoustic imaging (PAI) and photothermal therapy (PTT) functions based on their photothermal conversion effect. However, the mechanisms of tuning the PTT efficiency are still elusive, though several SP NPs with high photothermal efficiency are reported. Herein, two donor–acceptor (D–A) SP NPs PTIGSVS and PIIGSVS with the same donor unit but different acceptor units are designed and synthesized. Through tuning the acceptor unit, PTIGSVS shows more planar backbone structure, stronger D–A strength, redshifted absorption, enhanced extinction efficient, weakened emission properties, and more efficient nonradiative decay in comparison to the polymeric analogue PIIGSVS . Thus, PTIGSVS NPs present much higher photothermal conversion efficiencies (74%) than PIIGSVS NPs (11%), resulting in significantly enhanced in vitro and in vivo PAI and PTT performance. This contribution demonstrates that PTIGSVS NPs are superior PA/PTT agents for effective cancer theranostic and shed light on understanding the relationship between molecular structures and photothermal effect of CPs.     

Gadolinium‐Doped Iron Oxide Nanoprobe as Multifunctional Bioimaging Agent and Drug Delivery System

In this study, a high‐performance T₁–T₂ dual‐model contrast agent by gadolinium‐doped iron oxide nanoparticle (GION) is developed. Following its development, the application of this agent in vivo by combining doxorubicin (DOX) and folic acid (FA) (FA–GION–DOX) for targeted drug delivery to monitor cancer treatment is explored. GION showed transverse and longitudinal relaxivities up to 182.7 × 10^?3 and 7.87 × 10^?3m ^?1 s^?1, respectively, upon Gd/Fe ratio in GION at 1/4. DOX released from FA–GION–DOX is pH dependent and only kills cancer cell after FA receptor‐mediated internalization into the acidic environment of endosomes and lysosomes. Systemic delivery of FA–GION–DOX significantly inhibits the growth of tumors and shows good magnetic resonance enhancement in a human cervical cancer xenograft model. Thus, FA–GION–DOX has a potential application for the targeted and magnetic resonance imaging guided therapy of cervical cancer.     

Self‐Mineralized Photothermal Bacteria Hybridizing with Mitochondria‐Targeted Metal–Organic Frameworks for Augmenting Photothermal Tumor Therapy

A photothermal bacterium (PTB) is reported for tumor‐targeted photothermal therapy (PTT) by using facultative anaerobic bacterium Shewanella oneidensis MR‐1 (S. oneidensis MR‐1) to biomineralize palladium nanoparticles (Pd NPs) on its surface without affecting bacterial activity. It is found that PTB possesses superior photothermal property in near infrared (NIR) regions, as well as preferential tumor‐targeting capacity. Zeolitic imidazole frameworks‐90 (ZIF‐90) encapsulating photosensitizer methylene blue (MB) are hybridized on the surface of living PTB to further enhance PTT efficacy. MB‐encapsulated ZIF‐90 (ZIF‐90/MB) can selectively release MB at mitochondria and cause mitochondrial dysfunction by producing singlet oxygen (¹O₂) under light illumination. Mitochondrial dysfunction further contributes to adenosine triphosphate (ATP) synthesis inhibition and heat shock proteins (HSPs) down‐regulated expression. The PTB‐based therapeutic platform of PTB@ZIF‐90/MB demonstrated here will find great potential to overcome the challenges of tumor targeting and tumor heat tolerance in PTT.     

Phase‐Change Materials Based Nanoparticles for Controlled Hypoxia Modulation and Enhanced Phototherapy

Tumor hypoxia strengthens tumor resistance to different therapies especially oxygen involved strategies, such as photodynamic therapy (PDT). Herein, the thermal responsive phase change materials (PCM) are utilized to coencapsulate ultrasmall manganese dioxide (sMnO₂) and organic photosensitizer IR780 to obtain IR780‐sMnO₂‐PCM nanoparticles for controlled tumor hypoxia modulation and enhanced phototherapy. The thermal responsive protective PCM layer can not only prevent IR780 from photodegradation, but also immediately release sMnO₂ to decompose endogenous H₂O₂ and generate enough oxygen for PDT under laser irradiation. Owing to the efficient accumulation of IR780‐sMnO₂‐PCM nanoparticles in tumor under intravenous injection as revealed by both florescence imaging and photoacoustic imaging, the tumor hypoxia is greatly relieved. Furthermore, in vivo combined photothermal therapy (PTT) and PDT, IR780‐sMnO₂‐PCM nanoparticles, compared to IR780‐PCM nanoparticles, exhibit better performance in inhibiting tumor growth. The results highlight the promise of IR780‐sMnO₂‐PCM in controlled modulation of tumor hypoxia to overcome current limitations of cancer therapies.     

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.     

Core–Satellite Mesoporous Silica–Gold Nanotheranostics for Biological Stimuli Triggered Multimodal Cancer Therapy

A core–satellite nanotheranostic agent with pH‐dependent photothermal properties, pH‐triggered drug release, and H₂O₂‐induced catalytic generation of radical medicine is fabricated to give a selective and effective tumor medicine with three modes of action. The nanocomplex (core–satellite mesoporous silica–gold nanocomposite) consists of amino‐group‐functionalized mesoporous silica nanoparticles (MSN‐NH₂) linked to L‐cysteine‐derivatized gold nanoparticles (AuNPs‐Cys) with bridging ferrous iron (Fe²⁺) ions. The AuNPs‐Cys serve as both removable caps that control drug release (doxorubicin) and stimuli‐responsive agents for selective photothermal therapy. Drug release and photothermal therapy are initiated by the cleavage of Fe²⁺ coordination bonds at low pH and the spontaneous aggregation of the dissociated AuNPs‐Cys. In addition, the Fe²⁺ is able to catalyze the decomposition of hydrogen peroxide abundant in cancer cells by a Fenton‐like reaction to generate high‐concentration hydroxyl radicals (·OH), which then causes cell damage. This system requires two tumor microenvironment conditions (low pH and considerable amounts of H₂O₂) to trigger the three therapeutic actions. In vivo data from mouse models show that a tumor can be completely inhibited after two weeks of treatment with the combined chemo‐photothermal method; the data directly demonstrate the efficiency of the MSN–Fe–AuNPs for tumor therapy.     

Precise Molecular Engineering of Photosensitizers with Aggregation‐Induced Emission over 800 nm for Photodynamic Therapy

Owing to efficient singlet oxygen (¹O₂) generation in aggregate state, photosensitizers (PSs) with aggregation‐induced emission (AIE) have attracted much research interests in photodynamic therapy (PDT). In addition to high ¹O₂ generation efficiency, strong molar absorption in long‐wavelength range and near‐infrared (NIR) emission are also highly desirable, but difficult to achieve for AIE PSs since the twisted structures in AIE moieties usually lead to absorption and emission in short‐wavelength range. In this contribution, through acceptor engineering, a new AIE PS of TBT is designed to show aggregation‐induced NIR emission centered at 810 nm, broad absorption in the range between 300 and 700 nm with a large molar absorption coefficient and a high ¹O₂ generation efficiency under white light irradiation. Further, donor engineering by attaching two branched flexible chains to TBT yielded TBTC8 , which circumvented the strong intermolecular interactions of TBT in nanoparticles (NPs), yielding TBTC8 NPs with optimized overall performance in ¹O₂ generation, absorption, and emission. Subsequent PDT results in both in vitro and in vivo studies indicate that TBTC8 NPs are promising candidates in practical application.     

Size‐Transformable Metal–Organic Framework–Derived Nanocarbons for Localized Chemo‐Photothermal Bacterial Ablation and Wound Disinfection

Severe infectious diseases caused by pathogenic bacteria have become urgent threats to global public health. Antibacterial materials with combined chemo‐photothermal therapeutic capabilities possess distinct advantages when compared with many other antibacterial approaches. However, developing simplified and chemically tunable precursors to synthesize such antibacterial nanoagents for rapidly, safely, and synergistically combating pathogenic bacteria remains a huge challenge. Herein, metal–organic framework (MOF)‐derived nanocarbons with near‐infrared (NIR)‐responsive and size‐transformable capabilities are designed to overcome this challenge. The MOF‐derived nanocarbons with chemo‐photothermal bactericidal capabilities are first synthesized, and then coated with a thermoresponsive gel layer to obtain ON–OFF switching capability for bacterial trapping. The fabricated nanocarbons exhibit high photo‐to‐thermal conversion efficiency and fast size transformation from nanodispersions to micrometer aggregations upon NIR irradiation, thus enabling nanocarbons to generate localized massive heat and abundant Zn²⁺ ions for directly disrupting bacterial membrane and intracellular proteins. Furthermore, these nanocarbons not only exhibit a nearly 100% bactericidal ratio at very low dosage, but also possess highly efficient and safe wound disinfection activities, which are comparable to vancomycin. Overall, these proposed novel nanocarbons display robust and localized chemo‐photothermal bactericidal capability and possess great potential to be used as alternative to antibiotics for broad‐spectrum eradication of pathogenic bacteria.     

NIR‐II Light Activated Photosensitizer with Aggregation‐Induced Emission for Precise and Efficient Two‐Photon Photodynamic Cancer Cell Ablation

Near infrared (NIR) light excitable photosensitizers are highly desirable for photodynamic therapy with deep penetration. Herein, a NIR‐II light (1200 nm) activated photosensitizer TQ‐BTPE is designed with aggregation‐induced singlet oxygen (¹O₂) generation for two‐photon photodynamic cancer cell ablation. TQ‐BTPE shows good two‐photon absorption and bright aggregation‐induced NIR‐I emission upon NIR‐II laser excitation. The ¹O₂ produced by TQ‐BTPE in an aqueous medium is much more efficient than that of commercial photosensitizer Ce6 under white light irradiation. Upon NIR‐II excitation, the two‐photon photosensitization of TQ‐BTPE is sevenfold higher than that of Ce6. The TQ‐BTPE molecules internalized by HeLa cells are mostly located in lysosomes as small aggregate dots with homogeneous distribution inside the cells, which favors efficient photodynamic cell ablation. The two‐photon photosensitization of TQ‐BTPE upon NIR‐I and NIR‐II excitation shows higher ¹O₂ generation efficiency than under NIR‐I excitation owing to the larger two‐photon absorption cross section at 920 nm. However, NIR‐II light exhibits better biological tissue penetration capability after passing through a fresh pork tissue, which facilitates stronger two‐photon photosensitization and better cancer cell ablation performance. This work highlights the promise of NIR‐II light excitable photosensitizers for deep‐tissue photodynamic therapy.     

pH‐Responsive Cyanine‐Grafted Graphene Oxide for Fluorescence Resonance Energy Transfer‐Enhanced Photothermal Therapy

Stimuli‐responsive anticancer agents are of particular interest in the field of cancer therapy. Nevertheless, so far stimuli‐responsive photothermal agents have been explored with limited success for cancer photothermal therapy (PTT). In this work, as a proof‐of‐concept, a pH‐responsive photothermal nanoconjugate for enhanced PTT efficacy, in which graphene oxide (GO) with broad NIR absorbance and effective photothermal conversion efficiency is selected as a typical model receptor of fluorescence resonance energy transfer (FRET), and grafted cyanine dye (e.g., Cypate) acts as the donor of near‐infrared fluorescence (NIRF), is reported for the first time. The conjugate of Cypate‐grafted GO exhibits different conformations in aqueous solutions at various pH, which can trigger pH‐dependent FRET effect between GO and Cypate and thus induce pH‐responsive photothermal effect of GO‐Cypate. GO‐Cypate exhibits severe cell damage owing to the enhanced photothermal effect in lysosomes, and thus generate synergistic PTT efficacy with tumor ablation upon photoirradiation after a single‐dose intravenous injection. The photothermal nanoconjugate with broad NIR absorbance as the effective receptor of FRET can smartly convert emitted NIRF energy from donor cyanine dye into additional photothermal effect for improving PTT. These results suggest that the smart nanoconjugate can act as a promising stimuli‐responsive photothermal nanoplatform for cancer therapy.